HomeMy WebLinkAbout1 LEGOLAND DR; TOLL BOOTH; CB122746; Permit02-05-2013
City of Carlsbad
1635 Faraday Av Carlsbad.CA 92008
Commercial/Industrial Permit Permit No:
Building Inspection Request Line (760) 602-2725
CB122746
Job Address
Permit Type
Parcel No
Valuation
Occupancy Group
Project Title
1 LEGOLAND DR CBAD
Tl
2111000900
$40,000 00
Sub Type COMM
Lot# 0
Construction Type 5B
Reference #
Status ISSUED
Applied 12/21/2012
Entered By. JMA
Plan Approved 02/05/2013
Issued 02/05/2013
Inspect Area
Plan Check #
LEGOLAND
INSTALL 2 PREFAB TOLL BOOTHS AT PARKING LOT ENTRANCE
Applicant
RICHARD APEL
571-B HYGEIA AV
LEUCADIA CA 92024
760-943-0760
Owner
LEGOLAND CALIFORNIA LLC <LF> PLAY U S ACQUISI
C/O PROPERTY TAX SERVICE CO
P O BOX 543185
DALLAS TX 75354
Building Permit $379 92 Meter Size
Add'l Building Permit Fee $0 00 Add'l Reel Water Con Fee $0 00
Plan Check $265 94 Meter Fee $0 00
Add'l Building Permit Fee $0 00 SDCWA Fee $0 00
Plan Check Discount $0 00 CFD Payoff Fee $0 00
Strong Motion Fee $8 40 PFF (3105540) $0 00
Park Fee $0 00 PFF (4305540) $0 00
LFM Fee $0 00 License Tax (3104193) $0 00
Bridge Fee $0 00 License Tax (4304193) $0 00
BTD #2 Fee $0.00 Traffic Impact Fee (3105541) $0 00
BTD #3 Fee $0 00 Traffic Impact Fee (4305541) $0 00
Renewal Fee $0 00 PLUMBING TOTAL $0 00
Add'l Renewal Fee $0 00 ELECTRICAL TOTAL $41 00
Other Building Fee $0 00 MECHANICAL TOTAL $31 00
Pot. Water Con Fee $0 00 Master Drainage Fee $0 00
Meter Size Sewer Fee $0 00
Add'l Pot Water Con Fee $0 00 Redev Parking Fee $0 00
Red Water Con Fee $0 00 Additional Fees $0 00
Green Bldg Stands (SB1473) Fee $1 00 HMP Fee 99
Fire Expedidted Plan Review $0.00 Green Bldg Standards Plan Chk 99
TOTAL PERMIT FEES $727 26
Total Fees $727 26 Total Payments To Date-$727 26 Balance Due: $0.00
inspector
FINAL APPROVAL
Date Clearance.
NOTICE Please take NOTICE that approval of your project includes the "Imposition" of fees, dedications, reservations, or other exactions hereafter collectively
refen-ed to as "fees/exactions" You have 90 days from the date this pennit was issued to protest imposition of these fees/exactions If you protest them, you must
follow the protest procedures set forth in Govemment Code Section 66020(a), and file the protest and any other required information with the City Manager for
processing in accordance with Carlsbad Municipal Code Section 3 32 030 Failure to timely follow that procedure will bar any subsequent legal action to attack,
review, set aside, void, or annul their imposition
You are hereby FURTHER NOTIFIED that your nght to protest the specified fees/exactions DOES NOT APPLY to water and sewer connection fees and capacity
changes, nor planning, zoning, grading or other similar application processing or service fees in connection with this project NOR DOES IT APPLY to any
fees/exactions of which vou have previously been given a NOTICE similar to this, or as to which the statute of limitations has previously othewise expired
02-05-2013
City of Carlsbad
.1635 Faraday Av Carlsbad.CA 92008
Storm Water Pollution Prevention Plan (SWPPP) Permit
Permit No:SW120540
Job Address
Permit Type
Parcel No
Reference #
CB#
Project Title
Pnority
Applicant
RICHARD APEL
571-B HYGEIA AV
LEUCADIA CA 92024
760-943-0760
1 LEGOLAND DR CBAD
SWPPP
2111000900 Lot#-
LLEGOLAND TOO BOOTHS
INSTALL 2 PREFAB TOLL BOOTHS AT PARKING LOT
M
Status
Applied
Entered By
Issued
Inspect Area
Tier.
ISSUED
12/21/2012
MDP
02/05/2013
1
Owner.
LEGOLAND CALIFORNIA LLC <LF> PLAY U S ACQUISI
C/O PROPERTY TAX SERVICE CO
POBOX 543185
DALLAS TX 75354
Emergency Contact
CHRIS ROMERO
760 846-0842
SWPPP Plan Check
SWPPP Inspections
Additional Fees
$51 00
$216 00
$0 00
TOTAL PERMIT FEES $267 00
Total Fees $267.00 Total Payments To Date $267 00 Balance Due: $0.00
FINAL APPROVAL
DATE'/-5-/'^ CAARANCE
SIGNATURE IP
%
CARLSBAD
CITY OF
Building Permit Application
1635 Faraday Ave , Carlsbad, CA 92008
760-602-2717/2718/2719
Fax 760-602-8558
www.carlsbadca.gov
Plan Check No.
Est. Value lf6,Crtrb ace^"^^'
Plan Ck. Deposit
JOB ADDRESS 1 Legoland Dr., Carlsbad CA 92008
CT/PROJECT # # OF UNITS » BEDROOMS
SUITE#/SPACE#/UNIT#
# BATHROOMS
211 100 09
TENANT BUSINESS NAIVIE
LEGOLAND CALIFORNIA
CONSTR TYPE
A-3
DESCRIPTION OF WORK- /nc/ude Square Feet of Affected Areafs)
Installation of two new prefabricated toll booths at parking lot (96 s.f. total floor area). Associated site work to expand
entry drive at location of new toll booths, including grading, storm drainage, curb & gutter, paving,-teaemg, pedestrian
pathways. Extend electrical service to new booths.
EXISTING USE
Amusement Park
PROPOSED USE
Same
GARAGE (SF) PATIOS (SF) DECKS (SF) FIREPLACE
YESQ# NOfTI
AIRCONOITIONING
YES I I NO [71
FIRE SPRINKLERS
YES I iNofT]
CONTACT NAME (If Different Fom Applicant) Richard Apel APPLICANT NAIVIE Chris Romero
ADDRESS
R.W. Apel Landscape Architects, 571-B Hygeia Ave.
ADDRESS
Legoland California, 1 Legoland Dr.
Leucadia
STATE
CA
ZIP
92024 Carlsbad CA 92008
PHONE
(760) 943-0760
FAX
(760) 943-0760
PHONE
(760) 846-0842 (760)918-5469
EMAIL
nyapel2@cox.net chris.romero@legoland.com
PROPERTY OWNER NAME Merlin Entertainment Group U.S. Holdings CONTRACTOR BUS. NAME None selected at this time
ADDRESS
1 Legoland Dr.
ADDRESS
CITY
Carlsbad
STATE
CA
ZIP
92008
STATE
PHONE
(760) 918-5300 (760)918-5469
PHONE FAX
EIVIAIL EMAIL
ARCH/DESIGNER NAMES ADDRESS
R. W. Apel (see contact) 2825
CITY BUS UC«
(Sec 70315 Business and Professions Code Any City or County which requires a permit to construct, alter, improve, demolish or repair any structure, prior to its issuance, also requires the applicant for such permit to file a signed statement that he is licensed pursuant to the provisions of the Contractor's License Law (Chapter 9, commending with Section 7000 of Division 3 of the Business and Professions Code) or that he is exempt therefrom, and the basis for the alleged exemption Any violation of Section 7031 5 by any applicant for a permit subjects the applicant to a civil penalty of not more than five hundred dollars ($500))
siiSffiSiiiifiiiiiMlllB
Workers' Compensation Declaration / hereby affirm underpenalty of perjury one ofthe following declarations
CZ I have and will maintain a certificate of consent to self-insure for workers' compensation as provided by Section 3700 of the Labor Code, for the performance of the work for which this permit is issued
• 1 have and will mamtain workers' compensation, as required by Section 3700 of the Labor Code, (or the performance of the work for which this permit is issued My workers' compensation insurance carrier and policy
number are Insurance Co Policy No Expiration Date
This section need not be completed if Ihe permit is for one hundred dollars ($100) or less
I I Certificate of Exemption 1 certify that in the performance of the work for which this permit is issued, 1 shall not employ any person in any manner so as to become subject to the Workers' Compensation Laws of
California WARNING Failure to secure workers' compensation coverage Is unlawful, and shall subject an employer to criminal penalties and civil fines up to one hundred thousand dollars |&100,000|, In
addition to the cost of compensation, damages as provided for in Section 3706 of the Labor code, interest and attorney's fees
JS^ CONTRACTOR SIGNATURE • AGENT DATE
^IgiljWgNlE
/ hereby affirni lhat I am exempt from Contractor's bcense Law for the following reason
I I 1, as owner of the property or my employees with wages as their sole compensation, will do the work and the stmcture is not intended or offered for sale (Sec 7044, Business and Professions Code The CL
License Law does not apply to an owner of property who builds or improves thereon, and who does such work himself or through his own employees, provided that such improvements are not intended or offered for
sale If, however, the building or improvement is sold within one year of completion, the owner-builder will have Ihe burden of proving that he did not build or improve for the purpose of sale)
\y\ 1, as owner of the property, am exclusively contracling with licensed contractors to constmct the project (Sec 7044, Business and Professions Code The Contractor's License Law does not apply to an owner ol
property who builds or improves thereon, and contracts for such projects with contractor(s) licensed pursuant to the Contractor's License Law)
I I I am exempt under Section Business and Professions Code for this reason
1 I personally plan to provide the major labor and matenals for construction of the proposed properly improvement Q]Yes | INO
2 I (have / have not) signed an application for a building permit for the proposed work
3 I have contracted with the following person (firm) to provide the proposed construction (include name address / phone / contractors' license number)
4 I plan to provide portions of the work, but I have hired the following person to coordinate, supen/ise and provide the major work (include name / address / phone / contractors' license number)
5 I will provide some of the work, but I have contracted (hired) the following persons to provide the work indicated (include name / address / phone / type of work)
1^ -^PROPERTY OWNER SIGNATURE •AGENT
Is the applicant or future building occupant required to submitabusiness plan, acutely hazardous matenals registration form or nsk management and prevention program under Sections 25505,25533 or 2E _
Presley-Tanner Hazardous Substance Account AcP j jYes LZJNO
Is the applicant or future building occupant required to obtain a penrat from the air pollution control district or air quality management distncP QYes [3
Is the facility to be constructed withm 1,000 feet of the outer boundary of a school site? I lYes |i/|No
IF ANY OF THE ANSWERS ARE YES, A FINAL CERTIFICATE OF OCCUPANCY MAY NOT BE ISSUED UNLESS THE APPLICANT HAS MET OR IS MEETING THE REQUIREMENTS OF THE OFFICE OF
EMERGENCY SERVICES AND THE AIR POLLUTION CONTROL DISTRICT
I hereby affirm that there is a construction lending agency for the performance of the work this permit is issued (Sec. 3097 (i) Civil Code)
Lender's Name Lender's Address
1 certify that 1 have read the application and state thatthe above mfonnation is conect and thatthe infonnahon on the plans is accurate 1 agree to complywith all City onlinances and State laws relatingto building construcbon
I hereby authonze representative of the City of Carlsbad to enter upon Ihe above mentioned property for inspection puiposes I ALSO AGREE TO SAVE, INDEMNIFY AND KEEP HARMLESS THE CITY OF CARLSBAD
AGAINST ALL LIABILITIES, JUDGMENTS, COSTS AND EXPENSES WHICH MAY IN ANY WAY ACCRUE AGAINST SAID CITY IN CONSEQUENCE OF THE GRANTING OF THIS PERMIT
OSHA An OSHA penrat is required for excavations over 5'0' deep and demolition or construction of stractures over 3 stones in height
EXPIRATION Every pennit issued by the Building OfficiaUinder the provisions of this Code shall expire by limitation and become null and void if the building or work authorized by such permit is not commenced within
180 days from Ihe date of such perniil or if Ihe/building or work authonzed by such permit is suspended or abandoned at any time after the work is commenced for a penod of 180 days (Section 106 4 4 Uniform Building Code)
^APPLICANT'S SIGNATURE M DATE
Inspection List
Permit*: CB122746 Type: Tl COMM LEGOLAND
INSTALL 2 PREFAB TOLL BOOTHS AT PA
Date Inspection Item Inspector Act
04/03/2013 89 Final Combo -Rl
04/03/2013 89 Final Combo PD AP
03/28/2013 152 Final Bldg Inspection - Fire CWON AP
03/22/2013 92 Compliance Investigation PB AP
02/25/2013 11 Ftg/Foundation/Piers PD AP
02/22/2013 31 Underground/Conduit-Wirin PD AP
02/20/2013 31 Underground/Conduit-Wirin PD AP
Comments
MO CARD ON FILE AS OF YET
Tuesday, April 09, 2013 Page 1 of 1
Project Name:
LegoLand Toll Booth addition
Project No.:
10075-001
Date:
2-22-13
Report No.
Location:
Carlsbad
Author:
S.Lynn Reid
Day: M T W T F S S
• ••n^D o
Client/Contractor:
Lego/Commercial Builders/CCI
Supt/Foreman:
Chris/Robert Kay
Weather:
Clear 72+- F
Field Supervisor:
SAC
Geologist: Soil Engineer:
Observation/Testing of:
Curb subgrades/Toll booth pads
Tech SLR
Equipment Working:
1-skip loader 1-vibe sw roller 1-mini excavator
Hours 5.5
Today's Yardage:
Yardage to Date:
Summary of Operations:
2-22-13- (AM-PM) SLR on site early AM as scheduled by Robert w/Commercial Builders. The west curb and gutter grades
have been slightly adjusted and re-rolled, these sutigrades were probed and found to be firm except in the south most
25'+- where overwet soil conditions were noted in the upper 14" +- of the sg. The mini exc. removed the ovenwet area
down to firm grades (minor hand cleanup needed at the inlet box), the sg to be re-made with compacted material at
optimum moisture.
The curbs forthe walk from Armada have been made and probed firm. The east portion ofthis curb near the top-of the
minor slope was deepened at the author's suggestion.
The electric contractor observed installing conduits in a trench directly behind the curb west/SW ofthe existing toll
booths. Compacting the backfill of this trench to 90% relative density recommended to Robert to support the adjacent
curb.
The installed and backfilled inigation crossing trenches in the fire access drive were probed and were found to be loose
and not compacted. These backfills should be reworked and compacted to 90%+ rc up to minus 12" and 95% rc in the
upper 12" to subgrades.
The two new toll booth pad areas were filled to pad subgrade with granular native soils. The 12"~24''+- fills were placed in
thin lifts and compacted with the sw roller and by wheel rolling with the skip loader. Observation, probing, and testing of
the toll booth pads in representative locations indicated that adequate moisture and densities were obtained. The CCI
crew began digging the footings for these structures mid PM.
Observation and probing of the current soil conditions in the planned drive/paving area at near subgrades were still noted
to be ovenwet, yielding, rutting under wheel loads. A firm, compacted, and unyielding suljgrade is recommended priorto
base and paving. Drying back the subgrade/near surface material to near optimum moisture and re-compacting and/or
the use of geofabrics to improve the subgrade conditions should be considered. The subgrade conditions and
recommendations again discussed with Robert Kay and also with Chris (Lego).
Leighton and Associates
DAILY FIELD REPORT
Received By:
Print
3910 1098
Circle Distribution
EsGil Corporation
ltl (PartnersHip witH Qovemment for (BuiCding Safety
DATE: DEC. 31, 2012 • APPLICANT
^a^juRis
JURISDICTION: CARLSBAD • PLAN REVIEWER
• FILE
PLAN CHECK NO.: 12-2746 SET I
PROJECT ADDRESS: 1 LEGOLAND DRIVE
PROJECT NAME: ADDITION OF TWO NEW TOLL BOOTHS
I I The plans transmitted herewith have been corrected where necessary and substantially comply
with the jurisdiction's codes.
^ The plans transmitted herewith will substantially comply with the jurisdiction's building codes
when minor deficiencies identified below are resolved and checked by building department staff.
I I The plans transmitted herewith have significant deficiencies identified on the enclosed check list
and should be corrected and resubmitted for a complete recheck.
I I The check list transmitted herewith is for your information. The plans are being held at Esgil
Corporation until corrected plans are submitted for recheck.
I I The applicant's copy of the check list is enclosed for the jurisdiction to forward to the applicant
contact person.
I I The applicant's copy of the check list has been sent to:
EsGil Corporation staff did not advise the applicant that the plan check has been completed.
I I EsGil Corporation staff did advise the applicant that the plan check has been completed.
Person contacted: Telephone #:
Date contacted: (by: ) Email: Fax #:
Mail Telephone Fax In Person
^ REMARKS: As defined in CBC, Sec, 1102B, the toll booths qualify as work stations and need to comply with
Section 11238. This means the 4" raised curb, as shown on detail 1/A-2, should be accessible via a ramp or lowered
to the same level as adjacent grade.
By: ALI SADRE Enclosures:
EsGil Corporation
• GA • EJ • PC 12/26
9320 Chesapeake Drive, Suite 208 • San Diego, California 92123 • (858) 560-1468 • Fax (858) 560-1576
[DO NOT PAY- THIS IS NOTAN INVOICE]
VALUATION AND PLAN CHECK FEE
JURISDICTION: CARLSBAD PLAN CHECK NO.: 12-2746
PREPARED BY: ALI SADRE DATE" DEC. 31, 2012
BUILDING ADDRESS: 1 LEGOLAND DRIVE
BUILDING OCCUPANCY: A5 TYPE OF CONSTRUCTION: V-B
BUILDING
PORTION
AREA
(Sq Ft)
Valuation
Multiplier
Reg.
Mod.
VALUE ($)
TOLL BOOTHS
Air Conditioning
Fire Sprinklers
TOTAL VALUE 40,000
Jurisdiction Code CB By Ordinance
Bldg. Permit Fee by Ordinance • $379.92
Plan Check Fee by Ordinance $246.95
Type of Review 0 Complete Review • Structural Only
^•Repetitive Fee
^ j Repeats
• Other
|-j Hourly
EsGil Fee
Hr. @ *
$212.76
Comments:
Sheet 1 of 1
macvalue doc +
^ CITY OF
CARLSBAD
PLAN CHECK
REVIEW
TRANSMITTAL
Community & Economic
Development Department
1635 Faraday Avenue
Carlsbad CA 92008
wwvi? carlsbadca.gov
DATE: 01 /30/2013 PROJECT NAIVIE: Legoland_parking toll booths
PLAN CHECK NO: CB 12-2746 SET#: II ADDRESS: 1 Legoland Drive„92008
VALUATION: $40,000
PROJECT ID:CD 12 17
APN: 211-100-09
SCOPE OF WORK: Grading, storm drain, curb&gutter, paving, pedestnan pathways
associated with instaUation of two new toll booths.
*™UPDATED 02/05/2013***** '
This plan check review is complete and has been APPROVED by:
LAND DEVELOPIVIENT ENGINEERING DIVISION
A Final Inspection by the Construction Mgmt & Inspection Division is required fXj Yes [^| No
This plan check review is NOT COIVIPLETE. Items missing or incorrect are listed on
the attached checklist. Please resubmit amended plans as required.
Plan Check Comments have been sent to: rwapei2@c0x.net
PLANr^ii^--^-;:.fi=;?s ENGINEERING
760-602-2750 2/50 7^'^ *i';^*v-^'
HRt'BREfENTJgl^;'
f«fi.76p:6*0|?i66 .,'1 •"
i Chris Sexton
760-602-4624
Chris.Sextoti@carlsbadca.gov
j I Gir •, Ru /.
I I
' ' 760-bU2-^6 /5
Gina.Ruiz@carlsbadca.gov
j Kathleen Lawrence
—J 760-602-2741
Kathleen.Lawrence@carlsbadca.gov
X Linda Ontiveros
760-602-2773
Linda.Ontiveros@carlsbadca.gov
Greg Ryan
760-602-4663
Gregory.Ryan@carlsbadca.gov
"1 Cindy Wong
760-602-4662
Cynthia.Wong@carisbadca.gov
] Dominic Fieri
' 760-602-4664
Dominic.Fieri@carl3badca gov
Remarks: -Construction change to DWG 333-2Y signed 02/04/2013
-Print package completed 02/05/2013
***Minor grading permit, GR 13-04, to be issued concurrently with building permit*
•^
NS/ CITY OF
CARLSBAD
PLAN CHECK
REVIEW
TRANSMITTAL
Community & Economic
Development Department
1635 FaradayAvenue
Carlsbad CA 92008
www.carlsbadca.gov
DATE: 01 /09/2013 PROJECT NAIVIE: Legoland_parking toll booths
PLAN CHECK NO: CB 12-2746 SET#: I ADDRESS: 1 Legoland Drive_92008
VALUATION: $40,000
PROJECT ID:CD 12 17
APN: 211-100-09
SCOPE OF WORK: Grading, storm drain, curbftgutter, paving, pedestrian pathways
associated with installation of two new toll booths.
You may have corrections from one or more of ttie divisions listed in the table below.
To determine status by one or more of these divisions, please contact 760-602-2719.
This plan check review is complete and has been APPROVED by:
LAND DEVELOPIVIENT ENGINEERING DIVISION
A Final Inspection by the Construction Mgmt&lnspection Division is required [ J Yes [j No
X This plan check review is NOT COMPLETE. Items missing or incorrect are listed on
the attached checklist. Please resubmit amended plans as required.
Plan Check Comments^have been sent to: rwapei2@c0x.net
PLANNING
760-602-4610
ENGINEERING
760-602^2750,
FIRE PREVENTION
; 760-602-4665
Ii Chris Sexton
;L. ,J 760-602-4f324
Chris.Sexton@carlsbadca.gov
J j Gina Ruiz
c.„.J 760-602-4675
Gina.Ru!2@ca risbadca.gov
, Kathleen Lawrence
760-602-2741
Kathleen.Lawrence@carlsbadca.gov
X Linda Ontlveros
760-602-2773
Linda.Ontiveros@carlsbadca.gov
; tlreg Ryan
J 760-602-4663
Gregory.Ryan@carlsbadca.gov
r^""^ Cindy Wong
L^i 760-602-4662
Cyrithia.Wong@carlsbadca,gov
Dominic Fieri
760-602-4664
Dommic.Fierl@carlsbadGa.gov
Remarks:
Legoland_parkingtoll booths PLAN CHECK NO # CB 12-2746
Corrections on this plan review checklist have been marked with X . Items that conform to
permit requirements are marked with \ / ' -or- have intentionally been left blank
1. SITE PLAN
Provide a fully dimensioned site plan drawn to scale. Show
Ld North arrow L.J
1 /1 Existing & proposed structures 1 1
!
LJ /1 Existing street improvements 1 !
LJ UJ Property lines (show all dimensions) L_J
LJ 1 / i Easements
1 / 1 Right-of-way width & adjacent streets
[~7~1 Driveway widths
[323 Existing or proposed sewer lateral
CZZI Existing or proposed water service
UZ3 Submit on signed approved plans
DWG No
Show on site plan:
I 1
I 1
I 1
•
I I
Drainage patterns
1 Building pad surface drainage must maintain a minimum slope of one percent towards an adjoining
street or an approved drainage course
r ~]ADD THE FOLLOWING NOTE "Finish grade will provide a minimum positive drainage of 2% to swale
5' away from building"
r ' I Existing & proposed slopes and topography
Size, location, alignment of existing or proposed sewer and water service(s) that serves the project
Each unit requires a separate service, however, second dwelling units and apartment complexes are an
exception
Sewer and water laterals should not be located within proposed dnveways, per standards
Include on title sheet
• / j Site address
7~1 Assessor's parcel number
Legal descnption/lot number /
I I For commercial/industnal buildings and tenant improvement projects, include total building
square footage with the square footage for each different use, existing sewer permits
showing square footage of different uses (manufactunng, warehouse, office, etc ) previously
approved
I Show all existing use of SF and new proposed use of SF.
Example
Tenant improvement for 3500 SF of warehouse to 3500 SF of office.
Lot/Map No
Subdivision/Tract
Reference No(s)
E- 36 Page 2 of 6 REV 6/01/12
' Legoland_parking toll booths PLAN CHECK NO # CB 12-2746
2. DISCRETIONARY APPROVAL COMPLIANCE
X Project does not comply with the following engmeenng comments for project no CD 12-17
See memorandum from Tecla Levy dated January 8, 2013
3. DEDICATION REQUIREMENTS
Dedication for all street nghts-of-way adjacent to the building site and any storm drain or
utility easements on the building site is required for all new buildings and for remodels with a
value at or exceeding $ 20,000 00 , pursuant to Carlsbad Municipal Code Section 18 40 030
For single family residence, easement dedication will be completed by the City of Carlsbad,
cost $605 00
I / I Dedication required as follows
n/a
4. IMPROVEMENT REQUIREMENTS
All needed public improvements upon and adjacent to the building site must be constructed
at time of building construction whenever the value of the construction exceeds
$100,000.00, pursuant to Carlsbad Municipal Code Section 18 40 040
L/J Public improvements required as follows-
n/a
Construction of the public improvements must be deferred pursuant to Carlsbad
Municipal Code Section 18.40 Please submit a recent property title report or current grant
deed on the property and processing fee nf $ 441 nn so we may prepare the necessary
Neighborhood Improvement Agreement This agreement must be signed, notarized and
approved by the city prior to issuance of a building permit
L/J Future public improvements required as follows
n/a
E-36 Page 3 of 6
Legoland_parking toll booths PLAN CHECK NO tt CB 12-2746
5. GRADING PERMIT REQUIREMENTS
The conditions that require a grading permit are found in Section 15 16 of the Municipal
Code
X
X
X
Inadequate information available on site plan to make a determination on grading
requirements Include accurate grading quantities in cubic yards (cut, fill, import, export and
remedial) This information must be included on the plans. If no grading is proposed
write: "NO GRADING"
Grading Permit required NOTE The qradinq permit must be issued and rough grading
approval obtained pnorto issuance of a buildmq permit
I I Graded Pad Certification required (Note Pad certification may be required even if a grading
permit is not required ) All required documentation must be provided to your Engmeenng
Construction Inspector ***to be determined upon issuance*** The inspector will then
provide the engineenng counter with a release for the building permit
No grading permit required
Minor Grading Permit required
Redlines will be routed via project planner, Van Lynch
6. MISCELLANEOUS PERMITS
CX]
RIGHT-OF-WAY PERMIT is required to do work in city nght-of-way and/or private work
adjacent to the public nght-of-way Types of work include, but are not limited to street
improvements, tree tnmming, dnveway construction, tying into public storm dram, sewer and
water utilities
LZI other
Construction changed to existing grading plan, DWG 333-2Y ~ sheets 27 and 32.
Submittal fee is $779.00 (Base $469 + $155/sheet ~ 2 sheets total) and requires all
Items per construction change submittal checklist, E-4 (attached to this checklist).
E-36 Page 4 of 6 REV 13/01/12
.Legoland_parking toll booths PLAN CHECK NO # CB 12-2746
7. STORM WATER
Construction Compliance
i "! • ! Project Threat Assessment Form complete
Enclosed Project Threat Assessment Form incomplete
X See attached fee
(sht 20) from the
City's current
development fee
schedule to
calculate
Construction Storm - ,
Pollution Prevention '
Plan & Storm Water
Management Plan fX]
plan review fees.
Requires Tier 1 Storm Water Pollution Prevention Plan Please complete attached form
and return (SW )
LZJ Requires Tier 2 Storm Water Pollution Prevention Plan Requires submittal of Tier 2
SWPPP, payment of processing fee and review by city.
Post-Development (SUSMP) Compliance
" I Storm Water Standards Questionnaire complete
~j Storm Water Standards Questionnaire incomplete Please make the corrections, re-sign
the questionnaire and resubmit with next submittal.
Project IS subject to Pnonty Development Project and requires a Stormwater Management
Plan. See city Standard Urban Storm Water Management Plan (SUSMP) for reference
http //www carlsbadca qov/business/buildinq/Documents/EnqStandsw-stds-vol4-ch2 pdf
i Project needs to incorporate low impact development strategies throughout m one or
more of the foiiowing ways
I I Rainwater harvesting (ram barrels or cistern)
• Vegetated Roof
LI] Bio-retentions cell/ram garden
I ~~1 Pervious pavement/pavers
LZI Flow-through planter/vegetated or rock drip line
I I Vegetated swales or rock infiltration swales
r~~| Downspouts disconnect and discharge over landscape
Lll Other
E-36 Page 5 of 6 REV 6/01/12
Legoland_parking toll booths PLAN CHECK NO # CB 12-2746
9. WATER METER REVIEW
Domestic (potable) Use
rz
UJ
FYI
What size meter is required''
Where a residential unit is required to have an automatic fire
extinguishing system, the minimum meter size shall be a 1" meter
NOTE the connection fee, SDCWA system capacity charge and the
water treatment capacity charge will be based on the size of the meter
necessary to meet the water use requirements
For residential units the minimum size meter shall be 5/8", except where
the residential unit is larger than 3,500 square feet or on a lot larger than
one quarter (1/4) acre where the meter size shall be
8. FEES
***Fees required with
submittal of grading
plan, construction
change, storm water
pollution prevention
plan - Tier 2, and
Storm water
management plan -
these fees are paid
separate to Land
Development
Engineering***
Required fees have been entered in building permit
Drainage fee applicable
Added square feet
Added square footage in last two years'' LZ y®s LZ
Permit No
Permit No
Project built after 1980 LZv^^ L]"°
Impervious surface > 50%
Impact unconstructed facility
• yes no
• yes Dno
Fire spnnklers required •yes Qno (is addition over 150' from center line)
yes •no Upgrade
No fees required
10. Additional Comments
To download any ofthe city's applications and/or Land Development
Engineering handouts, please visit:
www.carlsbadca.gov/development-forms
Attachments. I / j Engineering Appilcation 1^ | Storm Water Form 1 _ RIght-of-Way Application/lnfo. ^/; Reference Documents
E-36 Page 6 of 6 REV 6/01/12
J
^ CARLSBAD
CITY OF
Memorandum
January 08, 2013
To: Van Lynch, Assistant Planner
From: Tecla Levy, Associate Engineer
Re: CD12-17- LEGOLAND TOLL BOOTH
Land Development Engineering (LDE) has completed its review of the above referenced project
and recommends approval. Please add the following requirements to the approval letter:
1. Based on our review of the preliminary grading plan, a minor grading permit must be
processed with the building permit.
2. Submit a construction revision to sheets 27 and 32 of the previously approved grading
plan, DWG 333-2Y, to include the proposed Legoland toll booth grading as shown on the
preliminary grading plan, sheet C-l ofthe Consistency Determination, CD 12-17.
3. Submit a Stormwater Management Plan (SWMP), a single sheet BMP map, a Stormwater
Pollution Prevention Plan (SWPPP) and earthwork quantity calculations with the
construction revision application requested in item 2 above.
4. Obtain fire department approval for the revised emergency fire access shown on the
preliminary grading plan, sheet C-l ofthe Consistency Determination, CD 12-17.
If you or the applicant has any questions regarding the above, please contact Tecla Levy at
extension 2733.
cc: File
Community & Economic Development
1635 Faraday Ave. I Carlsbad, CA 92008 I 760-602-2710 I 760-602-8560 fax | www.carlsbadca.gov
^ CITY OF
CARLSBAD
PLANNING DIVISION
BUILDING PLAN CHECK
REVIEW CHECKLIST
P-28
Development Services
Planning Division
1635 FaradayAvenue
(760) 602-4610
www carKbadra eov
DATE: 12/31/2012 PROJECT NAIVIE: Lego entry booths PROJECT ID: CD 12-17
PLAN CHECK NO: CB 12-2746 SET#: 2 ADDRESS: 1 LEGOLAND DRIVE APN: 211-100-09-00
^ This plan check review is complete and has been APPROVED by the Planning
Division.
By: Van Lynch
A Final Inspection by the Planning Division is required • Yes ^ No
Vou may also have corrections from one or more of the divisions listed below. Approval
from these divisions may be required prior to the issuance of a building permit.
Resubmitted plans should include corrections from all divisions.
IZZ This plan check review is NOT COMPLETE. Items missing or incorrect are listed on
the attached checklist. Please resubmit amended plans as required.
Plan Check Comments have been sent to: rwapel2@cox.net and
chris.romero@legoland.com
For questions or clarifications on the attached checklist please contact the following reviewer as marked:
PLANNiNG
760-602-4610
ENGINEERiNG
760-602-2750
FIRE PREVENTION
760-602-4665
Chris Sexton
760-602-4624
Chris.Sexton@carlsbadca.gov
1 Kathleen Lawrence
760-602-2741
Kathleen.Lawrence@carlsbadca.gov
1 Greg Ryan
760-602-4663
Gregorv.Ryan@carlsbadca.gov
Q Gina Ruiz
760-602-4675
Gina.Ruiz@carlsbadca.gov
1 1 Linda Ontiveros
760-602-2773
Linda.Ontiveros@carlsbadca.gov
Q Cindy Wong
760-602-4662
Cynthia.Wong@carlsbadca.gov
P] Van Lynch
760-602-4613
Van.lynch@carlsbadca.gov • 1 1 Dominic Fieri
760-602-4664
Dominic.Fieri@carlsbadca.gov
Remarks: pending approval of CD 12-17 for the Consistency Determination application for
the new toll booths.
Plan Check No CB 12-2746 Address 1 Legoland Dr Date 12/31/12/12 Review # 2
Planner Van Lvnch Phone (760) 602- 4613
Type of Project & Use commercial Net Project Density:n/a_DU/AC__
Zoning CT-Q General Plan: I^R Facilities Management Zone. 13
CFD (in/out) #_Date of participation: 1991 Remaining net dev acres:0
(For non-residential development Type of land use created by this permit: _)
REVIEW #:
12 3 Legend: ^ Item Complete • Item Incomplete - Needs your action
• • Environmental Review Required: YES • NO ^ TYPE
DATE OF COMPLETION
Compliance with conditions of approval If not, state conditions which require action.
Conditions of Approval
• lEl • Discretionary Action Required: YES • NO ^ TYPE
APPROVAL/RESO NO . DATE
PROJECT NO. CD 12-17
OTHER RELATED CASES SDP 96-14
Compliance with conditions or approval If not, state conditions which require action.
Conditions of Approval- Subiect to the pending approval of CD 12-17 Approved 1/16/2013
n D Coastal Zone Assessment/Compliance
Project site located in Coastal Zone"? YES Kl NO •
CA Coastal Commission Authonty'? YES Q NO El
If California Coastal Commission Authority. Contact them at - 7575 Metropolitan Drive,
Suite 103, San Diego, CA 92108-4402, (619) 767-2370
Determine status (Coastal Permit Required or Exempt): Exempt
Kl • • Habitat Management Plan
Data Entry Completed? YES • NO K
If property has Habitat Type identified in Table 11 of HMP, complete HMP Permit application
and assess fees in Permits Plus
(A/P/Ds, Activity Maintenance, enter CB#, toolbar, Screens, HMP Fees, Enter Acres of
Habitat Type impacted/taken, UPDATEi)
Kl • • Inclusionary Housing Fee required: YES • NO Kl
(Effective date of Inclusionary Housing Ordinance - May 21, 1993 )
Data Entry Completed? YES • NO •
(A/P/Ds, Activity Maintenance, enter CB#, toolbar, Screens, Housing Fees, Construct
Housing Y/N, Enter Fee, UPDATE!)
Kl • • Housing Tracking Form (form P-20) completed: YES • NOD N/A ^
p-28 Page 2 of 3 07/11
Site Plan:
^ • • Provide a fully dimensional site plan drawn to scale Show, North arrow, property lines,
easements, existing and proposed structures, streets, existing street improvements, right-of-
way width, dimensional setbacks and existing topographical lines (including all side and rear
yard slopes). Provide legal descnption of property and assessor's parcel number
City Council Policy 44 - Neighborhood Architectural Design Guidelines
• • 1. Applicability: YES • NO Kl
• • 2 Project complies-YES • NOQ
• •
• •
Zoning:
1 Setbacks:
Front
Intenor Side-
Street Side:
Rear-
Top of slope
Required 300: Shown > 300'
Required 45; Shown 56 5'
Required n/a Shown n/a
Required n/a Shown n/a
Required ri/a Shown n/a
2 Accessory structure setbacks:
Front: Required.
Interior Side Required
Street Side- Required,
Rear- Required.
Structure separation Required
Shown
Shown
Shown
Shown
Shown
• • 3. Lot Coverage. Required nia Shown 96 sq ft
• • 4. Height. Required < 45 feet Shown 9 5 feet
Kl D D 5. Parking Spaces Required . Shown No Change
(breakdown by uses for commercial and industrial projects required)
Residential Guest Spaces Required _ Shown
D n n Additional Comments
OK TO ISSUE AND ENTERED APPROVAL INTO COMPUTER ATE Januarv 23.2013
p-28 Page 3 of 3 07/11
V'ciTY OF
CARLSBAD
PLANNING DIVISION
BUILDING PLAN CHECK
REVIEW CHECKUST
P-28
Development Services
Planning Division
1635 FaradayAvenue
(760) 602-4610
www rarKbadra sov
DATE: 12/31/2012 PROJECT NAME: Lego entry booths PROJECT ID: CD 12-17
PLAN CHECK NO: CB 12-2746 SET#: ADDRESS: 1 LEGOLAND DRIVE APN: 211-100-09-00
• This plan check review is complete and has been APPROVED by the Planning
Division.
By: Van Lynch
A Final Inspection by the Division is required DYes Kl No
You may also have corrections from one or more of the divisions listed below. Approval
from these divisions may be required prior to the issuance of a building permit.
Resubmitted plans should include corrections from all divisions.
^ This plan check review is NOT COIVIPLETE. Items missing or incorrect are listed on
the attached checklist. Please resubmit amended plans as required.
Plan Check Comments have been sent to: rwapel2@cox.net and
chris.romero@legoland.com
For questions or clarifications on the attached checklist please contact the following reviewer as marked:
PLANNING
760-602-4610
ENGINEERING
760-602-2750
FIRE PREVENTION
760-602-4665
1 1 Chris Sexton
760-602-4624
Chris.Sexton@carlsbadca.gov
1 1 Kathleen Lawrence
760-602-2741
Kathleen.Lawrence@carlsbadca.gov
Greg Ryan
760-602-4663
Gregorv.Ryan@carlsbadca.gov
1 1 Gina Ruiz
760-602-4675
Gina.Ruiz@carlsbadca.gov
1 1 Linda Ontiveros
760-602-2773
Linda.Ontiveros@carlsbadca.gov
1 1 Cindy Wong
760-602-4662
Cvnthia.Wong@carlsbadca.gov
X Van Lynch
760-602-4613
Van.lynch@carlsbadca.gov • 1 1 Dominic Fieri
760-602-4664
Dommic.Fieri@carlsbadca.gov
Plan Check No CB12-2746 Address 1 Legoland Dr Date 12/31/12/12 Review # 1
Planner Van Lvnch Phone (760) 602- 4613
Type of Project & Use. commercial Net Project Density n/a DU/AC
Zoning CT-Q General Plan. I^R Facilities Management Zone 13
CFD (in/out) #_Date of participation 1991 Remaining net dev acres;0
(For non-residential development. Type of land use created by this permit: _)
REVIEW #:
12 3 Legend: Kl Item Complete • Item Incomplete - Needs your action
S • • Environmental Review Required: YES • NO ^ TYPE
DATE OF COMPLETION
Compliance with conditions of approval? If not, state conditions which require action.
Conditions of Approval-
• • • Discretionary Action Required: YES • NO K TYPE
APPROVAL/RESO. NO , DATE
PROJECT NO. CD 12-17
OTHER RELATED CASES. SDP 96-14
Compliance with conditions or approval? If not, state conditions which require action.
Conditions of Approval: Subiect to the pending approval of CD 12-17.
Kl n Ll Coastal Zone Assessment/Compliance
Project site located in Coastal Zone? YES Kl NO •
CA Coastal Commission Authority? YES • NO Kl
If California Coastal Commission Authonty- Contact them at - 7575 Metropolitan Drive,
Suite 103, San Diego, CA 92108-4402, (619) 767-2370
Determine status (Coastal Permit Required or Exempt). Exempt
13 • • Habitat Management Plan
Data Entry Completed? YES • NO K
If property has Habitat Type identified in Table 11 of HMP, complete HMP Permit application
and assess fees in Permits Plus
(A/P/Ds, Activity Maintenance, enter CB#, toolbar, Screens, HMP Fees, Enter Acres of
Habitat Type impacted/taken, UPDATE!)
Kl • • Inclusionary Housing Fee required: YES • NO Kl
(Effective date of Inclusionary Housing Ordinance - May 21, 1993 )
Data Entry Completed'? YES • NO •
(A/P/Ds, Activity Maintenance, enter CB#, toolbar, Screens, Housing Fees, Construct
Housing Y/N, Enter Fee, UPDATE')
Kl • • Housing Tracking Form (form P-20) completed: YES • NO • N/A K
p-28 Page 2 of 3 07/11
Site Plan:
K • • Provide a fully dimensional site plan drawn to scale. Show: North arrow, property lines,
easements, existing and proposed structures, streets, existing street improvements, right-of-
way width, dimensional setbacks and existing topographical lines (including all side and rear
yard slopes). Provide legal description of property and assessor's parcel number
City Council Policy 44 - Neighborhood Architectural Design Guidelines
• • 1 Applicability YES • NO Kl
• • 2. Project complies. YES • NOn
• •
• •
Zoning:
1 Setbacks.
Front.
Interior Side-
Street Side
Rear:
Top of slope:
Required 300: Shown > 300'
Required 45^ Shown 56 5'
Required nia Shown n/a
Required n/a Shown n/a
Required n/a Shown n/a
2 Accessory structure setbacks.
Front. Required
Interior Side Required
Street Side. Required
Rear Required
Structure separation. Required
Shown
Shown.
Shown
Shown
Shown
K • •
K • •
K • •
• • •
3 Lot Coverage
4. Height
5 Parking:
Required n/a Shown 96 sq ft
Required < 45 feet Shown 9 5 feet
Spaces Required _ Shown No Change
(breakdown by uses for commercial and industrial projects required)
Residential Guest Spaces Required _ Shown
Additional Comments
OK TO ISSUE AND ENTERED APPROVAL INTO COMPUTER DATE
P-28 Page 3 of 3 07/11
CITY OF
CARLSBAD
PLAN CHECK
REVIEW
TRANSMITTAL
Community & Economic
Development Department
1635 Faraday Avenue
Carlsbad CA 92008
www.carlsbadca.gov
DATE: 1/23/13 PROJECTNAME: legoland calif toll booth PROJECTID:
PLAN CHECK NO: cbl22746 SET#: II ADDRESS: 1 legoland dr APN:
3 This plan check review is complete and has been APPR0VEli^i^5& ftfe Division. ^Opy
By: cwong
A Final Inspection by the Division is required Kl Yes • No
IZZ This plan check review is NOT COMPLETE. Items missing or incorrect are listed on
the attached checklist. Please resubmit amended plans as required.
Plan Check Comments have been sent to: chris.romero@legoland.com
Vou may also have corrections from one or more of the d/V/s/ons Usted below. Approval
from these divisions may be required prior to the issuance of a building permit
Resubmitted plans should include corrections from all divisions.
For questions or clarifications on the attached checklist please contact the following reviewer as marked:
PLANNING
760-602-4610
ENGINEERING
760-602-2750
FIRE PREVENTION
760-602-4665
1 1 Chris Sexton
760-602-4624
Chris.Sexton@carlsbadca.gov
1 1 Kathleen Lawrence
760-602-2741
Kathleen.Lawrence@carlsbadca.gov
Q Greg Ryan
760-602-4663
Gregory.Rvan@carlsbadca.gov
1 1 Gina Ruiz
760-602-4675
Gina.Ruiz@carlsbadca.gov
1 1 Linda Ontiveros
760-602-2773
Linda.Ontiveros@carlsbadca.gov
X Cindy Wong
760-602-4662
Cvnthia.Wong@carlsbadca.gov
• • 1 1 Dominic Fieri
760-602-4664
Dominic.Fieri@carlsbadca.gov
Remarks:
** APPROVED:
THIS PROJECT HAS BEEN REVIEWED AND APPROVED FOR THE PURPOSES OF ISSUEANCE
OF A BUILDING PERMIT.
Page I of 2
THIS APPROVAL IS SUBJECT TO FIELD INSPECTIONS, ANY REQUIRED TESTS, FIRE
DEPARTMENT NOTATIONS, CONDITIONS IN CORRESPONDENCE AND COMPLIANCE WITH
ALL APPLICABLE CODES AND REGULATIONS.
THIS APPROVAL SHALL NOT BE HELD TO PERMIT OR APPROVE ANY VIOLATION OF THE
LAW.
*** Bubble All Changes***
1. Reference 24' Emergency Access on West Side. Show inside and outside turning dimension for fire department
apparatus utilizing the 24' access road. After turn, show that 24' access is maintained.
2. Note on plans that existing gate be fully functional via acceptance test at time of final inspection.
Page 2 of 2
Carlsbad Fire Department
Plan Review Requirements Category: TI, COMM
Date of Report: 01-23-2013
RICHARD APEL
Reviewed by:
Name:
Address:
57l-B HYGEIA AV
LEUCADIA CA
92024
Permit #: CBI22746
Job Name: LEGOLAND
Job Address: 1 LEGOLAND DR CB AD
INCOMPLETE The item you have submitted for review is incomplete. At this time, this office cannot
adequately con
carefully all comments atta^ed,j,«£lease°TSsubmit thenecess3^'T?lasis»aH4 with changes "clouded",
to this office fo|ix^ag^?f°gfi3approval.
Conditions:
Cond: CON0005988
[NOT MET]
*** Bubble All changes***
1. Reference 24' Emergency Access on West Side. Show inside and outside tuming dimension for fire
department apparatus utilizing the 24' access foad. After tum, show that 24' access is maintained.
2. Note on plans that existing gate be fully functional via acceptance test at time of fmal
inspection.
Entry: 01/03/2013 By: cwong Action: CO
Cond: CON0006039
[MET]
**APPROVED:
THIS PROJECT HAS BEEN REVIEWED AND APPROVED FOR THE PURPOSES OF ISSUEANCE OF A
BUILDING PERMIT.
THIS APPROVAL IS SUBJECT TO FIELD INSPECTIONS, ANY REQUIRED TESTS, FIRE DEPARTMENT
NOTATIONS,
CONDITIONS IN CORRESPONDENCE AND COMPLIANCE WITH ALL APPLICABLE CODES AND
REGULATIONS.
THIS APPROVAL SHALL NOT BE HELD TO PERMIT OR APPROVE ANY VIOLATION OF THE LAW.
Entry: *bl/23/2013 By: cwong Action: AP
D.UNN SAVOIE INC.
STRUCTURAL ENGINEERS
.' , gpa.S -CL'EVELAKip'ST
' _ a'CEANSIDE, GA-92054
,76D-96'6.635'5 PR \-
760.966'esao FX' ' •
DSt@SURFDSl.CpM-EM Al L
STRUCTURAL CALCULATIONS
FOR
LegoLand - New Toll Booth Anchorage
. . - One Legoland Drive Z , ;
Z Carlsbad, CA 92008Z Z'
(DSI PROJECT NO. 12-185.00)
(ARCHITECT: R W Apel Landscape Architects, Jnc.)
pEeEMBER 20, 2012
TABLE OF CONTENTS
ITEM • _ ; •
DESIGN CRITERIA : / .
NEW TOOL BOOTH LATERAL FORCE ANALYSIS
. WIND ANALYSIS , .• ]
SIMPSON'SET-XP'EPOXY ANALYSIS
siMspoN 'WEDGE-ALL'ANCHOR SPEC, SHEETS
FOOTING ANALYSIS. : ,
Dunn Savoie Inc.
Structural Engineers
908 S. Cleveland St.
Oceanside, CA 92054
Tel: (760) 966-6355
Fax: (760) 966-6360
JOB LegoLand - Toll Booth Anchorage
SHEET NO 1 OF
CALCULATED BY SRG DATE 12/12
CHECKED BY DATE
SCALE
DESIGN CRITERIA
CODE:
SEISMIC:
2009 International Building Code (IBC)
2010 California Building Code (CBC)
Buildina Occupancv Categorv II
Seismic Desiqn Cateqorv: D
IE = 1.00
Fa = 1.000
Fv = 1.521
SDS = 0.846
SDI -0.486
1 = 0.108 sec
R = 2.0
no = 2.5
Cd = 2.0
Seismic Base Shear: V = 1 .OE = 0.423 *W (Strength Design)
V = 0.7E = 0.296 *W (ASD)
Vw/p=1.3= 0.385 *W ASD Seismic Design Force
WIND: Basic Wind Speed = 85 MPH (3-sec Gust)
Exposure = C
CONCRETE: ACI 318-08
FOUNDATION CRITERIA
ALLOWABLE SOIL PRESSURE FOR D+L 1500 PSF
DUNN SAVOIE INC.
STRUCTURAL ENGINEERS
908 S. Cleveland Street
OCEANSIDE, CA 92054
PH. (760) 966-6355 FAX (760) 966-6360
Email: dsi@surfdsi.com
SHEET NO . 0F_
CALCULATED BY_
CHECKED BY
DATE.
DATE.
SCALE .
^/e^'Je^y^A^y ^^^-I^^M]...^;^ ^'^^' y^^p^-J^ir^
D PRODUCT 207
Dunn Savoie lr>c
Structural Engineerc
908 S Cl«v»land St
Oceanside, CA 92054
Tel- (760)966-6355
Fax (760) 966-6360
JOB Legoland - Toll Booth Anchorage
SHEET NO OF
CALCULATED BY SRG DATE 12/12
CHECKED BY DATE
SCALE
>^SCE 7-05 Wind Lateral Desian Analvsis For Rigid Structures With Flat Roofs
r " —
Directionallv Independent: , - —
Desion Parameters: !
BuildJng Category = II Top of Roof Elevation 9.5 ft
Importance Factor, 1 = 1 00 Top of Parapet Elevation 95 ft
Basic Wind Speed (3-sec, mph), V = 85 Max Honzontal Dimension 12 tt
Exposure Category = C Mm Honzontal Dimension 4 33 ft
Directionality Factor, = 0 85 Parapet Factor Windward 1 5
(0 = 1 Parapet Factor Leeward -1 0
Velocity Pressure Exposure Coefficient:
a= 95
Zg = 900 ft
Structure Height (tt)
Kz = 2 0r(z/Zg7^=| 0 77
Topographic Factor:
95 95 9.5 95 95 9 5 95 Parapet
0 77 0.77 0 77 0 77 0.77
2-D Ridgel X 12-D EscarpQ 3-D Hill r
Elevation Change, H = 10 ft
Crest to Mid-Height, Lh = 1 ft
Dist from Crest, x = 0 ft
H / Lh = 0 50 MAX
0 77 0 77
("X" One Box)
< 15ft Topographic Factor NOT Required
Downwind of Crest' | No "j (Yes or No)
K, =
= 1 - (|x|/nLh) =
0 73
1 00
3.0
1.5
Structure Height (ft) 9.5 95 95 95 95 95 95 Parapet
K3 = e""^'" =
= (1 + K, KJ K,)^ =
0.24
1 00
0.24
1 00
0 24
1 00
0 24
1 00
0 24
1 00
0.24
1 00
0 24
1 00
0 24
1 00
Velocity Pressure:
Stmcture Height (ft) 95 9.5 95 95 95 95 95 Parapet
qz = 0.00256 K^ K^ K<( I co =1 12 12 12 12 12 12 12 12 12 12 12 12 1212 12 12 psf
Directionallv Dependent:
Gust Effect Factor: Gs = 0.850
External Pressure Coefficients:
Short Direction: | Windward Leeward
Walls, Cp =\ 08 -0 50
GL = 0.850
Long Direction:
Walls, Cp ••
Windward Leeward
08 -0 26
Desiqn Wind Pressures:
Short Direction:
Pwalls =
Windward Leeward
Gs Cp =1 See Below -5 15 psf
Leeward Parapet
-12 12 psf
Structure Height (ft) 95 95 95 95 95 95 95 Parapet
Pwalls ~ Pz Os Cp = 8.24 8 24 8 24 8.24 8 24 8 24 8.24 18 18 psf
Ptotai = qz Gs Cp -Ph Gs Cp= 13.40 13.40 13.40 13.40 13.40 13.40 13.40 30.31 psf
Long Direction: Windward Leeward Leeward Parapet
Pwalls ~ GL Cp = See,Beiow -2.69 psf -12.12 psf
structure Height (ft) 95 95 95 9 5 9.5 95 95 Parapet
Pwaiis - Qz GL Cp = 8 24 8 24 8 24 8 24 8 24 8 24 8.24 18 18 psf
PtDiai = Qz Gs Cp -cih Gs Cp= 10.94 10.94 10.94 10.94 10.94 10.94 10.94 30.31 psf
Buildinq Elements:
(+) GCp (-) GCp GCp, Force at Highest Elev
Walls AAain-(4): P= qh[(GCp)-(GCp,)] EQ 6-22 0 93 -1 1 -0 18 15.52 psf
Walls Corners-(5): P= qh[(GCp)-(GCp,)] EQ 6-22 1 -1 2 -0 18 16.73 psf
Parapets: P= qp(GCp-GCp,) EQ 6-24 22 -0 26.67 psf
Main Roof Uplift-(l): P= qh[(GCp)-(GCp,)] EQ 6-22 1 -0 8 0 18 14.30 psf
Roof uplift at Ends and Peal(S-(2)-p= qh[(GCp)-(GCp,)] EQ 6-22 1 1 -1 0 0 18 15.52 psf
Dunn Savoie Inc.
Structural Engineers
908 S. Cleveland St.
Oceanside, CA 92054
Tel: (760) 966-6355
Fax: (760)966-6360
JOB LegoLand - Toll Booth Anchorage
SHEET NO A-OF
CALCULATED BY SRG DATE 12/12
CHECKED BY DATE
SCALE
SIMPSON SET-XP EPOXY ANCHOR ANALYSIS
Using ESR-2508 & ACI318-08
Input:
Anchor Diameter = 0.625 in
c = 6 in (edge distance of anchor)
hef = 4.00 in (anchor embedment depth)
fc = 2500 psi (concrete strength)
^max ~ 472 Ibs
Tension„ax = 1603 Ibs
Ca mm ~~ 1.75 <Table 1 > Nsa = 12880 lbs<Table2>
kc = 17 <Table 4> cf, = 0.75 <Table 4>
fc,N = 1.0 <D.5.2.6> ^k, uncr ~ 2075 <Table 5>
Y'cp,N = 1.0 <D.5.2.7> ''"k, cr -855 <Table 5>
V'p,Na -1.0 <D.5.3.14>
Output:
Factored Loads: <Der ACI 318, 9.2.1>
Nua = 2565 Ibs
Vua = 755 Ibs
steel Caoacitv in Tension:
9660 Ibs > 2565 Ibs, Therefore OK.
Concrete Breakout Caoacitv:
6800.00
l^ed.N = 0.79 use V/ed,N = 0.79
1.5he,= 6.00 in
ANC ~ 144.00 in^
ANCO -144 00 in^
4029 Ibs > 2565 Ibs, Therefore OK.
Adhesive Anchor Caoacitv:
Nao = 6715.154 Ibs
Scr,Na ~ 14.95 in use Scr.Na ~ 12.00 in
3he,= 12 in
Ccr,Na ~ 7.48 in
^Na ~ 201.53 in^
ANBO ~ 223.5 in^
V'ed,Na " 0 77 use 'l/'ed,Na = 0.77
4'N3 = 3497 Ibs > 2565 Ibs, Therefore OK.
Dunn Savoie Inc.
Structural Engineers
908 S Cleveland St.
Oceanside, CA 92054
Tel: (760)966-6355
Fax: (760)966-6360
JOB LegoLand - Toll Booth Anchorage
SHEET NO OF
CALCULATED BY SRG DATE 12/12
CHECKED BY DATE
SCALE
SIMPSON SET-XP EPOXY ANCHOR ANALYSIS
Using ESR-2508 & ACI318-08
Input:
Anchor Diameter = 0.625 in
c = 6 in (edge distance of anchor)
hef = 4.00 in (anchor embedment depth)
fc = 2500 psi (concrete strength)
^max ~ 472 Ibs
Tension^ax = 1603 Ibs
Ca mm ~ 1.75 <Table 1 > Vsa = 7730 Ibs <Table 2>
kc = 17 <Table 4> $ = 0.65 <Table 4>
fo.\/ = 1.0 <D.5.2.6> ^k, uncr ~ 2075 <Table 5>
i^cp.n = 1.0 <D.5.2.7> '''k, cr -855 <Table 5>
';^p,Na = 1.0 <D.5.3.14>
Output:
Factored Loads: <oer ACI 318. 9.2.1 >
Nua = 2565 Ibs
Vua = 755 Ibs
Steel Caoacitv in Shear.
<i'Vsa = 5025 Ibs > 755 Ibs, Therefore OK.
Concrete Breakout Caoacitv:
Vb = 6163.86 Ibs
Y'ed.N = 1.00 use ^ed,N = 1.00
1.5031 = 9.00 in
Ave ~ 162.00 in^
Avco ~ 162.00 in^
'i'Veb = 4007 Ibs > 755 Ibs, Therefore OK.
Concrete Prvout Caoacitv
kcp ~ 2.0 Ibs
Na = 4662.39 Ibs
Ncb = 5372 Ibs
Vcp = 9324 78 in
6061 in^ > 755 Ibs, Therefore OK.
SM, V
Wedge Anchors
Tension Loads for Stainless Steel Wedge-All Anchors In Normal-Weight Concrete t
Size
in.
(mm)
Embed.
Depth
In.
(mm)
Critical
Edge
Dist.
in.
(mm)
Critical
Spacing
in.
(mm)
AJIowable.fensiqh Load,-ibs-fO(N|4-'f^^ Install.
Torque
'"ftllbs
/ , '. r
Size
in.
(mm)
Embed.
Depth
In.
(mm)
Critical
Edge
Dist.
in.
(mm)
Critical
Spacing
in.
(mm)
fc >= 2000 psi'
(13.8,IVIPa)
Concrete
f'c >= 3000 psi"
(20l7:iVIPa)
' CDncrete
f'c >= 4000 psi"
'(27l6pPa)*
Concrete
Install.
Torque
'"ftllbs
/ , '. r
1/4
(6 4)
1 1/8 2 1/2
(64)
1 5/8
(41)
155
(0 7)
185
(0 8)
215
(1 0) 8
(10 8)
1/4
(6 4) 2 1/4
(57)
2 1/2
(64)
3 1/8
(79)
430
(1 9)
475
(21)
520
(2 3)
8
(10 8)
3/8
(9.5)
1 3/4
(44)
3 3/4
(95)
2 3/8
(60)
350
(16)
500.;; '
- .-(2;2)>,;,''
''-•i650'i.'f - • •
3/8
(9.5)
2 5/8
(67)
3 3/4
-'(95)
3 5/8
(92)
755 '
(3 4) • -
; 990 .rr
••• •=-• (4:4j,i;,;-
3/8
(9.5)
3 3/8
- (86)
3 3/4
(95)
4 3/4
(121)
830
(3'7)' ,
'. •.,1-,025.fv:'
,l(4*)\Jt/\:-
1/2
(12 7)
2 1/4
(57)
5
(127)
3 1/8
--JZl) _
740
(3 3)
965
(4 3)
1,190
(5 3)
80
(81 3)
1/2
(12 7)
3 3/8
(86)
5
(127)
4 3/4
(121)
1,360
(6 0)
1.785
(7.9)
2,215
(9 9)
80
(81 3)
1/2
(12 7)
4 1/2
(114)
5
(127)
6 1/4
(159)
1.565
(7 0)
2.115
(9 4)
2.665
(119)
80
(81 3)
/my n^)
,2,3/4
•^(ZDL
6 1/4 .
. ^(159)V'
3J/8
iv(98) -
•1,015 O ., 1;935
=i*;i?'(8!6iS^3il
•i{122';OJ5ji
/my n^) ^4.1/^ .6,,1/4
>-(159)"
,'6'1/4
.••(159)
i;"S':g-3;535S>'i>>'
•i{122';OJ5ji
/my n^)
5 1/2
.. (i'40):'
• •6;ci/4'-. . '(159),:.;
JJ3/4 -
-.-f:i97)'"
:'-'.' l;845;V',>' - . (f2^^ >•
•i{122';OJ5ji
3/4
(191)
3 3/8
(86)
7 1/2
(191)
4 3/4
(121)
1,520
(6 8)
1.880
(8 4)
2,240
(10 0)
150
(203 4)
3/4
(191)
5
(127)
7 1/2
(191)
7
(178)
2,260
(101)
2,905
(12 9)
3,545
(15 8)
150
(203 4)
3/4
(191)
6 3/4
(171)
7 1/2
(191)
9 1/2
(241)
2,260
(101)
3.040
(13 5)
3,825
(17 0)
150
(203 4)
,7/8
(22.2)
' 3;7/8,
.,.•(98) •
8:3/;4r..-
.;j:222),'
5r3/8 7.
' ^^(137) :f
•.i,685::.'.'-r;.-;",i'-."i*2i05op-tH
-'i''j¥'(9l#5.f!"l
2v41D ,7/8
(22.2) VW
' (206f'
,8-3/4
: (222),
, 11 •
- (279)
' 1, 3i835.',-;:^'-> '' • ••'-,;,4i205ft'.
nis^fS?!
4,570
vfc*(2Cg3i5tf
1
(25 4)
4 1/2
(114)
10
(254)
6 1/4
(159)
3.465
(15 4)
3.495
(15 5)
3,530
(15 7) 300
(406 7)
1
(25 4) 9
(229)
10
(254)
12 5/8
(321)
4.670
(20 8)
5.720
(25 4)
6,770
(301)
300
(406 7)
1 1/4
(31.8)'
5 5/8
; .(143)
12,1/2
(318)'
; 7 ,7/8 ,
(200) .
•r 3,410'
:a5-2)!-^v-'
4,490 5.570
;-'>';::(2458i!:li'?,-'
"•(542r3):<
1 1/4
(31.8)' 9 1/2-
• (241)
12 1/2
(318)
13'1/4
- ,(337)
•,',4,535''>-'.;
' ,-(2o''2)'^'..; --''!;' •^•^a^QiS
- •'i-'l(34-6)'*'i,'f''
11.005
i'^'mMk:-"
"•(542r3):<
1 1/2
(381)
9 1/2
(241)
12 1/2
(318)
13 1/4
(337)
4,535
(20 2)
7.770
(34 6)
11,005
(49 0)
400
(542 3)
1 The allowable loads listed are based on a safety factor of 4 0
2 Allowable loads may be increased by 3373% tor short term loading due to wind or seismic forces
where permitted by code
3 Refer to allowable load adjustment factors for edge distance and spacing on pages 112 & 114
4 Drill bit diameter used in base material corresponds to nominal anchor diameter
5 Allowable loads may be linearly interpolated between concrete strengths listed
6 The minimum concrete thickness is iy2 times the embedment depth
*See page 5 for an
explanation of the
load table icons
109
SIMPSON
Strong^Tie ;
I ANCHOR GYSTEMS ; Wedge Anchors
Shear Loads for Stainless Steel Wedge-All Anchors In Normal-Weight Concrete tti
Size
in.
(mm)
Embed.
Depth
in.
(mm)
Critical
Edge
Dist.
in.
(mm)
Critical
Spacing
in.
(mm)
Allowable Shear Load lbs. (kN) Install.
Torque
n-lbs
(N-m)
Size
in.
(mm)
Embed.
Depth
in.
(mm)
Critical
Edge
Dist.
in.
(mm)
Critical
Spacing
in.
(mm)
f'c>= 2000 "psi
(13.8 MPa)
Concrete' -
i;
f'c >= 3000 psi
(20.7>MRa)
Concrete
f'c >= 4000 psi
(27.6 MPa) Concrete
Install.
Torque
n-lbs
(N-m)
1/4
(6 4)
1 1/8
(29)
2 1/2
(64)
1 5/8
(41)
265
(1 2)
265
(1 2)
265
(1 2) 8 1/4
(6 4) 2 1/4
(57)
2 1/2
(64)
3 1/8
(79)
265
(12)
265
(1 2)
265
(1 2)
(10 8)
3/8
(9.5)
1 3/4
(44)
3 3/4
(95)
2 3/8
(60)
655
(29), ,
- 655
• (2^9)
655
(2 9) ,
30
(40 7)
3/8
(9.5)
2 5/8
.. (67)
3 3/4
, (95)
3 5/8
(92)-,
1.215 -
(5.4)" •••'-• .
1,215. •
.-••"-;(5-4^,
1,215
' (5 4)
30
(40 7)
3/8
(9.5)
3 3/8
(86)
3 3/4
"(95)
4-3/4
. (121)
1,215 "
(5.4): ^••'
1,215' •
(5M), • •-
1i215 ,
.l5'4)
30
(40 7)
1/2
(12 7)
2 1/4
(57)
5
(127)
3 1/8
(79)
1.545
(6 9)
1,710
(7 6)
1,870
(8 3)
60
(81 3)
1/2
(12 7)
3 3/8
(86)
5
(127)
4 3/4
(121)
1.925
(8 6)
2.130
(9 5)
2,325
(10 3)
60
(81 3)
1/2
(12 7)
4 1/2
(114)
5
(127)
6 1/4
(159)
1,925
(8 6)
2,130
(9 5)
2,325
(10 3)
60
(81 3)
(
059)
' ,2 3/4- •
- ''mL-.
. 6 1/4
' (159)
,3 7/8
.r^(98)
1,865 V-'" r2,185', -1 •"•
; 'smh-r^,'--
. 21505
" (Il.l): ••. ,90
(122.0) (
059) -rm 6.1/4
' (.159)-
6 1/4
'ai59)
. 3,150 . 3;615
bi^ri). :
,90
(122.0) (
059) •5;l/2'--
• (.f40);
',-6;i/4'
(159).-
.7,;3/4
., (197) •,
• 2,680 : ; •• »:.f.3',150,;,''' :
•M;HIW' •
; ^3;615';
''-•• (iB i) '.
,90
(122.0)
3/4
(191)
3 3/8
(86)
7 1/2
(191)
4 3/4
(121)
3,265
(14 5)
3,265
(14 5)
3,265
(14 5)
150
(203 4)
3/4
(191)
5
(127)
7 1/2
(191)
7
(178)
5.300
(23 6)
5,300
(23 6)
5,300
(23 6)
150
(203 4)
3/4
(191)
6 3/4
(171)
7 1/2
(191)
9 1/2
(241)
5.300
(23 6)
5,300
(23 6)
5,300
(23 6)
150
(203 4)
7/8 _ \
(22:2)'
3'.7/8:i.
"v(98)t^.'
•'8j3/4 •
~.v(222).',
.;'5;3/8'.
>i':(i37.).,.
3,955 ; ,S
•(i,7;6)f*'?i'
"••i~-''---'3i955'r'::''
; •^%?(iK6yitr
3;955 > ,
2ljp
, (271 2)
7/8 _ \
(22:2)' -757/8^5
"•(200) "
'•8-3/4 •"
• (222)
-•';,T11.,-
i „(2'79)'
.•^f""6;410f*i?ff
' -(28:5)v; ;
.'•;^;i6';4ior,> -•-
V:':(28-5)S'.
- .i, •6,410: '
i .•.(28-5)' > "
2ljp
, (271 2)
1
(25 4)
4 1/2
(114)
10
(254)
6 1/4
(159)
6,590
(29 3)
6,590
(29 3)
6,590
(29 3) 300
(406 7)
1
(25 4) 9
(229)
10
(254)
12 5/8
(321)
7,295
(32 4)
7,295
(32 4)
7,295
(32 4)
300
(406 7)
11/4
' (3,1.8)'
5 5/8
' (143)
12.1/2
'•.(318)
. 7>7/8
•"(260) ••
• 8,430 ! ,
: '(37 5)' y '-.
. 8,430i .•
,1 ,'(375V--'
,8,430
.•,(37.5) 41)0
(542^3)
11/4
' (3,1.8)' 9 1/2
• (241) .
12 1/2
• -(SIS)"-.
13-1/4
- (337) '
8,430 ;
(37:5)::-:,v
' 8,430
. , ^(37-5) /
8,430
,r(375)
41)0
(542^3)
1 1/2
(381)
9 1/2
(241)
12 1/2
(318)
13 1/4
(337)
8,430
(37 5)
8,430
(37 5)
8,430
(37 5)
400
(542 3)
1 The allowable loads listed are based on a salety factor of 4 0
2 Allowable loads may be increased by 16% for short term loading due to wmd or seismic forces
where permitted by code
3 Refer to allowable load adiustment factors for spacing and edge distance on pages 112,113 & 115
4 Drill bit diameter used in base material corresponds to nominal anchor diameter
5 Allowable loads may be linearly interpolated between concrete strengths listed
6 The minimum concrete thickness is VA times the embedment depth
*See page 5 for an
explanation of the
load table icons
10
Dunn Savoie Inc.
Structural Engineers
908 S. Cleveland St.
Oceanside, CA 92054
Tel: (760)966-6355
Fax: (760) 966-6360
JOB Legoland - Toll Booth Anchorage
SHEET NO OF
CALCULATED BY SRG DATE 12/12
CHECKED BY DATE
SCALE
IFOUNDATION DESIGN |
Allowable Bearing Pressure, q =_1;^^_ psf
(2 per soils report
• assumed
Continous Footings:
Location:
w1 =
Width Req'd = (w1/q)x 12 =
pit
\i^^
Use: 1^ "Widex 12- "Deep with ^ # Top & Bottom
Location:
w1 = = plf
Width Req'd = (w1/q)x 12 = = II
Use: " Wide x " Deep with # Top & Bottom
Location:
w1 = plf
Width Req'd = (w1/q)x 12 = = II
Use: " Wide x " Deep with # Top & Bottom
/S^-
Pad Footings: ^s^-p-.
Mark:
P = Ibs
Area Req'd = (P/q) x 144 = in^
Use: " Square x " Deep with # Ea Way (3" Clear from Soil)
Mark:
P = Ibs
Area Req'd = (P/q) x 144 = in^
Use: " Square x " Deep With # Ea. Way (3" Clear from Soil)
Mark:
P = Ibs
Area Req'd = (P/q) x 144 = in^
Use: " Square x " Deep with # Ea. Way (3" Clear from Soil)
IICAL UPDATE AND PLAN REVIEW
IRKING LOT TOLL BOOTH ADDITION
EGOLAND CALIFORNIA
wARLSBAD, CALIFORNIA
Prepared for:
LEGOLAND CALIFORNIA, LLC
One Legoland Drive
Carlsbad, California 92008
Project No. 10075.001
December 21, 2012
4
Leighton and Associates
A LEIGHTON GROUP COMPAMY
11 iW.
Leighton and Associates, Inc.
December 21, 2012
Project No. 10075.001
LEGOLAND California
One Legoland Drive
Carlsbad, California 92008
Attention: Mr Chns Romero
Subject: Geotechnical Update and Plan Review
Proposed Parking Lot Toll Booth Addition
LEGOLAND California, Carlsbad, California
Introduction
In accordance with your request and authorization, this report has been prepared to
provide geotechnical recommendations and to provide grading plan review relative to the
proposed Parking Lot Toll Booth Addition project at LEGOLAND California in Carlsbad,
California (Figure 1).
Proposed Development
Based on our review of the grading plans (Chang, 2012), we understand the site
improvements will include the construction of two (2) new toll booths atthe mam vehicle
entrance to the park. Associated vehicular pavement, underground utilities, flatwork, a
desilting basin, and landscaping are also planned. Grading will consist of cuts up to 9 feet
and minor fills up to 2 feet from the existing ground surface.
3934 Murphy Canyon Road, Suite B205 ~« San Diego. CA 92123-4425
858 292 8030 B Fax 858 292 0771 ^ www leightongroup com
10075 001
Findings and Conclusions
Based on our review ofthe final as-graded report of rough gradmg (Leighton, 1998a), the
following Items were noted:
• The location ofthe proposed improvements is within an area underlain by existing
documented fill placed as part of the original mass grading of the park and by
Quaternary-aged Terrace Deposits and Tertiary-aged Santiago Formation.
• IVIinor grading will be required to construct the proposed improvements and will result
in constructing 2:1 (H:V) slopes up to 10 feet in height.
• Based on our professional experience on sites in the general vicinity and the final as-
graded report of rough grading (Leighton, 1998a), the on-site soils possess a very low
to low expansion potential and a negligible soluble sulfate content. Laboratory testing
upon completion of fine grading operations forthe proposed toll pad is recommended
to determine actual expansion potential of finish grade soil atthe site.
• Ground water is not considered to be a constraint to the proposed improvements.
However, if seepage conditions are encountered during site grading, additional
evaluation should be provided to determine if subdrainage measures are needed,
In conclusion, it is our professional opinion that the parking lot toll booth and ancillary
improvements are suitable for its intended use provided the recommendations presented
herein are incorporated into the design and construction ofthe proposed improvements.
Recommendations
The following recommendations should be followed during the design and construction of
the proposed improvements. We anticipate that earthwork on the site will consist of
demolition and removal of the existing hardscape and landscaping improvements in
preparation for construction of the proposed improvements. We recommend that
earthwork on the site be performed in accordance with the following recommendations,
the City of Carlsbad grading requirements, and the General Earthwork and Grading
Specifications of Rough-Grading included in Appendix B, In case of conflict, the following
recommendations shall supersede those in Appendix B.
10075,001
1) Site Preparation
We recommend that in the areas of proposed development the surficial soils be
scarified to a minimum depth of 12 inches, moisture-conditioned to optimum or above
moisture content and compacted to a minimum 90 percent relative compaction (based
on ASTM Test Method D1557). Areas to receive fill or pavement should be cleared of
subsurface obstructions, potentially compressible material (such as loose
landscaping soils and undocumented fill) and stripped of vegetation prior to grading.
Vegetation and debris should be removed and properly disposed of offsite, Holes
resulting from removal of buried obstructions and abandoned utilities that extend
below finish site grades should be replaced with suitable compacted fill material.
Areas to receive fill and/or other surface improvements should be scarified to a
minimum depth of 12 inches, brought to optimum or above optimum moisture
condition, and recompacted to at least 90 percent relative compaction, or to
95 percent relative compaction in pavement sections (based on ASTM Test Method
D1557).
2) Excavations
Excavations ofthe on-site materials may generally be accomplished with conventional
heavy-duty earthwork equipment. It is not anticipated that significant quantities of
oversized rock (i.e., rock with maximum dimensions greater than 6 inches) will be
generated during future grading. However, if oversized rock is encountered, it should
be hauled offsite, or placed in non-structural or landscape areas.
Excavation of utility trenches should be performed in accordance with the project
plans, specifications and all applicable OSHA requirements. The contractor should be
responsible for providing the "competent person" required by OSHA standards
Contractors should be advised that sandy soils and/or adversely oriented bedrock
structures can make excavations particularly unsafe if not all safety precautions are
taken,
10075 001
3) Fill Placement and Compaction
The on-site soils are generally suitable for use as compacted fill provided they are free
of organic material, debris, and rock fragments larger than 6 inches in maximum
dimension. All fill soils should be brought to optimum or above optimum moisture
conditions and compacted in uniform lifts to at least 90 percent relative compaction, 95
percent in paving areas, based on the laboratory maximum dry density (ASTM Test
Method D1557). The optimum lift thickness required to produce a uniformly compacted
fill will depend on the type and size of compaction equipment used, In general, fill
should be placed in lifts not exceeding 4 to 8 inches in compacted thickness.
Placement and compaction of fill should be performed in general accordance with the
current City of Carlsbad grading ordinances, sound construction practices, and the
General Earthwork and Grading Specifications of Rough-Grading presented in
Appendix B.
4) Foundation Recommendations
The site is considered suitable forthe proposed improvements. The following design
parameters may be used in the design ofthe structure foundations.
Allowable Soil Pressure (Spread) = 1,500 psf
Allowable Soil Pressure (Mat) = SOOpsf
Modulus of Subgrade Reaction = 150 pci
Coefficient of Friction = 0.35
Passive Pressure (Level Ground) = 300 psf/ft (3,000 psf max)
Active Retaining Pressure = 35 pcf (level backfill)
At-Rest Retaining Pressures = 55 pcf (level backfill)
Lateral Surcharge (Traffic) = 75 psf (auto traffic surcharge)
Lateral Surcharge (Uniform Pressure) = 0.35q where q is the uniform pressure
Spread footings should be at least 12 inches below the lowest finish grade.
Reinforcement should be designed by the structural engineer. Continuous footings
should contain at least four No 4 bars, top and bottom. The allowable pressures may
be increased by one-third when considering loads of short duration such as wind or
seismic forces. Structure slabs should be at least 5 inches thick reinforced with No. 3
bars at 18 inches on center, each way. Slabs designed to carry structural loads may
10075 001
require increased thickness and reinforcing. Slab underlayment should be designed by
the project architect.
We recommend a minimum horizontal setback distance from the face of slopes for all
structural footings and settlement-sensitive structures. This distance is measured from
the outside edge of the footing, horizontally to the slope face (or to the face of a
retaining wall) and should be a minimum of 7 feet. We should note thatthe soils within
the structural setback area possess poor lateral stability, and improvements (such as
retaining walls, sidewalks, fences, pavement, underground utilities, etc) constructed
within this setback area may be subject to lateral movement and/or differential
settlement. Foundations should be deepened as needed to attain an embedment
below 1:1 plane from parallel utility trenches.
5) Seismic Parameters
We have provided updated seismic design parameters per California Building Code
(CBC 2010). The following seismic design parameters have been determined in
accordance with the 2010 CBC and the USGS Ground Motion Parameter Calculator
(Version 5.1.0):
Table 1
2010 CBC Seismic Design Parameters
Site Class D
Site Coefficients Fa= 1.0
Fv = 1.521
Mapped Spectral Accelerations Ss = 1.269g
Sl = 0.479g
Site Modified Spectral Accelerations SMS = 1.269g
SMI = 0.729g
Design Spectral Accelerations SDS = 0.846g
SDI = 0.486g
10075 001
6) Cement Type for Construction
Concrete in direct contact with soil or water that contains a high concentration of
soluble sulfates can be subject to chemical deterioration commonly known as "sulfate
attack". We anticipate thatthe on-site soils should possess a negligible potential to
attack normal concrete. As a result, the onsite concrete design mix can be designed
for a negligible potential of sulfate attack and follow the recommendations presented in
Section 4.2.1 of ACI 318-11. Laboratory testing ofthe actual pad grade soils atthe toll
booth pads upon completion ofthe grading operations should be performed to confirm
the sulfate attack potential.
7) Concrete Flatwork
In order to reduce the potential for differential movement or cracking of driveways,
sidewalks, patios, other concrete flatwork, 6x6-6/6 welded-wire mesh reinforcement
or No. 3 rebar on 18 inch centers, each way, is suggested along with keeping pad
grade soils at a uniform moisture content. Flatwork subgrade soil should be moisture
conditioned to at least 2 percent above optimum moisture.
8) Control of Surface Water and Drainaqe Control
Positive drainage may be accomplished by providing drainage away from structures
at a gradient of at least 2 percent toward area drains. Eave gutters, with properly
connected downspouts to appropriate outlets, are recommended to reduce water
infiltration into the subgrade soils.
9) Pavement Design Recommendations
Based on our review ofthe pavement design report (Leighton, 1998b), the pavement
section design below is based on an R-Value test result 36. While we were not
retained to verify actual depths of the existing pavement section, it is our
understanding that Lego Drive was designed for a Traffic Index of 7.0. Flexible
pavement sections have been evaluated in general accordance with the Caltrans
method for flexible pavement design. The recommended flexible pavement section
forthis condition is given in Table 2 below:
10075 001
Table 2
Preliminary Pavement Sections
Traffic Description Traffic Index (Tl) Asphalt Concrete
(inches)
Aggregate Base
(inches)
LEGOLAND Drive 7.0 4,0 8.0
Asphalt Concrete (A.C.) and Class 2 aggregate base materials should conform to and
be placed in accordance with the latest revision of the California Department of
Transportation Standard Specifications (Caltrans).
The upper 12 inches of subgrade soils should be moisture conditioned and
compacted to at least 95 percent relative compaction based on ASTM Test Method
D1557 priorto placement of aggregate base. The base layer should be compacted to
at least 95 percent relative compaction as determined by ASTM Test Method D1557.
If pavement areas are adjacent to landscape areas, we recommend steps be taken to
prevent the subgrade soils from becoming saturated. Concrete swales should be
designed in roadway or parking areas subject to concentrated surface runoff.
10) Construction Observation and Testing and Plan Review
Final foundation and any revisions to the grading plans should be reviewed by
Leighton. The geotechnical consultant should perform construction observation and
testing during the grading operations, future excavations, and foundation or retaining
wall construction atthe site. Additionally, footing excavations should be observed and
moisture determination tests ofthe slab subgrade soils should be performed by the
geotechnical consultant prior to the pouring of concrete.
Grading Plan Review
As part of our update evaluation we have reviewed the precise grading plans (Chang,
2012). Based on our review, the plans have been prepared in general accordance with
the project geotechnical recommendations.
.at «^ "
-7-
10075.001
Limitations
The conclusions and recommendations in this report are based in part upon data that
were obtained from a limited number of observations, site visits, excavations, samples,
and/or tests. Such information is by necessity incomplete. The nature of many sites is
such that differing geotechnical or geological conditions can occur within small
distances and under varying climatic conditions. Changes in subsurface conditions can
and do occur over time. Therefore, the findings, conclusions, and recommendations
presented in this report can be relied upon only if Leighton has the opportunity to
observe the subsurface conditions during grading and construction of the project, in
order to confirm that our preliminary findings are representative for the site.
If you have any questions regarding our report, please contact this office. We
appreciate this opportunity to be of service.
Respectfully submitted,
LEIGHTON AND ASSOCIATESJsia
Sean CoIorBdo, GE 25
Principal Engineer
Michael D. Jensen, CEG 2457
Project Geologist
Attachments: Appendix A - References
Appendix B - General Earthwork and Grading Specifications
Distribution: (2) Addressee
(1) Chang Consultants, Attention' Mr. Wayne Chang
(1) Dunn Savoie Inc., Attention: Mr. Rhett Savoie
(1) R.W. Apel Landscape Architects, Inc., Attention: Richard Apel
10075 001
APPENDIX A
REFERENCES
California Building Code (CBC), 2010, California Code of Regional Title 24, Part2.
Chang Consultants, 2012, Precise Grading Plan, New Parking Toll Booths, LEGOLAND
California, Sheet C-1, received December 19, 2012.
Leighton and Associates, Inc., 1997, As-Graded Condition, Legoland Family Park,
Carlsbad Ranch, Carlsbad, California, dated October 15, 1997.
, 1998a, Final As-Graded Report of Rough-Grading, LEGO Family Park,
Carlsbad, California, dated February 10, 1998.
,1998b, Recommendations for Pavement Section for South Parking Lot
Expansion Area, Proposed LEGO Family Park, Carlsbad, California, dated April 29,
1998.
2002, Geotechnical Pavement Design Review, Main Drive Aisle and Lego
Drive, Legoland Theme Park, Carlsbad, California, dated October 18, 2002
A-1
APPENDIX B
GENERAL EARTHWORK AND GRADING SPECIFICATIONS
LEIGHTON AND ASSOCIATES, INC.
General Earthwodc and Grading Specifications
1.0 General
1.1 Intent
These Geieral Earthwoiik and Grading Specifications are for the gradirig and
earthwoik shown on the ^proved gradirig plan(s) and/or indicated in the
geotechnical rqx}rt(s). These Specifications are a part of the recommaidations
contained in the geotechnical report(s). In case of conflict, the specific
recommendations in the ^otechnical report shall siqDo^sede these n»re general
Specifications. Observations of the earthwork by the project Geotechnical
Consultant during the course of grading may result in new or revised
recommendations that could siqjersede these specifications or the
recommHidations in the geotechnical rqx)rt(s).
1.2 The Geotechnical Consultant of Record
Prior to commencement of work, tiie ovvner shall ennploy the Geotechnical
Consultant of Record (Geotechnical Consultant). The Geotechnical Consultants
shall be responsible for reviewing the ^proved geotechnical report(s) and
accqiting tiie adecpjacy of the preliminary ^otechnical findings, conclusions, and
recommendations prior to the commencement of the gradirig.
Prior to commencanent of grading, the Geotechnical Consultant shall review the
"work plan" prepared by the Earthwork Contractor (Contractor) and schedule
sufficient personnel to paform the ^propriate level of obssvation, mapping, and
conpaction testing.
During the grading and earthwork opaations, the Geotechnical Consultant shall
obsave, m^, and docurriHit the sutsurface ejqxisures to verify the geotechnical
design assunptions. If the observed conditions are found to be significantiy
diffenant than the intapreted assunptions during the design phase, the
Geotechnical Consultant stiall infonn the owner, recommend appropriate changes
in design to accommodate the observed conditions, and notify the review agency
where required. Subsurface areas to be geotechnically observed, mapped,
elevations recorded, and/or tested include natural ground after it has been cleared
for receiving fill but before fill is placed, bottoms of all "remedial removal" areas,
all key bottoms, and benches made on sloping ground to receive fill.
The Geotechnical Consultant shall obsave the moisture-conditioning and
processing of the subgrade and fill materials and perform relative conpaction
testing of fill to determine the attained level of conpaction. The Geotechnical
Consultant shall provide the test results to the owner and the Contractor on a
routine and fiecpjent basis.
-1-
LEIGHTON AND ASSOCIATES, BMC.
Goiaal Earthwork and Gradirg Specificaticos
1.3 The Eartiiwork Contractor
The Earthwork Contractor (Contractor) shall be qualified, expaienced, and
knowledgeable in earthwork logistics, prqiaration and processing of ground to
receive fill, moisture-conditioning and processirig of fiU, and conpacting fill.
The Contractor shall review and accept fhe plans, geotechnical rqx)rt(s), and
tiiese Specifications prior to commaricement of grading. The Contractor shall be
solely responsible for performing the grading in accordance with the plans and
specifications.
The Contractor shall prepare and submit to the owner and the Geotechnical
Consultant a work plan that indicates the sequence of earthwork grading, the
number of "spreads" of work and fhe estimated quantities of daily earthwork
contmplated for the site prior to commencement of grading. The Contractor
shall inform tiie owner and the Geotechnical Consultant of changes in work
schedules and updates to the work plan at least 24 hours in advance of such
changes so that ^propriale ohsa:vations and tests can be planned and
acconplished. The Contractor shall not assume that the Geotechniral Consultant
is aware of all grading operations.
The Contractor shall have the sole responsibility to provide adequate equiprrmt
and methods to accomplish the earthwoik in accordarK:e with the ^plicable
grading codes and a^ncy ordinances, these Specifications, and the
recommendations in the approved geotechnical rqxDrt(s) and grading plan(s). If,
in the opinion of the Geotechnical Consultant, unsatisfactory corxlitions, such as
unsuitable soil, inpropar moisture condition, inadequate conpaction, insufficient
buttress key size, advase weather, etc., are resulting in a quality of work less than
required in these specifications, tiie Geotechnical Consultant shall reject the work
and may recommend to the owner that construction be stopped until fhe
conditions are rectified.
2.0 Prqjaration of Areas to be Filled
2.1 Clearing and Grubbing
V^^tation, such as brush, grass, roots, and other deleterious material shall be
sufflciaidy removed and properly disposed of in a method acceptable to the
owner, goverrrir^agaicies, andthe Geotechnical Consultant.
The Geotedmical Consultant shall evaluate the extent of these rmiovals
deperdirig on specific site conditions. Earth fill material shall not contain more
than 1 pax:ent of or^nic materials (by volume). No fill lift shall contain more
than 5 parent of organic matter. Nesting of the or^nic materials shall not be
allowed.
LEIGHTON AND ASSOCIATES, INC.
General Earthwork and Gradirg Specifications
If potentially hazardous materials are mcountaed, the Contractor shall stop woik
in the affected area, and a hazardous material specialist shall be informed
immediately for proper evaluation and handling of tiiese mataials prior to
continuing to woik in that area.
As presendy defined by the State of Califomia, most refined petroleum products
(^soline, diesel fuel, motor oil, grease, coolant, etc.) have chemical constituents
that are considered to be hazardous waste. As such, the indiscriminate durrping
or spilla^ of these fluids onto the ground may constitute a misdoiieanor,
punishable by fines and/or irrprisonment, and shall not be allowed.
2.2 Processing
Existirg ground that has beei declared satisfactory for sipport of fill by the
Geotechnical Consultant shall be scarified to a niinimum depth of 6 inches.
Existing ground that is not satisfactory shall be overexcavated as specified in the
following section. Scarification shall continue until soils are broken down and
free of large clay lumps or clods and the working surface is reasonably unifonn,
flat, and fiTee of uneven features that would inhibit uniform conpaction.
2.3 Overexcavation
In addition to removals and overexcavations recommended in the approved
geotechnical rqx)rt(s) and the grading plan, soft, loose, dry, saturated, spongy,
organic-rich, higjily fiactured or otherwise unsuitable ground shall be
overexcavated to conpetent ground as evaluated by the Geotechnical Consultant
during grading.
2.4 BerKhing
Where fills are IB be placed on ground with slopes steeper than 5:1 (horizontal to
vertical units), the ground shall be stepped or benched. Please see the Standard
Details for a gr^hic illustration. The lowest bench or key shall be a minimum of
15 feet wide and at least 2 feet cteep, into conpetent material as evaluated by the
Geotedmical Consultant. Other beiches shall be excavated a minimum hei^ of
4 feet into conpetent rmleial or as otharwise recommended by the Geotechnical
Consultant. Fill placed on ground sloping flatter than 5:1 shall also be benched or
otherwise overexcavated to provide a flat subgrade for the fill.
2.5 Evaluation^Acceptance of FUl Areas
All areas to receive fill, including removal and processed areas, key bottoms, and
benches, shall be observed, m^ped, elevations recorded, and/or tested prior to
being accepted by the Geotechnical Consultant as suitable to receive fill. The
Contractor shall obtain a written accqitance from the Geotechnical Consultant
LEIGHTON AND ASSOCIATES, INC.
Genaal Earthwork and Giadirg Speciflcations
prior to fill placement. A licensed surveyor shall provide fhe survey control for
determining elevations of processed areas, keys, and benches.
3.0 FUI Material
3.1 Genaal
Material to be used as fill shall be essentiaUy free of oigsnic matter and other
deleterious substances evaluated and acceptal by tiie Geotechnical Consultant
prior to placanent. Soils of poor quality, sudi as those with unaccqitable
gradation, higji ejq^ansion potential, or low strmgtii shall be placed in areas
accqitable to fhe Geotedmical Consultant or mixed with other soils to achieve
satisfactoiy fiU material.
3.2 Oversize
Oversize matoial defined as rock, or otho" iireducible mataial with a maxinuim
dimmsion greater than 8 inches, shaU not be buried or placed in fiU unless
location, riBterials, and placemait methods are specifically accepted by the
Geotechnical Consultant. Placanent operations shall be such that nesting of
ovasized material does not occur and such that oversize material is corrpletely
surroimded by conpacted or densified fUl. Oversize material shall not be placed
within 10 vertical feet of finish grade or within 2 feet of future utUities or
underground construction.
3.3 Inport:
If inporting of fill mataial is required for grading, proposed inport mataial shall
meet the requirements of Section 3.1. The potential inport source shaU be givai
to the Geotechnical Consultant at least 48 hours (2 working days) before
inportii^ b^pis so tiiat its suitabiUty can be deteimined and appropriate tests
paformed.
4.0 FUI Placement and Conpaction
4.1 FUl Layeis
Approved fiU mataial shall be placed in areas prqiared to receive fiU (per
Section 3.0) in near-horizontal layas not exceeding 8 inches in loose thickness.
The Geotechnical Consultant may accept thicker layers if testing indicates the
grading procedures can adequately conpact fhe thicker layers. Each layer shall
be spread evenly and mixed tix)roughly to attain relative unifomiity of material
and moisture tiuxDugJiout.
LEIGHTON AND ASSOCIATES, INC.
General Earthwork and Grading Specifications
4.2 FiU Moisture Conditioning
Fill soUs shall be watered, dried back, blended, and/or mixed, as necessary to
attain a relatively uniform moisture content at or sU^itly over optunum
Maximum density and optimum soU moisture content tests shall be performed in
accordance with the Amoican Society of Testing and Materials (ASTM Test
Metiiod D1557).
4.3 Compaction of FiU
After each layer has been moisture-conditioned, mixed, and evenly spread, it shaU
be uniformly conpacted to not less than 90 parait of maxumun dry density
(ASTM Test Method D1557). Conpaction equipment shaU be adequately sized
and be either specifically designed for soil conpaction or of proven reliability to
efficientiy achieve the specified level of conpaction with uniformity.
4.4 Conpaction of FiU Slopes
In addition to normal conpaction pnx:edures specified above, conpaction of
slopes shaU be acconplished by backrolling of slopes with sheepsfoot rollers at
increments of 3 to 4 feet in fiU elevation, or by other methods producing
satisfactory results accqjtable to the Geotechnical Consultant. Upon completion
of grading, relative conpaction of the fiU, out to the slope face, shaU be at least
90 pax:ait of maximum density per ASTM Test Method D1557.
4.5 Conpaction Testing
Field-tests for moisture content and relative conpaction of the fiU soils shall be
perfbrmed by the Geotechnical Consultant. Location and fiiequency of tests shaU
be at the Consultant's discretion based on field conditions aicountoTed.
Conpaction test locations wiU not necessarily be selected on a random basis.
Test locations shall be selected to vaify adequacy of conpaction levels in areas
that are judged to be prone to inadequate conpaction (such as close to slope faces
and at the fill/bedrock bendies).
4.6 Frequency of Compaction Testing
Tests shall be taken at intavals not exceeding 2 feet in vertical rise and/or
1,000 cubic yards of conpacted fUl soUs embankment. In addition, as a
guideline, at least one test shall be takm on slope faces for each 5,000 square feet
of slope face and/or each 10 feet of vertical heiglit of slope. The Contractor shall
assure that fUl construction is such that the testing schetijle can be acconplished
by the Geotedmical Consultant. The Contiactor shall stop or slow down the
earthwoik construction if these niinimum standards are not met
LEIGHTON AND ASSOCIATES, INC.
General Earthwork and Gradir^ Speciflcations
4.7 Conpaction Test Locations
The Geotechnical Consultant shall ctocument the approximate elevation and
hcttizontal coordinates of each test locatioa Tlie Contractor shaU coordinate with
the project surveyor to assure that sufficient grade stakes are established so that
the Geotedmical Consultant can determine the test locations with sufficient
accuracy. At a rrdnimurri, two grade stakes within a horizontal distance of 100
feet and verticaUy less than 5 feet apart from potential test locations shall be
provided.
5.0 Subdrain Installation
Subdrain systeins shaU be instaUed in accordance with the qproved geotechnical
report(s), the grading plan, and the Standard Details. The Geotedmical Consultant may
reccffnmend additional subdrains and/or chaiiges in subdrain ext&rt, location, grade, or
material dqiaiding on conditions mcoimtaed during grading. All subdrains shaU be
surveyed by a land surveyor/civU enginea- for Une and grade after installation and prior
to burial. Sufficient time should be allowed by fhe Contractor for these surveys.
6.0 Excavation
Excavations, as weU as over-excavation for ranedial purposes, shaU be evaluated by the
Geotechnical Consultant during gradirig. Ranedial removal deptiis shown on
geotedmical plans are estimates only. The actual extent of ronoval shaU be determined
by the Geotechnical Consultant based on the field evaluation of ejqiosed conditions
during grading. Where fiU-ovo'-cut slopes are to be graded, the cut portion of the slope
SIHU be made, evaluated, and accqjted by the Geoteclmical Consultant prior to placement
of rtBtoials for construction of the fill portion of the slope, unless otherwise
recommended by the Geotechnical Consultant.
7.0 Trench Backfills
7.1 Safety
The Contractor shall follow all OSHA and Cal'OSHA requirements for safety of
troich excavations.
LEIGHTON AND ASSOCIATES, INC.
Genaal Earflwork and Gradir^ Speciflcations
7.2 Bedding and BackfiU
AU bedding and backfUl of utUity troidies shall be paformed in accordance with
the applicable provisions of Standard Specifications of Public Works
Construction. Bedding mataial shall have a Sand Equivalent greata- than 30
(SE>30). The bedding shall be placed to 1 foot over the top of the conduit and
densified. BackfUl shaU be placid and densified to a mininuim of 90 pax:ent of
relative conpaction finm 1 foot above the top of the conduit to the surface.
The Geotechnical Consultant shaU test the trench backfUl for relative conpaction.
At least one test should be made for evoy 300 feet of troich and 2 feet of fill.
7.3 Lift Thickness
Lift thickness of trench backfiU shaU not exceed those allowed in the Standard
Specifications of Public Works Constmction unless the Contractor can
demonstiate to the Geotechnical Consultant that fhe fiU Uft can be conpacted to
the minimum relative conpaction by his altonative equipment and method.
7.4 Observation and Testing
The densification of the bedding around the conduits shall be ohsa;ved by the
Geotechnical Consultant.
FILL SLOPE
PROJECTED '""LANE 1:1 -
(HORIZONTAL: VERTICAL)
MAXIf/UM FROM TOE
OF SLOPE TO
APPROVED GROUND
EKISTING-
GROUND SURFACE
^:¥:>C0MPXcfE&?:¥:-:->^^
^ ,Mgp&^^X^
,^.^Y:55Y:::3:I-^^^^ ^REMOVE
2 FEET MIN
KEY DEPTH
^^^^^SIJIBENCH HEIGHT
''''^'''^^•^^^r^'' (4 FEET TYPICAL)
UNSIJITABI F
MATERIAL
.15 FEET MIN.^
LOViEST
BENCH (KEY)
FILL-OVER-CUT SLOPE
LXIStING
GROUND SURFACE
OMPACTED:-
•HFiLL->:-->--
2 FEET
MIN KEY
DEPTH
LOWEST
BENCH (KEr)
•BENCH HEIGHT
(4 FEET TYPICAL)
REMOVE
UNSUITABLE
MAIFRIAI
CUT-OVER-FILL SLOPE
-CUT FACE
SHAI I BF CONSTRIICTD PRIOR TO ,
FILL PLACEMENT TO ALLOW VIEWING
OF GEOLOGIC CONDITIONS y ^
EXISTING---~--___.^/ '"V
GROUND _
\)JT FACE SHALL 3E
CUNSIRUCltD PRfOK
TO FILL PLACEMENT
OVERBOLD AND
TRIM BACK
PROJECTED PLANE-
1 TO 1 MA>;iMUM
FROM TOE OF SLOPE
TO APPROVED GROUND
REMOVE
UNSUITABLE
MATERIAL
2 FEET MIN.-J
KEY DEPTH
15 FEET MIN.^
LOWEST
BENCH (KEY)
-BENCH HEGHT
(4 FEET TYPICAL)
BENCHING SHALL BE DON; WHEN SLOPE'S
ANGLE IS EQUAL TD OR GREATER THAM 5' 1
MINIMUW BENCH HEIGHT SHALL GE 4 FEET
AND MINIMUM Fll I WIDTH SHAI I RF 9 FFFT
KEYING AND BENCHING
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL A
FINISH GRACE
SLOPE FACE —
OVERSIZE ROCK IS LARGER THAN
8 INCHES IN LARGEST DIMENSION,
EXCAVATE A TRENCH IN THE COMPACTED
FILL DEEP ENOUGH TO BURY ALL THE
ROCK.
BACKFILL WITH GRANULAR SOIL JETTED
OR FLOODED IN ?LACE TO FILL ALL THE
VOIDS
00 NOT BURY ROCK WTHIN 10 FEET OF
FINISH GRAOE
WINDRDW OF BURIED ROCK ShALL BE
PARALLEL TO THE FINISHED S.OPC.
GRANULAR MATERIAL TO 8E "
DLNSIHED IN PLACE Ht
FlOOOtNG OR JETTING
DETAIL
•'JETTED OR FLOODED - - •
GRANULAR MATERIAL
TYPICAL PROFILE ALONG WINDROW
OVERSIZE ROCK
DISPOSAL
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL B
\ \ ^— EXISTING
\^\.^ GROUND SURFACE
BENCHING
KtMOVt
UNSUITAOL;
MATERIAL
SUBDRAIN
TRENCH
SEE DETAIL BELOW
6" MiN.
OVERLAP
CALTRANS aASS 2 PERMEABLE-—.X^^^^"^
OR #2 ROCK (gFT'J/FT) WRAPPED>( ; |-
fN FILTER FABRfC //••-• ••"."i
ILTER FABRIC
(MIRAFI 140N OR APPROS/EO
EQUIVALENT)*
5" MIN
COVER
'i-L,
4 MIN, BEDDING
COLLECTOR PIPE SHALL
BE MINIMUM 5" DIAMETER
SCHEDULE 40 PVC PERFORATED
PIPE. SEE STANDWO DETAIL 0
FOR PIPE SPECIFICATIONS
$UBPRAIN PETAL
DESIGN FINISH
GR<\DE
NONPERFORATED & 0 MIN
PERFORATED
6" 0MIN PIPF
ILTER FABRIC
{MIRAFI UON OR APPROVED
EQUIVALiNT)
CALTRANS CLAS3 2 PERMEABLE
OR #2 ROCK (9FT'^3/FT) WRAPPED
^N HLIEK l-AbKfC
QUNl OF CANYON mmm QMTIST
CANYON SUBDRAINS GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL C
15' MIN
OUTLET PIPES
4" 0 NONPERFORATED PPE,
100" f/AX OC HORIZONTALLY. \.
30' VAX OC. VERTICALLY
CU'
FLATTER
SEE SUBDRAIE*! TRENCH
DETAIL
LOWEST SUBDRAIN SHOULD
BE SITUATED AS LOW AS
POSSIBLE TO ALLOW
SUITABLE OUTLET
-KEY DEPTH
{2 MIN)
KEY WIDTH
AS NOTED ON GRAOING PLANS
(15' MIN ) 12" MIN OVERLAP-
FROM THE TOP 10
RING T!ED EVERY
6 FEET
CA. TRANS CLASS II
PERMEASLE OR §2
RODK (3 FT'3/FT)
WRAPPED IN FILTER
FABRIC
5-4 ' 0
\ N0N-PE=*FORATEO
\ OUILtl PIPE
PROVDC POSITIVE
SEAL AT THE
JONT
I-CONNECTlCKi
-OR COl I rCTOR
=»IPE TO OUTLET PIPE
e" WIN
COVER
4" 0
PERFORATED
PIPF
-FILTER FABRIC
ENVELOPE (MIRAFI
140 OR APPROVED
EQUIVALENT)
A MIN
BEDDING
SUBDRAIN TRENCH DETAIL
SUBDRAIN I^STALLATION - subdram ccjileclor pipe shall be instolted with perforotion down or.
unless otherwise designoted by Ihs geotecht>icol consultant Outlet pipes shall be non-perforoted
oipe The subdroiri pipe shots hove ot least 8 perforotions uniforrr>ty spoced per fool Perforation
sholl be 1/4" lo 1/2" if d'ill holes ore used All sut>droin pipes shall have o qrodient of of
eost 2% towords the outlet,
SUBDRAIN PIPE - Subdroin pipe shall bo ASTM D2751. SOR 23.5 or ASTM D1527. St-htjdule 40. or
ASTM 0.3034. SDR ?.3 S. Schedule; 40 Folyviryl Chloride Ploslic (PVC) pipe
'VII outlet oipe sholl be pioced in o treTch no wider thon twice the <!ubdrnin pipe
BUTTRESS OR
REPLACEMENT
FILL SUBDRAINS
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL D f
CUT-FILL TR.^NSITION LOT OVEREXCAVAHON
REMOVE
UNSUITABLE
3ROUND
y-.^^
£• WIN '"••'^
OVEREXCAVATE
\m RLCOMMAC
UNWEATKRED BEDROCK DR MATERIAL AP='RCVED
' BY IHL bWltUHNILAL LUNbUL I AN I
/
TRANSITION LOT FILLS
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL E
SOIL BACKFILL, COMPACTED TO
90 PERCENT RELATIVE COMPACTION
BASED ON ASTM D1557
RETAINING WALL
WALL WATERPROOFING
PER ARCHITEC'S
SPLCIUCAIIONS
WALL FOOTING
FILTER FABRIC ENVELOPE
(MIRAFI UON OR APPROVED
EQUIVALENT)'*
TO 1-1/2" CLEAN GRAVEL
-4" (M-N.) DIAMETER PERFORATED
PVC PIPE (SC-IEDULE 40 OR
EQUIVALENT) WITH PERFORATIONS
ORIENTED DOWN AS DEPICTED
MINIMUM 1 PERCENT GRADIENT
TO SUITABLE OUTLET
-3" MIN.
COMPETENT BEDROCK OR MATERIAL
•AS EVALUATED OY TIC GEOTECHNICAL
CONSULTANT
NO II- U'-'ON RLVItW BY IHE GEOTECHNICAL CONSULTANT,
COMPOSHl UKAINAGL PROUUCIS bUCH Ab MIKAUtiAIN OR
J-DRAIN WAY 3E USED AS AN ALTERNATIVE TO GRAVEL OR
CIASS ? PFRMFABIF MATFRIAL. INSTALLATION SHOUID BF
PERFORMED IN ACCORDANCE WITH MANUFACTURER'S
SPECIFICATIONS
RETAINING WALL
DRAINAGE
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL F
i(<
ACTIVE
ZONE
GRAVEL
DRAINAGE FILL
MIN 6" BELOW WALL
MIN 12" BEHIND UNITS
FOUNDATION SOILS
REAR SUBDRAIN
4" (MIN) DIAMETER PERFORATED PVC PIPE
(SCHEDULE 40 OR EQUIVALENT) WITH
PERFORATIONS DOWN SURROUNDED BY
1 CU FT/FT OF 3/4" GRAVEL WRAPPED IN
FILTER FABRIC (MIRAFI MON OR EQUIVALENT)
OUTLET SUBDRAINS EVERY 100 FEET, OR CLOSER,
BY TIGHTLINE TO SUITABLE PROTECTED OUTLET
GRAVEL DRAINAGE FILL.
SIEVE SIZE
1 INCH
3/4 INCH
NO 4
NO 40
NO 200
% PASSING
100
75-100
0-60
0-50
0-5
NOTES
1) MATERIAL GRADATION AND PLASTICITY
REINFORCED ZONE.
SIEVE SIZE % PASSING
1 INCH 100
NO 4 20-100
NO 40 0-60
NO 200 0-35
FOR WALL HEIGHT < 10 FEET, PLASTICITY INDEX < 20
FOR WALL HEIGHT 10 TO 20 FEET, PLASTICITY INDEX < 10
FOR TIERED WALLS, USE COMBINED WALL HEIGHTS
WALL DESIGNER TO REQUEST SITE-SPECIFIC CRITERIA FOR WALL HEIGHT > 20 FEET
2) CONTRACTOR TO USE SOILS WITHIN THE RETAINED AND REINFORCED ZONES THAT MEET THE STRENGTH REQUIREMENTS OF WALL DESIGN
3) GEOGRID REINFORCEMENT TO BE DESIGNED BY WALL DESIGNER CONSIDERING INTERNAL EXTERNAL AND COMPOUND STABILITY
3) GEOGRID TQ BE PRETENSIONED DURING INSTALLATION
4) IMPROVEMENTS WITHIN THE ACTIVE ZONE ARE SUSCEPTIBLE TO POST-CONSTRUCTION SETTLEMENT ANGLE a -45+<t>/2, WHERE * IS THE
FRICTION ANGLE OF THE MATERIAL IN THE RETAINED ZONE
5) BACKDRAIN SHOULD CONSIST OF J-DRAIN 302 (OR EQUIVALENT) OR 6-INCH THICK DRAINAGE FILL WRAPPED IN FILTER FABRIC PERCENT
COVERAGE OF BACKDRAIN TO BE PER GEOTECHNICAL REVIEW
SEGMENTAL
RETAINING WALLS
GENERAL EARTHWORK AND
GRADING SPECIFICATIONS
STANDARD DETAIL G
structural Engineers
Calculations for
Legoland Hotel
Carlsbad, CA
Architects Delawie Wilkes Rodrigues Barker
2265 India Street
San Diego, CA 92101
August 2011
€y i Sheet.
^^^^^^^^l Project: Legoland Hotel GSSI No. 11046A
Structural Engineers
Engr. BShell Date- 6/29/2011
Legoland Hotel Structural Design Criteria
Code: 2010 CBC
3 story Wood and Steel Hotel Building
Lateral Load Resistmg System: Beanng Walls with Light Framed Walls using Wood Shear Resisting Panels
Soil Bearing Capacity:
SBC = 3,500 psf @ 18 inches below/ lowest adjacent finished grade.
Seismic:
Site Class D
Ss=126 Fa= 1.00 SMS = 1.26 SQS = 0.84
Si = 0.476 Fv = 1 52 SMI = 0.73 Spi = 0 48
Response Cs Cs
Occupancy Importance Mod Factor SDS/(R/I) Scs/(R/I)
Category Factor, I R ( LRFD ) {ASD )
III 1 25 6.5 0.162 0.115
Seismic Design Category: D
Max Allowed Height: 65 ft.
Wind Load:
Basic Wind Speed- 85 mph
Exposure: C
Importance Factor 1.15
i
4- f
Project - Loading W7 xlsx
structural Engineers
Project Legoland Hotel
Engr. BShell
Sheet: ^ ^
GSSI No 11046A
Date 6/30/2011
Loads:
Legoland Hotel
Roof: (sloped :12) Mansard Roof
Dead Load ( DL ) Dead Load ( DL )
Roofing/Zonolyte 8.0 psf Tile 12.0 psf
1/2" Plywood 2.0 psf 1/2" Plywood 3 0 psf
TGIJoists(g24" 3.0 psf 2x6 @ 24 1 0 psf
Insulation 1 0 psf psf
2x 5/8" Gyp CIg 6.0 psf psf
Spnnklers 0 5 psf psf
Mech. 0.5 psf psf
Misc 1 0 psf psf
DLZ = 22 0 psf DLI = 16 0 psf
Live Load ( LL ) Live Load ( LL )
LLI = 20.0 psf (Reducible) 20 0 psf (Reducible)
X DL -t- LL = 42.0 psf Z DL -1- LL = 36.0 psf
Wood Floors Wood & Steel 2nd Floor:
Dead Load ( DL ) Dead Load ( DL )
Flooring 2.0 psf Floonng 2 0 psf
1 1/2" Elasticell 15 0 psf 1 1/2" Elasticell 15.0 psf
3/4" Plywood 2 5 psf 3/4" Plywood 2.5 psf
TGI Joists @ 16" 3.0 psf TGI Joists @ 16" 3 0 psf
Insulation 0 5 psf Insulation 0.5 psf
Sprinklers 0.5 psf Sprinklers 0.5 psf
2x5/8" Gyp CIg 6.0 psf 2x5/8" Gyp CIg 6.0 psf
Mech. 1.0 psf Mech 1.0 psf
Misc. 1 5 psf Misc. 1.5 psf
DLI = 32 0 psf DLZ = 32.0 psf
Beams 10 0 psf
Live Load ( LL ) Live Load ( LL )
LL = 40.0 psf (Rooms) LL = 40.0 psf (Rooms)
LL = 100 psf (Corndors LL = 100 psf (Corridors)
I DL -F LL =
Walls:
stud Walls
Extenor Walls
Interior Walls
72.0 psf
132.0 psf
18 0 psf
13.0 psf
(Rooms)
(Corridors
ZDL+LL= 82.0
142 0
psf (Rooms)
psf (Corridors)
Project - Loading W7 xlsx
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Structural Engineers
Project Legoland Hotel
Engr-M.Griffiths
Sheet
GSSI No. 11046A
Date 7/5/2011
Joist and Beam Capacities
2 X Joists
Av = 180 psi Repetitive Use Increase = 1.15 Snow Load Increase 1.15
Fb = 1000 psi Roof Load Increase = 1.25 Snow Snow
Width Depth
Actual
Width Depth Cf Area Section
Modulus
Moment
of Inertia
Shear
Vr.floor
Moment
Mr,floor
Shear
Vr,roof
/\/loment
Mr,roof
Shear
Vr,roof
/[/lament
Mr, roof
2 4 1.5 35 1.5 5.3 3.1 5.4 630 440 788 550 725 506
2 6 1 5 55 1.3 8.3 7.6 21 990 942 1,238 1,178 1,139 1,083
2 8 1.5 7.25 1.2 109 13 1 48 1,305 1,511 1,631 1,889 1,501 1,738
2 10 1 5 9.25 1.1 139 21 4 99' 1,665 2,255 2,081 2,819 1,915 2,593
2 12 1.5 11.3 1 16.9 31 6 178 2,025 3,032 2,531 3,790 2,329 3,487
2 14 1.5 13.3 0.9 199 43.9 291 2,385 3,786 2,981 4,732 2,743 4,353
4 X Beams
Av = 180 psi
Fb = 1000 psi Snow Snow
Nominal
Width Depth
Actual
Width Depth Cf Area Section
Modulus
Moment
of Inertia
Shear
Vr.floor
Moment
Mr,floor
Shear
Vr,roof
l\4oment
Mr,roof
Shear
Vr,roof
Moment
Mr, roof
4 4 3.5 3.5 1.5 12.3 7.1 12.5 1,470 893 1,838 1,117 1,691 1,027
4 6 3.5 5.5 1.3 193 17.6 49 2,310 1,912 2,888 2,390 2,657 2,198
4 8 35 7.25 1.3 25.4 30 7 111 3,045 3,322. 3,806 4,152 3,502 3,820
4 10 35 9.25 1 2 32.4 49.9 231 3,885 4,991 4,856 6.239 4,468 5,740
4 12 3.5 11.3 1 1 39 4 73.8 415 4,725 6,768 5,906 8,459 5,434 7,783
4 14 35 13.3 1 46.4 102.4 678 5,565 8,534 6,956 10,668 6,400 9,814
4 16 3.5 15.3 1 53.4 135.7 1034 6,405 11,305 8,006 14,131 7,366 13,001
6 X Beams
Av = 170 psi
Fb = 1350 psi Snow Snow
Nominal
Width Depth
Actual
Width Depth Cf Area Section
Modulus
Moment
of Inertia
Shear
Vr.floor
Moment
Mr.floor
Shear
Vr,roof
Moment
Mr, roof
Shear
Vr,roof
Moment
Mr, roof
6 6 5.5 5.5 1 30.3 27.7 76 3 3,630 3,120 4,285 3,899 3,943 3,587
6 8 55 7.5 1 41.3 51.6 193 4,950 5,801 5,844 7,251 5,376 6,671
6 10 5.5 95 1 52.3 82.7 393 6,270 9,307 7,402 11,634 6,810 10,703
6 12 5.5 11 5 1 63.3 121.2 697 7,590 13,638 8,960 17,048 8,244 15,684
6 14 5.5 13.5 0.98 74.3 167.1 1128 8,910 18,419 10,519 23,023 9,677 21,181
6 16 55 15.5 0.97 85.3 220.2 1707 9,662 24,033 12,077 30,041 11,111 27,637
6 18 5.5 17.5 0.96 96 3 280.7 2456 10,908 30,319 13,635 37,898 12,545 34,867
JOIST DESCRIPTION AND DESIGN PROPERTIES
• '^^ A ^ -1 ^•. %,Joist.>'
|ge|thj;
"'Fs'
idoist.'
-Weight;
/Resjstile,^'
;;Mo'mentlJ)'
"^''f^jj' F'>.^
SVertlcall,''
^|(lbs)i<i
irEI;x;i'fl8'J
a'?X-#K»Eria'ReaGtio'n1lb's)^-;r.^|. . .r/ Intermediate- Rea'ctionllB's) fff( • '^^ A ^ -1 ^•. %,Joist.>'
|ge|thj;
"'Fs'
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-Weight;
/Resjstile,^'
;;Mo'mentlJ)'
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SVertlcall,''
^|(lbs)i<i
irEI;x;i'fl8'J tiff Be'arinc Sehgttf :»!r'/'"'' -tvj,-Bearine 'L'eiigth;?'V>yA; • '^^ A ^ -1 ^•. %,Joist.>'
|ge|thj;
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-Weight;
/Resjstile,^'
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^|(lbs)i<i
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• '^^ A ^ -1 ^•. %,Joist.>'
|ge|thj;
"'Fs'
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-Weight;
/Resjstile,^'
;;Mo'mentlJ)'
"^''f^jj' F'>.^
SVertlcall,''
^|(lbs)i<i
irEI;x;i'fl8'J
S Web.stiff eriers' l-WeKStiffeners-iWeb Stiffeners', ?Web\Stiffenersi
• '^^ A ^ -1 ^•. %,Joist.>'
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-Weight;
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^|(lbs)i<i
irEI;x;i'fl8'J
i'Yeslt \ 5Nd Yes i-+Yes}.',
30 5,215 1,675 263 1,375 NA 1,675 NA 2,745 NA 3,365 NA
33 •,^6,750 -';1,925 ,;-"450 --1,-375 --1r745\ -,1;885.-. 1,925" '^745^ 3,120-- 3,365 • :" 3,735
36 8,030 2,125 666 1,375 1,750 1,885 2,125 2,745 3,365 3,365 3,985
:.3 9 -- 9,-210'.. -' :C913 -.1,375_ 1,750,: :i;885---.2,330-, 2,745t '3,490i 3,-365; .4,105-
(.ttlSS'S 42 10,380 2,535 1,205 rL375 1,750 n",885" 2,535 2,745 3,615 3,365 4,230
• 4-4-'-,=11,540 2,-740/= -X 4,545" -N A :r;750'. ..NA : '2;740--3fZ40-~ cN'A-'t .4,355"
22" 47 12,690 2.935 1,934 NA. 1,750 NA 2,935 NA 3,860 nTA~ 4,480
lam^- .• 50 13,830-3,060" - 2,374-NA -1,-750-! NA -'3,060 NA.^ 3,875.--, N A-^-4;605''
53 14,960 2,900 2,868 NA 1,750 NA 2,900 NA 4,725(5) N A 5,345(6)
V''2r.:i: 55' ••16,085_ • :- 2,900; . ' 53;417^-^ NA-" • 1:750 ;N:A--{2,900=--NA 4,850(5) "NA-5,470(6)
30" 58 17,205 2,900 4,025 NA 1,750 N A 2,900 NA 4,975(5) NA 5,590(6)
The stated allowable design properties are for loads of normal duration Adjustments to the allowable design values shall be in accordance with
the applicable code
(1) Caution. Joist resistive moment properties should not be increased by a repetitive-member-use factor
(2) Interpolation between beanng lengths and joist depths is permitted
(3) The minimum bearing length may be reduced for joists supported by hangers if supplemental nail attachment is provided to the web stiffener
(4) Bearing lengths are based on RedBuilt™ products Check allowable bearing on supporting members 1t/2'
(5) A 5'/4" beanng length is required at intermediate reactions
(6) A 7" bearing length is required at intermediate reactions
-n r 2'/2"
T
Available Slopes:
VB" to Vf per foot
For slopes not shown in this guide, contact your
RedBuilt™ representative.
Available Lengths:
12' through 60'
Available Depths:
Minimum- Wf
Maximum 30"
WEB STIFFENERS
to 30"
;Ret/|r" yo/sts are inteiided^
'/16" -
Tapered Red-165™ joists
Top and bottom flanges of
V/2" X 21/2" RedLam™ LVL mth VK" web
The Importance of Web Stiffeners
Web stiffeners are available from RedBuilt™ in precut sizes and can be installed
at the plant on one or both ends upon request. Web stiffeners are an important
part of almost all Red-I™ joist installations because they wilt
• Stiffen the Red-I™ joist web material and prevent buckling
• Minimize the beanng length required for the Red-I™ joist.
• Help transfer reaction loads into Red-I™ joist web
• Provide stabilization in hangers.
1 Vf maximunn X
Space nails I
equally 1
1 Vf maximum
Gap
' minimum
Jl" 2%" maximum
Snug fit
,
To Ensure System Performance
• Web stiffeners must be installed at bearing points as shown in the
details below and at points of concentrated loads exceeding 1,500 Ibs.
• Web stiffeners are required on joists 20" and greater m depth
• Web stiffeners are available from RedBuilt™ and typically have the
maximum gap shown below Venfy that hanger nails adequately engage
the web stiffener
• Gap must be at top at all bearing conditions. In case of concentrated
loads, the gap must be at the bottom.
• Plant-installed web stiffeners are available; one-end-only for skewed,
hip and other bearings where dimensions cannot be assured
Nail Quantities for
Web Stiffener Attacliment Web Stiffener Size and IVIaterial
Joist,
•Depth'r
8d ,(2V2") Mails
End or Intermediate
•iV/s" ' 3
• 14"... 5
16" 6
181' 7
20° 8
22" 9
24° 10
26° 11
28°, 12
,30" 13
Web Stiffener
Size ;, , Wei) Stiffener Material
1"X 25/16"
Sheathing (with face gram vertical)
that meets the requirements of
PS 1 or PS 2, or CSA Standards
0151,0352, or 0437
LOAD TABLES
Snow—115% (PLF)
|gg>V4°/ft'SiopB?'-ai-|?-j.?y3';/ft'Siope"^'s
f^..'Shallbw.EnTf.De"pth?»je;.%':
'F^4^"'kF "-IG;K -H2W ':Ji4;t iJio;;-t'12'3,f; I:i4".-,-
266 266 266 266 266 266
*',i4s;# -223 22S :22S '223-.-228 .223
799 799 799 799 799 799
•'S/iS'9:, 177' 777 777 777; 777 ; 777
158 759 759 759 759 759
^Ski22'\.'-125; r744 744 744 744 :-f44
1.;:-24>'f 102 732 732 124 732 732
;-«26'rs •--84-117£ - 722 :;103: t722 722
m2S-:'S 70 97 773 88 773 773
-:59 ;-82 ;io4* 75 101 -705'
'&32i^-'t 51 70 92 65 88 99
;'it34':%: ::;44 "-60 -180. "57 - 76 " 91 "-
36' 38 52 69 50 67 83
:''38';-i: .- 33 -: ---46 --"-61 - 44. 59 '75
40' 30 41 54 39 53 68
Non-Snow—125% (PLF)
;ySp'an"
.sr:\V4'yftiSlbpe--;v|.--'^;.%-'/ft'Slope«.>;';
y-Shallow^End'Depth'gj
ilO?,-•'42??. .'•:i4':« .;io" y2'!?
,;,£'12'.;--":-' 269 289 289 289 289 289
v'"'t4:M 248 ^248 24&--248., 248 248:
276 276 276 276 276 276
/;£l8i-^: - 792 >792. 792 792 .792 792
-20:-- : 158 773 773 773 773 773
.-125" •757. 757-. "152 757: 757"
',-24'.";. 102 142 744 124 744 744
r::'26!,ii ,84 117i 732 • 103^ - 732 -732
-:3\-28'-70 97 723 --.88 119 723
30' • 59' ""-" 82 -109 •75-102-,775
t,.32\ 51 70 93 65 88 707
34' 44 60. ^ -80 • -57 '76-' 99"
-.;i-36'"i-38 52 69 50 67 86
,33 46 61 - -44 •59-." -76
40' 30 41 54 39 53 68
Bold italic values indicate load is controlled by PA" beanng length To achieve higher loads for other beanng conditions, contact your RedBuilt'" representative
} ••'.%-^]h<3lef,.-contaicUyo J,
How to Use Tiiese Tables
1 Select span. Tapered Red-I™ joist tables shown are for simple-
span applications only. For multiple-span applications, contact your
RedBuilt™ representative.
2 Scan across to proper slope and depth column. Load shown is the
maximum capacity in pounds per linear foot.
General Notes
• Tables are based on-
- simple spans
-1%" minimum bearing length
- Uniform loads
- Maximum live load to dead load ratio of 41
- Deflection criteria of L/240 live load and L/180 total load
• Straight line interpolations may be made between depths and spans
• For span or loading conditions not covered by these tables (such
as multiple spans or concentrated loads), contact your RedBuilt™
representative for assistance
Example Problem
2x6
stud -
wall
".....:^„#/'-:.^:ii^'.-^4^'J^,'i^.^i^^^P-d'^'^ks^-^~^'pif.z S'...
26'-9"
2x6 • stud wall
Desired slope is Vf per foot
Load duration of 125%
Out-to-out of 2x6 stud walls is 26'-9"
Desired spacing is 32" on-center
Live load is 20 psf
Dead load is 15 psf
Design load is 35 psf at 32" 0 c = 93 plf
Solution
1. For joist span, use clear span plus V2 of IW minimum bearing at each end
and round up.
^ Clear span = 26'-9" - 51/2" - 51/2"
= 25'-10"
Joist span = clear span plus
minimum bearing distance = 25'-10" H- Vf H- Vf
= 25'-1iy4"
Round joist span upto26'-0"
2. Check the Vf per foot columns in the Non-Snow—125% (PLF) table until
a load in excess of 93 plf is located. A12" shallow end depth Red-165™
exceeds the required 93 plf
3. To determine the depth at the deep end, multiply the slope times the length
(to calculate the amount of rise) and add to the shallow end depth.
Therefore 0 25 x 26 H- 12" = 18 5" depth at deep end
SNOWDRIFT LOADING
Wind direction, site exposure and roof type and shape are some of the
factors that can dramatically influence the accumulation of snow on a
roof structure ASCE 7 (Minimum Design Loads tor Buildings and Other
Structures) and the applicable building code, as well as other local state and
regional codes, provide guidelines for calculating snowdrift loadings on all
types of building construction
Drifts usually occur at locations of discontinuity in a roof such as at parapet
walls, valleys, or where a high roof meets a low roof. Closer on-center
spacing or additional support may be required at these locations Examples
above illustrate potential snowdnft conditions.
The project design professional is ultimately responsible for determining any
additional loads due to snow drifting
^
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t- P«J^et- ' Project- Pf«^cct Name
Structural Engineers F^t*^^ ^^^^^k*«,r>'^
, ^ . Engr- O. Gonzalez
Sheet No
Project 8000A .
Date. 7/31/2011.
Stud Wall Design
20W>CBC, NDS 3 9.2
Location: Typical stud wall Stud height = TOS - joist depth-curb ht
Stud Grade = D.F. #2 Stud height = 14 ft. Stud height^ 16 8
CBC or DSA? CBC Stud spacing = 16 inches on center
Fc = 1350 psi Stud Size = 2x6 Top of shtg 19 ft
Fb = 900 psi Width = 1.5 inches Joist depth = 1.66 ft
E = 1,600,000 psi Depth = 5.5 inches curb tit = 0.5 ft.
^min — 620,000 psi le/d, max. 50 height =
E' =
mm
Emin*CM.E*Ct*C|.CT le/d = 31 < le/d, max OK! 14
E min ~ 620,000 psi fc = 242 psi fc = P/A
C = 08 FcE = 546 psi FcE = 822*E'min/(le/d)'^2
Occup Category= lil F* =
' c
2376 psi F*c = Fc*Co*Cm.pc*C,*Cp_
Wind (P,et3o) = X*Kzt*l*P,e, Fc' = 517 psi F'c = FC'CD'CM.FC'CI'CF.
1 = 1.15 fb = 1017 psi fb = M*12/(b*cl'^2/6)
PnetSO = 14.1 psf Fb' = 2527 psi F'b = Fb*CD*CM_Pj,*C,*Ci_*
X= 1.21
K^t = 1.00 see ASCE 7 6 5 7
w, wind = 19.6 psf
Moment = 481 ft-lbs/ft
Axial load = ^fSOO lbs/ft
Cp = (HF,E/FV(2*c)-sqrt(((H-FeE/F*,)/(2*c))'^2-(FcE/F\)/c))
ratio = (fc/Fcr2+fb/(Fb'(1-(fc/FcE))<= 1 00
0 22 + 0.72
Use 2 x 6 studs
0 94 < 1.00 Okay
16 in o/c
Load Duration Factor (Table 2 3 2)
Duration, CD= 1.60 1 00 for normal, 1.6 for wind, 1 6 for seismic
Wet Use Factor for Fb (Table 4A)
Wet Use, Cwjib = 1.00 1 00 @ normal conditions, 0 85 @ exposed conditions, when Fb *Cf<1150 psi, Cm = 1 0
Wet Use Factor for Fc (Table 4A)
Wet Use, CM FC = 1-00 1.00 @ normal conditions, 8 @ exposed conditions, when Fc*Cf<750 psi, Cm = 1.0
@ Fc*Cf_fc = 569 psi, Cm = 1 0 Fc*Cf_fc = ## psi
Wet Use Factor for E (Table 4A)
Wet Use, CM E = 1-00 1 00 @ normal conditions and 0 90 @ exposed conditions
Size Factor for Fb (bendina)
Size Factor, Cp= 13 1 5 @ 2x4, 3x4, 4x4, 1 3 @ 2x6, 3x6, 4x6, 4x8, 1 2 @ 2x8, 3x8, 4x10
1 1 @ 2x10, 3x10, 4x12, 1 0 @ 2x12, 3x12
Size Factor for Fc' (compression)
Size Factor, Cp ^c = 1.10 1 15 @ 4 inch deep members, 1 1 @ 6 inch deep members, 1.05 @ 8 inch
deep members, 1.0 @ 10 and 12 inch deep members & 0.9 for 14 inch deep members
Bending Stress Increase in lieu of the Repetitive Factor for Fb'. see CBC section 2306 2
Rep. Factor, C, = 1.35 2x4 =1.5, 2 6 = 1 35, 2x8 = 1 25, 2x10 = 1 2, 2x12 = 1 15
The following factors = 10, C, (temperature), Cy (Buckling stiffness), 0^, (Fiat Use ), C, (incising), CL (Beam Stablity)
Page 1
0^ Project. RpojecHSteme
Structural Engineers
Engr OaSSTTialez "^.^
Sheet No ^
Project. 8000A
Date. 8/2/2011
Stud Size =
Width =
Depth = 3.5 inches
le/d, max. 50
Stud Wall Design
2007 CBC, NDS 3.9 2
Location: Typicai stud wall
Stud Grade = D.F. #2 ^\ Stud height = ^±£F>
CBC or DSA? CBC
Fc = 1500 psi
Fb= 1000 psi
E = 1,700,000 psi
Emin= 620,000 psi
E mm ~ EiTOn*CM_E*Ct*C|.CT
E'min = 620,000 psi
c= 08
Occup. Category= ill
Wind (PnetSo) = rKzt*l*Pne,
1= 1.15
PnetSO =
X =
Kz,=
w, wind =
Moment =
Axial load =,
Stud height = TOS - joist depth-curb ht.
Stud height = 13.0
Top of shtg •• 14 ft
joist depth = 1 ft
curb ht =
le/d = 48 < le/d, max OK!
fc = 179 psi
FcE = 221 psi
F*c = 2760 psi
Fc'= 217 psi
fb= 192 psi
Fb' = 3600 psi
765 7
3x4
2 5 inches
0 ft.
height =
14
fc = P/A
FcE = 822'E'min/(le/d)'^2
F*c - Fc*CD*Cy_p(;*Ct*Cp_pt.*C,
F'c - Fc*CQ*CM.pc*Ct*Cp_Fi;*C|*Cp
fb= iVl*12/(b*d'^2/6)
F'b - Fb*Cp*CM_Fb*Ct*C|.*Cf_Fb*Cfu*C|*Cr
Cp = (1+F,E/FV(2*c)-sqrt(((H-FcE/F%)/(2*c))'^2-(F,E/F\)/c))
ratio = (fc/Fc'r2+fb/(Fb'(1-(fc/FcE))<= 1.00
^^^^^^^^^^
0.68 + 028 = C_0.96 <).00 Okay
Use 3 X 4 studs @ 8 in o/c
Load Duration Factor (Table 2.3.2)
Duration, CD= 1.60 1 00 for normal, 1 6 for wind, 1 6 for seismic
Wet Use Factor for Fb (Table 4A)
Wet Use, CM_P5 = 1.00 1 00 @ normal conditions, 0 85 @ exposed conditions^, when Fb *Cf<1150 psi, Cm = 1.0
Wet Use Factor for Fc (Table 4A)
Wet Use, CM FC = 1-00 1 00 @ normal conditions, 8 @ exposed conditions, when Fc*Cf<750 psi, Cm = 1.0
@ Fc*Cf_fc = 250 psi. Cm = 1 0 Fc'CfJc = ## psi
Wet Use Factor for E (Table 4A)
Wet Use, CM E - 1-00 1 00 @ normal conditions and 0 90 @ exposed conditions
Size Factor for Fb (bending)
Size Factor, Cpjb = 1.5 1.5 @ 2x4, 3x4, 4x4, 1 3 @ 2x6, 3x6, 4x6, 4x8, 1 2 @ 2x8, 3x8, 4x10
1.1 @ 2x10, 3x10, 4x12, 1 0 @ 2x12, 3x12
Size Factor for Fc' (compression)
Size Factor, Cp pc - 1.15 1 15 @ 4 inch deep members, 1 1 @ 6 inch deep members, 1 05 @ 8 inch
deep members, 1 0 @ 10 and 12 inch deep members & 0 9 for 14 inch deep members
Bendina Stress Increase in lieu ofthe Repetitive Factor for Fb'. see CBC section 2306.2
Rep Factor, = 1 5 2x4 =1 5, 2 6 = 1 35, 2x8 = 1.25, 2x10 = 1 2, 2x12 = 1.15
The following factors = 10, C, (temperature), Cj (Buckling stiffness), C,u (Fiat Use ), C, (incising), CL (Beam Stabiity)
Page 1
Structural Engineers
Location: Typical stud wall
Project- Project Name
:^t*^C^A ^^Engr- 0-@®t^[ez
Sheet No x^f"
Project 8000A
Date 8/2/2011
Stud Grade =
CBC or DSA?
Fc =
Fb =
E =
^mm ~
E' =
*— mm
- - -E',
D.F. #2
CBC
1350 psi
900 psi
1,600,000 psi
620,000 psi
Emin*CM_E*Ct*C|.Cj
_620,000 psi
08
ill
Stud Wall Design
2007 CBC, NDS 3.9.2
Stud height = TOS - joist depth-curb ht.
tTfP) Stud height = 13.0
t^iggfiegon center
2 X 6 i Top of shtg- 14 ft
joist depth = 1 ft
curbht = 0 ft.
height =
Stud height
Stud spacing -•
Stud Size =,
Width 1f5*incl1fs
Depth = 5 5 inches
le/d, max 50
• mm-
C =
Occup. Category=
Wind (PnetSo) = ^*Kzt*l*P,e,
1= 1.15
Pnet30 =
X =
Kzt =
w, wind =
Moment
Axial load
le/d = 31 < le/d, max OK!
fc-= - - 380 psi -
14
I
14.1 psf
1.21
1.00 seeASCE 765 7
FcE = 546 psi
F*c = 2376 psi
Fc'= 517 psi
fb = 259 psi
Fb' = 2527 psi
i
- fc=-P/A . _
FcE = 822*E'min/(le/d)'^2
F'c - Fc*CD*CM.Fc'Ct*CF_Fc*C|*Cp
fb= M*12/(b*d'^2/6)
b ~ '-'D ^M_Fb '>^f_Fb ^fu ^i
Cp = (1-HFcE/F*c/(2*c)-sqrt(((1+FcE/F*c)/(2*o))'^2-(F,E/F*e)/c))
ratio = (fc/Fc')'^2+fb/(Fb'(1-(fc/FcE))<= 1.00
0.54 + 0.34
Use 2 x 6 studs
0 88 < 1.00 Okay
16 in o/c
Load Duration Factor (Table 2.3.2)
Duration, CD= 1.60 1 00 for normal, 1 6 for wind, 1 6 for seismic
Wet Use Factor for Fb (Table 4A)
Wet Use, CM PO = 1.00 1 00 @ normal conditions, 0 85 @ exposed conditions, when Fb *Cf<1150 psi, Cm = 1 0
Wet Use Factor for Fc (Table 4A)
Wet Use, CM.FC= 1.00 1 00 @ normal conditions, 8 @ exposed conditions, when Fc*Cf<750 psi, Cm = 1 0
@ Fc*Cf_fc = 569 psi. Cm = 1 0 Fc*Cf_fc = ## psi
Wet Use Factor for E (Table 4A)
Wet Use, CM E - 1-00 1 00 @ normal conditions and 0 90 @ exposed conditions
Size Factor for Fb (bending)
Size Factor, Cpjb = 1.3 1 5 @ 2x4, 3x4, 4x4, 1.3 @ 2x6, 3x6, 4x6, 4x8, 1 2 @ 2x8, 3x8, 4x10
1 1 @ 2x10, 3x10, 4x12, 1 0 @ 2x12, 3x12
Size Factor for Fc' (compression)
Size Factor, Cp p^ = 1.10 1.15 @ 4 inch deep members, 1 1 @ 6 inch deep members, 1 05 @ 8 inch
deep members, 1.0 @ 10 and 12 inch deep members & 0 9 for 14 inch deep members
Bending Stress Increase in lieu of the Repetitive Factor for Fb'. see CBC section 2306 2
Rep. Factor, Cr = 1 35 2x4 =1 5, 2 6 = 1 35, 2x8 = 1 25, 2x10 = 1 2, 2x12 = 1 15
The following factors = 10, C, (temperature), Cj (Buckling stiffness), Cf^ (Fiat Use ), C, (Incising), CL (Beam Stablity)
Page 1
Project- Project Name
'2^<-f I ^-^^ 4^ E^*"- O-Gonzalez
Stud Wall Design
20WCBC, NDS 3 9 2
Sheet No:
Project 8000A
Date. 7/31/2011
Location: Typicai stud wall Stud height - TOS - joist depth-curb ht.
Stud Grade = D.F. #2 Stud height = 9 ft. Stud height = 9.0
CBC or DSA'? CBC Stud spacing = 16 inches on center i CBC or DSA'? CBC Stud spacing = 16 inches on center i IB 1
Fc = 1350 psi Stud Size = 2x4 Top of shtg 10 ft
Fb = 900 psi Width = 1.5 inches joist depth = 1 ft
E = 1,600,000 psi Depth = 3.5 inches curb ht. = 0 ft
Emm 620,000 psi le/d, max. 50 height =
mm Fmin*CM.E*Ct*C|.CT le/d = 31 < le/d, max OK! 9
E' =
mm
C =
620,000 psi
08
fc = 406 psi
535 psi
fc = P/A ^ r E' =
mm
C =
620,000 psi
08 FcE =
406 psi
535 psi FcE = .822*E'min/(ie/d)'^2
Occup. Category= lil F* =
r c
2484 psi F*c = FC*CD*CM_FC*C(*CF_PC*C,
Wind (Pnetao) = x*Kzt*rp„et Fc' = 509 psi F'c = Fc*CD*CM_Fc*Ct*Cp_pc*C|*C p
1 = 1.15 fb = 264 psi fb = i\/l*12/(b*d'^2/6)
Pnet30 = 14.1 psf Fb' = 3240 psi F'b = Fb*CD*CM.Fb*Ct*CL*Cf_ Fb*C fu*C,*Cr
X = 1.21 Cp = (UFcE/F*c/(2*c)-sqrt{((1-^F,E/F%)/(2*c))'^2-(F CE/F*C)/C))
w, wind •
Moment •
Axial load •
1.00 see ASCE 7 6 5.7
5 0 psf
JS/ft
'1600 lbs/ft
ratio = (fc/Fc'^2-^fb/(Fb'(1-(fc/FcE))<= 1.00
0 64 + 0 34
Use 2 X 4 studs
0.98 < 1.00 Okay
16 in o/c
Load Duration Factor (Table 2 3.2)
Duration, CD= 1.60 1 00 for normal, 1 6 for wind, 1 6 for seismic
Wet Use Factor for Fb (Table 4A)
Wet Use, Cw.Fb - 1-00 1 00 @ normal conditions, 0 85 @ exposed conditions, when Fb *Cf<1150 psi, Cm = 1 0
Wet Use Factor for Fc (Table 4A)
Wet Use, CM_FC= 1.00 1 00 @ normal conditions, 8 @ exposed conditions, when Fc*Cf<750 psi, Cm = 1 0
@ Fc*Cf_fc = 585 psi, Cm = 1.0 Fc'CfJc = ## psi
Wet Use Factor for E (Table 4A)
Wet Use, CM E ~ 1-00 1 00 @ normal conditions and 0 90 @ exposed conditions
S;ze Factor for Fb (bendina)
Size Factor, Cp fb = 1.5 1 5 @ 2x4, 3x4, 4x4, 1 3 @ 2x6, 3x6, 4x6, 4x8, 1 2 @ 2x8, 3x8, 4x10
1 1 @ 2x10, 3x10, 4x12, 1 0 @ 2x12, 3x12
Size Factor for Fc' (compression)
Size Factor, Cp pc = 1.15 1 15 @ 4 inch deep members, 1 1 @ 6 inch deep members, 1 05 @ 8 inch
deep members, 1 0 @ 10 and 12 inch deep members & 0 9 for 14 inch deep members
Bendina Stress Increase in lieu ofthe Repetitive Factor for Fb'. see CBC section 2306 2
Rep. Factor, C^ = 1 5 2x4 =1 5, 2 6 = 1 35, 2x8 = 1 25, 2x10 = 1 2, 2x12 = 1.15
The foiiovwng factors = 10, Of (temperature), Cj (Buckling stiffness), Cf^ (Flat Use ), 0, (incising), CL (Beam Stablity)
Page 1
Structural Engineers Project Project Name Copy to your directory first
Engr O Gonzalez
Allowable Post Loads
CBC 2010, Sec 2307
Grade =
Fc4 =
E4 =
Emin4 —
E min4 ~
Fee =
E6 =
Emln6 =
E mine -~
c' =
le/d, max =
Fbrg =
D.F. #1
1500 psi
1,700,000 psi
620,000 psi
620,000 psi
1000 psi
1,600,000 psi
580,000 psi
580,000 psi
0 80
50
625 psi
FcE4 •
FcE6 •
822*E'm,„4/(le/d)'>2
822''E'm,„6/(ie/d)'^2
@ 4xposts
@ 4xposts
@ 4xposts
@ 4xp0StS, E,^,n*CM_E*C,*C,*CT
@ 6xposts and larger
@ 6xposts and larger
@ 6xposts and larger
@ 4xposts, E^,„*CM_E*C,*C *CT
(0 80 for sawn lumber, 0,85 for poles, 0 90 for giue-iaminated lumber
Sheet S 4 ^
Project No 8220A
Date. 7/31/2011
F*c6 - FC*CD*C|VI_PC*C(*CP_PC*C|
F'c = F;((1 +(FcE/Fc))/(2*c')-sqrt(((1 +(FcE/Fc))/(2*c'))-2-(FeE/Fc)/c'))
F'C ~ Fc*Cp*CM_p(.*C(*Cp_pc*C|*Cp
Pali= A * F'c*Cd*Cm*Cf
I
I
I
Duration Factor
1.00 for Fc only, Cd = 1 0 for Fbrg
Wet Use Factors for Fc
Wet Use, Cm = 1 00
Wet Use, Cm = 1.00
W/et Use Factors for E
WetUse, Cn,= 1.00
Wet Use, Cm =
Size Factors for Fc
Size Factor, Of =
Size Factor, Of =
Size Factor, Cf =
Size Factor, Cf =
Size Factor, Cf =
The following factors
! 4x's- 1 00 @ normal conditions and 0 80 @ exposed conditions, when Fc*Cf<750 psi. Cm = 1 0
! 6x's and larger 1 00 @ normal conditions and 0 91 @ exposed conditions
J 4x's 1 00 @ normal conditions and 0 90 (
1 00 @ 6x's and larger
! exposed conditions
115 @ 4x4 posts
1 10 @ 4x6 posts
1 05 @ 4x8 posts
1 00 @ 4x10 posts
1 00 @ 6x posts and larger
1 0, Cf (temperature), C^ (Buckling stiffness), Cfu (Fiat Use ),
Post
Size
4x4
8
10 x 4
4x6
8
10 x 6
12 x 6
4 x
8 8
10 x 8
12 x 8
Allowable Post l/oads, kips
Height
8 10 11 12 13 (W"^ 15 16 17 18 19
cismg), CL (Beam Stablity), Cr (Repetitive)
75 . 5.0
11.7 f 9.5 )7.8
15 10
19 13
42
6.6
11
3 5
56
3.9
6.1
2.6
4.1 h/d exceeds 50
22
33
45
57
68
19
29
40
51
60
17
26
35
44
53
15
22
31
39
46
13
20
27
34
40
14
17
23
30
35
12
16
20
24
11
14
18
22
13
16
19
12
15
18
37
54
74
93
110
35
51
70
89
105
33
48
66
83
99
30
45
61
77
91
27
41
56
71
84
33 22
37 34
51 46
64 58
76 69
20
31
42
53
62
18
28
16 15
38
48
57
25 23
34 31
43 39
51 46
13
21
28
36
42
Pendicuiarto
Gram Beanng
77
12
16
20
12
19
26
33
39
16
26
35
45
53
2007 Post Table XLS
(Oont.)
(All species except Soutliern Pine — see Table 48) (Tabulated design values are for normal load
duration and dry service conditions. See NDS 4.3 for a comprehensive description of design value
adjustment factors.)
USE WITH TABLE 4A ADJUSTIWENT FACTORS
Species and
commercial grade
Size
classification
Design values in pounds per square inch (psi)
Species and
commercial grade
Size
classification
Bending
Fb
Tension
parallel
to gram
Ft
Shear
parallel
to gram
Fv
Compression
perpendicular
to gram
Fci
Compression
parallel
to gram
Fc
Modulus
of
Elasticity
Grading
Rules Species and
commercial grade
Size
classification
Bending
Fb
Tension
parallel
to gram
Ft
Shear
parallel
to gram
Fv
Compression
perpendicular
to gram
Fci
Compression
parallel
to gram
Fc E FfTiin Agency
BEECH-BIReH^HIGKORY: ;f
Select structural
No1
No 2
No 3
\Stud-;..,-|;t '•'••'i^fi-l*^.
2" & wider
fcg','^4j«|de^
1,450
1,050
1,000
575
;*:-*775-.
850
600
600
350
195
195
195
195
715
715
715
715
>s»'r'^7i5'-.
1,200
950
750
425
iiiimsobj
1,700,000
1,600,000
1,500,000
1,300,000
•-•-;'M;3ooi6ooi'
§m3MSSit
|fff{tll200,QOg|
620,000
580,000
550,000
470,000
' ;; r'' ,'47d;ood:
ItlSSIa'odoS
NELMA
COTTONWOOD
Select Structural
No1
No 2
No 3
rStud. r--*-:.?
IS^i: Mm
2" & wider
'•.lai'&wider -
f 2"-4"wKte .
875
625
625
350
.?.v*'475t-
525
375
350
200
.'•'•t :;.275-.V
125
125
125
125
-•>'•»;,•-,1,25
ftiSiilsii
320
320
320
320
:;,'s'-if320^-
775
625
475
275 •v:u'.';'-3oo'-
1,200,000
1,200,000
1,100,000
1,000,000
!;---<l1;000;000 „
440,000
440,000
400,000
370,000
>•,'. 37o;ooo.,
iSiHI
NSLB
DOUGLAS FIR-LARCH
Select Structural
No 1 & Btr
.No1 2" & wider
1,500
1,200
1,000,
1,000
800
675
180
180
180
625
625
625
( 1,700,, ^rsso
1,500--
i 1,900,000
1,800,000
1,700,000
690,000
660,000
620,000
- WCLIB
WWPA
No 2
No 3 Stud; .>.s:t -PSr w^':^ SI'S iGooitamtsMSiis
liiMaii^iaiiiai
•'r'saT&.wiaef.^;
900
525
:IY\'70o;;
jiijdfib';!
iSilziS
575
325
:,':450-i
illilil msm
180
180
.r••„••'<,i8o;:
625
625
Vr :;,-;r~,625;-.
'**'ijhi5%S825f*i
5im;%25-F|
1,350
775
-'-;850'>.
1,600,000
1,400,000
%i?,.C,1^400;000!,|
'€"%!ii#oo;ooo*if
f|Sil'B3pp,O0C)S<
580,000~
510,000
%\|,i5:-'5io;ooof;
*»5S|5|o;op|
- WCLIB
WWPA
DOUGLAS FIR-LARCH (NORTH)
Select Structural
No 1 & Btr
No 1/No 2
No 3
:stuB;^ "Itrils/'-iS-Jrj;^!
2" & wider
<;:;2j&'widei-|j,
|M|tf|f|i.cfgsf-
1,350
1,150
850
475
{650.^.:
P|?950|S
yllfSoS
825
750
500
300
A-.fiS4!l50siS
180
180
180
180
I'X'J: .iiisoi..
625
625
625
625
-vV^S .f ..625'..*-
#Mfe?&25T>
1,900
1,800
1,400
825
r ,".-,"%oo-<
1,900,000
1,800,000
1,600,000
1,400,000
-•.t''H-,ir400,O0Oi
•issftfSoKooo??,
f^CiliSoMffoi".
690,000
660,000
580,000
510,000
•/.>.':..:..5io,oo()'i
NLGA
DOUGLAS FIR-SOUTH
Select Stnjctural
Nol
No 2
No 3
2" & wider
S»¥2r&»wiHefC
1,350
925
850
500
•i:»s'';675;'*
900
600
525
300
180
180
180
180
520
520
520
520
«• T'lSSiKog
1,600
1,450
1,350
775
i;-'.:.850i3t
mi^l'Ms.
l'»''?#Ss<R9Q0>*
1,400,000
1,300,000
1,200,000
1,100,000
i>r'si;ioo,ood)'
Pif^jaos'Soii
fMi»i!iG!00,'oooe
510,000
470,000
440,000
400,000
S'ltSlStol
WWPA
f ja^sf ERN, H^MBO^^
Select Structurai
No1
No 2
No 3
-stod' -• '.-•y-i.:;-is^f...f,-;w-^<
iCo®fljaon1f««j&
2" & wider
f?T2"'&'wiaer,',
1,250
775
575
350
575
350
275
150
v;':;,;>2oo,,;.'=
140
140
140
140
;f/"iSl4p?.
:..yfi»'il40-*»i
335
335
335
335
,\,fc;i.3-,--;335 r
l|Mf2:3354s.
iSl#3.35|?
1,200
1,000
825
475
J-fsi-Vf 525"'
1,200,000
1,100,000
1,100,000
900,000
:'-f'E,|90o;ooo'-
^P^fifooOiWof.
IJISfeboSoSfe
%-f|if8fO;topi?
440,000
400,000
400,000
330,000
*,".>;;.'33p;000';
*rI'Wli370^#?j
i€%:*S'29,g,O0Q5
NELMA 1
NSLB <
AiVlERICAN WOOD COUNCIL
Page Spread 3500 xls
Soil Capacity *
Concrete, f c
Remforcement, fy
3500 psf
3000 psi
60,000 psi
* Increase 0 psf for each in width from 2
feet, with 2000 max.
Increase width from = 2 ft.
Increase = 0
Maximun Increase = 3500 psf
Square Spread Footing Design
(2010 CBC)
F8 F7 F6 F5 F4 F3
Size, WxB 8.0 7.0 6.0 5.0 4.0 3.0
Ai-ea, ft'^2 64.0 49 0 36 0 25 0 16.0 90
Footing Thickness, in 21 18 15 15 15 12
Soil Bearing Capacity 3500 3500 3500 3500 3500 3500
P, allowable, kips CF~207 '^^'-"779 P CJl Fso Pu, allowable, P*l.55 321 249 185 128 82 ~ 47
Column Size, in. 10 10 10 10 10 10
Effective Ftg, d, in 17 14 11 11 11 8
Soils Pressure, ksf 5 0 5 I 5 1 5 1 5 1 5.2
Shear:
Punching shear, kips 296 228 169 113 66 35
Vu, allowable, kips 342 250 172 172 172 107
Vu OK Vu OK Vu OK Vu OK VuOK Vu OK
Beam shear, kips 109 9.7 8.6 6.0 34 22
Vu, allowable, kips 19.0 15.6 123 12 3 12.3 89
Vu OK Vu OK Vu OK Vu OK Vu OK Vu OK
Bending.
Mu, fl-kips 32.2 24 I 17 1 11 1 6.4 3 0
Ku, psi 124 137 157 102 59 53
P 0.0021 0.0023 0 0027 0.0017 0.0010 0 0009
As, in''2 4 60 3 67 2.85 1.53 0 70 0.34
Number of Rebars 8 7 7 6 5 4
Rebar size #7 #7 #6 #5 #5 #5
As, actual, in.'^2 4.80 4 20 3 08 1.86 1 55 1.24
As OK ,^s OK As OK As OK As OK As OK
F2.5 F2
Size, WxB 2.5 2.0
Area, tf'^2 63 40
Footing Thickness, in. 12 12
Soil Beanng Capacity
P, allowable, kips
Pu, allowable, P*1.55 32
_ 3500
Column Size, in. 8 8
Effective Ftg, d, in 8 8
Soils Pressure, ksf 5 2 5.2
Shear:
Punching shear, kips 23 12
Vu, allowable, kips 95
Vu OK
95
Vu OK
Beam shear, kips 1 3 0.0
Vu, allowable, kips 89
Vu OK
89
Vu OK
Bending-
Mu, ft-kips 2.2 1.2
Ku, psi 38 20
P 0 0006 0 0003
As, in''2 0 20 0 09
Number of Rebars 3 3
Rebar size #4 #4
As, actual, in ^1 0.60
As OK
0 60
As OK
7/31/2011 Spread 3500 xls
J _ _ _ SHEET. L-l
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fl<jF
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I " K' IMJ U//HA^
Z^' I- ^-,^7
L-lo
How to Enter Data
h= 10 ft
b =
V =
HE
/
15
300 I plf
Wood Panel Grades or Species Group Numbers
I Structural I j " G = 90,000 psi
Nominal thickness of wood panel
3/8-U
Interior Edge Nailing
S d ' I (®
in o.c
* = 0.278 psi
Unsanded
150
0.0360
pounds/ 8d
m
7 -Y
0.470
OK
in
Boundary Element
Species Douglas Fir-Larch
Grade No 1
DFL No. 1
# 2
(in) nominal b 2
(in) nominal d 4
(in) actual b 3.00
(in) actual d 3.50
(in') S 6.13
(in') A 10.50
On') 1 10.72
(psi) E 1,700,000
Holddown Selection
Holddown connecting to
HD2A
Studs Below
0.707 in
8vh'
EAb
(bending)
0.0090
0.4704
Vh
Gt
(shear)
0.1199
0.75 he, hd.
(nail deformation) (chord splice slip)
+ 0.2700 0.0715
V
h
b
E
A
G
t
e„
d.
maximum shear due to design loads at the top of wall (plf)
wall height (ft)
wall width (ft)
elastic moduus of boundary element (vertical member at shear wall boundary) (psi)
area of boundary element cross section (sq in )
modulus of rigidity of wood structural panel (psi)
effective thicl(ness of wood structural panel for shear (in)
nail deformation (in)
deflection due to anchorage details (rotation and slip at tie-down bolts) (in)
How to Enter Data
h = 10
V =
85
265 plf
Wood Panel Grades or Species Group Numbers
Structural I ~| • G = 90,000 psi
Nominal thickness of wood panel
3/8-U
Interior Edge Nailing
I 8d I @
in 0 c.
0.278 psi
Unsanded
A
7 y
/•
:••/
/
/
/
/
e„ =
133
0.0280
pounds / 8d
in
July 22, 2011
0.451 in
OK
Boundary Element
Species Douglas Fir-Larch
Grade No 1
DFL No.l
It 2
(in) nominal b 2
(in) nominal d 6
(in) actualb 3 00
(in) actual d 5.50
(in') S 15 13
(in') A 16.50
On') 1 41.59
(psi) E 1,700,000
Holddown Selection
Holddown connecting to
HD2A
Studs Below
0.107 in
8vh'
EAb
(bending)
0.0089 [
0.4510 I
vh
Gt
(shear)
0.1059
0.75 he. hd.
(nail deformation) (chord splice slip)
I 0.2*00 I -I- 1 0.1262 I
V
h
b
E
A
G
t
d.
maximum shear due to design loads at the top of wall (plf)
wall height (ft)
wall width (ft)
elastic moduus of boundary element (vertical member at shear wall boundary) (psi)
area of boundary element cross section (sq.in.)
modulus of rigidity of wood structural panel (psi)
effective thickness of wood structural panel for shear (in)
nail deformation (in)
deflection due to anchorage details (rotation and slip at tie-down bolts) (in)
^
PROJECT
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DATE
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DATE
F^ %i^Hi'
4T
Hiiri -r 111 ii.iri...iiii I ' I II. B^aSW V *
1^ Vkh
4
F
103 5
-103 5
Loads BLC 1, lat
Results for LC 1, lat
Member z Bending IVloments (k-ft)
SK-1
Aug 2, 2011 at 2:25 PM
untitled r3d
Company
Designer
Job Number
Aug 2, 2011
2 26 PM
Checked By._
Joint Deflections
1 1 Nl 0 0 0 0 0 0
•' '-f =7'? c'C!t^2-,:-7'}' t, 7* 7'* 7o^^>.; = ^'-;>0:-'-77 ?7'^;0i-v-; '-'7-7*-0;?#i7v,-
3 1 N3 0 0 0 0 0 0
153733^ • ^ -WftU:^ „ ,p t-' 0 j» 7'',r' 777'dl'i7<^ \"-^7M'2e-^7
5 1 N5 0 0 0 0 -5.218e-4
'.•,€6?'-:FS^:333'7st' 7^-CSciGii v;''"-0'7f*^^; :7r^*^o';^7-^ 7~l;1-i19^^3'-:i
Joint Reactions (By Combination)
1 1 Nl -16.118 -6 321 0 0 0 / 146 079
42'.; •'•77.-.vN275?^i^ S7?^2isb3fi.j5 :77^i0i01^7fc >.0--i''t--'ri P iti^o'^Jfe':^: ;^fi67:775r^':-
3 1 N3 -16.847 8.322 0 0 0 V 149.208
.,'/A'i:j"4T.otils:;:'„.«=i" ^- 77^7>7?^
5 1 COG (ft). NC NC NC
Member Section Forces (By Combination)
1 1 Ml 1 -6.321 16.118 0 0 0 146.079
72:; 7'*7''",/ ,f'"?i7^- -^i-.^-' • l-?*'^ ,;..2;' 7-6:321: -"16.1:18 : .' v--:-.o-T , -. 7" drii-r/v i,':-t':,*^i':: •,;;t3-3?354«-t
3 3 -6.321 16.118 0 0 0 120.629
^ ^ 7 j--'4?,,; . :6f321,: ; -'ll 6:118 7 • : ' Q -71(37:90^':
5 5 -6.321 16.118 0 0 0 95.179
;'6'^ :.&:< ,:-6;321/ ; 7-i6:tf8''v :,;• 0^ !^.-^ _~*.o>^; '" 82!-45y-->-'
7 7 -6.321 16.118 0 0 0 69.729
:.8i 'T;r - A ir'Mi-^i''8;'-' '7^>32T^4 : 16.118-7 ' -.t-'/it.ojt :7 77;:^)'-^--" :'"o^:.''v. T57.Qb47:t'
9 9 -6.321 16.118 0 0 0 44.279
;:'ib> 7l-*.-7*;"7' ,5l'0I;r ':<-;,;'-:6:32.i:*''"'^ 7'16:1 f 87. ' *":''7o::7':':'; :^>:77-0T"' i',^ '77 jO-7 .V:31':554:v-f
11 11 -6.321 16.118 0 0 0 18 829
:H12^-r i . •V-.'12':" -6:321" ',16.118, • 'd\' o--:-;,-0 -V---'y;;6;io4:-:;
13 13 -6 321 16.118 0 0 0 -6 621
14^ 'V T6 3217 -,76:i;i&i" 7 . • -^0*-';" 7-^-^0'. 7: •,f9^346'';"
15 15 -6.321 16.118 0 0 0 -32.071
M6: " m' V6;32i::^5; ;16.'118 . ' -. V, -io"'' -^ 0' • " • r44.'796
17 17 -6 321 16.118 0 0 0 -57.521
18^ i..18,-> ^'7^6:321;-. • >7l6:jl8:.' •• .i^b-:--'.:;, ':.---o-'.:. : ., -70:246- :
19 19 -6.321 16.118 0 0 0 -82.971
20 r'-'-' -\7w 720^-" • = 'f 6.32.1'. ':-^t6.ii^, ,v o-.;*;^^-i ''{i^^'b-57 ' /OV'"' '45:696..-v
21 1 IV12 1 -2.001 21.034 0 0 0 167.775
22 V'27 :' -2:001 ,.; 21.034. . - '••'•' 0:..' ••' . •, 0, " 151.169-
23 3 -2.001 21.034 0 0 0 134.563
24-:"';4''^;: :-2:001: - ~ !: 21.034 T -'0 -?'':• "S-;b - 0 .. ,,i 171957'.
25 5 -2.001 21.034 0 0 0 101 351
26 'i"' ';'...>"7 ' 'y ' ,'6"': -2.001" , .21.034 .,0'-" V 0'- , ' 84:745_ : ,
27 7 -2.001 21.034 0 0 0 68.139
28 ;-8''--t:-2:001 ; 21:034 ' //:'o-: ' -0, . .> 0" ' 51.533 '
29 9 -2.001 21.034 0 0 0 34.927
.30'. io -2:001 21.034 0:':--,^0 : 7 0 : '18.321 ;
31 11 -2.001 21.034 0 0 0 1 715
32 •:.:r.s . :^ •i^' •• 12 -2:001 ,; 21.034 .0 -0 , 0 , .-14;891
RISA-3D Version 8 1.2 [C:\RISA\untitled.r3d] Page 1
Company
Designer
Job Number
Aug 2, 2011
2 26 PM
Checked By..
Member Section Forces (By Combination) (Continued)
33 13 -2 001 21.034 0 0 0 -31 497
$34^ ^157: •7:7?''^""".''' 7/ *Ijiii7 7515.00^^7 "7217034. 'i v:i*«7:-'^-•;7-:o77^; ;it£fd"7s,; ^ ••S48?iib3^'l7
35 15 -2 001 21.034 0 0 0 -64 709
v36'i ^« '7 ^*1-6f 77-Zddi::,: :ri72i7d34:7 ^»''7'=d7>^. J7;^81*:31'57'-'
37 17 -2.001 21.034 0 0 0 -97.921
7' Sy"^ ;7;^'-2:odi7-: :.^321^034si7 ••f >>?7'" Q> "Y'-'^'A 77»v;:^)777"t;, '•:'•.-./:., o,:.'-*"'i'* :^ti 4:527:7
39 19 -2 001 21.034 0 0 0 -131 132
,~:4oi-'/,-t7 ••i'7« 7-777> 7:20^: :7;-'-=2:0dT'':" 777d7''7; f77oi7v?7: ^7r1i7773^7
41 1 M3 1 8.322 16.847 0 0 0 149.208
-,'|'2*-7..4:^'"".';iS^*^^"7t. 7*:277 77-8:3227*. •7;i678477*.v ,7:o77ie 7l!-35:9blf.'
43 3 8.322 16.847 0 0 0 122 607
•*44u w>l77''^itr27.' 77:8:1322^77: •7 i6:847r.; ':v'7..0^-\-7^ 'iki'^/iO},^' •;.:. "*lb9:3067
45 5 8.322 16.847 0 0 0 96.006
,/:46-^ .t,','r': ",3.',''':,?r.i:'ji:-.i ::''6 • 7,: 87322'':i*>. 'i:,7t)?.7ff? 7^.-:d7v;v; 777-xb7=S7 ••;!8277d5->'«'
47 7 8.322 16.847 0 0 0 69.404
':"',\:: i?'':: •"-'7)-!" ^78*'-7«.'873227 :r 16.847: :^ I" t<W^M ?77'f-:d'-::7r 7'-t'B^77.e^ :567lid477
49 9 8.322 16.847 0 0 0 42.803
;-50 •»vi»'\i77l-.i5t-b;*:; ?-^37 8?322 V :' 16:S47^!7 7»:7d7/"? 7^'t."Ci•7"~-lf ;''":~29;5037'.
51 11 8.322 16.847 0 0 0 16.202
,:-52f-', 7''-- 7 : \/^'^i i^a^ti 7 ' ' 7-4,J°-\7 ' 7^'''" f7i2:7 :78H322-i:'j: :'i 16:847":: :<\.7o;-'';*'7 7 7!dc< 7::'-77 7*d-77"7-/2:9o;i:7^'7
53 13 8.322 16.847 0 0 0 -10.399
547' 7 , (' -'t4J-r'7:8:322 •7.; '--^^i6.847j;i: ';^v;7{X7>r. 7.-o'"'=::7/ ;7- ;'o:";:'7 ,7>72377 ?7
55 15 8.322 16.847 0 0 0 -37
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RISA-3D Version 8.1.2 [C-\RISA\untitled r3d] Page 3
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UPDATED GEOTECHNICAL INVESTIGATION,
PROPOSED LEGOLAND CALIFORNIA HOTEL,
CARLSBAD, CALIFORNIA
Prepared for:
LEGOLAND California
One LEGOLAND Drive
Carlsbad, California 92008
Project No. 960151-034
April 22, 2011
I 1 L»# M\ L
960151-034
Table 2
2010 CBC (Seisnnic Parameters)
Description Values CBC Reference
Site Class D Table 1613.5.2
Short Period Spectral Acceleration Ss 1.260 Figure 1613.5(3)
1-Second Period Spectral Acceleration s, 0.476 Figure 1613.5(4)
Short Period Site Coefficient Fa 1.000 Table 1613.5.3(1)
1-Second Period Site Coefficient Fv 1.524 Table 1613.5.3(2)
Adjusted Short Period Spectral Acceleration SMS 1.260 Equation 16-37
Adjusted 1-Second Period Acceleration SMI 0.725 Equation 16-38
Design Short Period Spectral Acceleration SDS 0.840 Equation 16-39
Design 1-Second Period Spectral Acceleration SDI 0.483 Equation 16-40
4.4 Secondary Seismic Hazards
Secondary effects that can be associated with severe ground shaking follo-wing a
relatively large earthquake include shallow ground rupture, soil liquefaction and dynamic
settlement, lateral spreading, seiches and tsunamis. These secondary effects of seismic
shaking are discussed in the following sections.
4.4.1 Shallow Ground Rupture
No active faults are mapped crossing the site, and the site is not located within a
mapped Alquist-Priolo Earthquake Fault Zone (Bryant and Hart, 2007). Shallow
ground rupture due to shaking from distant seismic events is not considered a
significant hazard, although it is a possibility at any site.
4.4.2 Liquefaction
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fc:^' a Vi// 4 iJ
6.0 RECOMMENDATIONS
960151-034
The conclusions and recommendations in this repoit are based in part upon data that were
obtained from a limited number of observations, site visits, excavations, samples, and tests. Such
information is by necessity incomplete. The nature of many sites is such that differing
geotechnical or geological conditions can occur within small distances and under varying
climatic conditions. Changes in subsurface conditions can and do occur over time. Therefore, the
findings, conclusions, and recommendations presented in this report can be relied upon only if
Leighton has the opportunity to observe the subsurface conditions during earthwork operations
and construction of the project, in order to confirm that our preliminary findings are
representative for the site.
6.1 Site Preparation
A significant consideration regarding the planned site development is the presence of the
agricultural debris that was buried during mass grading below the site. The organic
content and potentially compressible nature of these materials necessitates measures to
mitigate the potential for adverse settlement. Two options, removal of agricultural debris
and deep foundations were previously presented in our early planning study report
(Leighton, 2008). It is understood that it is preferable to develop the site without
removing the agricultural debris.
6.1.2 Deepened Foundation Mitigation
The proposed hotel, pool and pool building should be supported on foundations
that extend below, or are outside the influence of the agricultural debris. The
limits of agricultural debris influence are illustrated on Figure 3. Piles should
develop capacity below an imaginary 1 to 1 projection from the hmit of influence
line, where the projection is inclined toward the zone of agricultural debris, and
becomes horizontal at an elevation of 103 feet above mean sea level. To mitigate
the potential differential settlement, piles should taper in depth over a distance of
at least 20 feet beyond the limits of the agricultural debris influence. It is also
noted that an existing storm drain line is present east of the proposed kitchen.
Foundations should also be deepened below a 1 to 1 projection from the bottom
of that trench. Foundations beyond the limits prescribed for deep foundations
maybe founded on shallow foundations. Where deep foundations are utilized, the
slab should consist of pile supported structural slabs. With this method,
differential settlement between site improvements and pile supported elements
may necessitate periodic maintenance.
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960151-034
In areas where shallow foundations are utilized, the existing site should be over
excavated at least 3 feet. Over-excavation should also extend at least 2 feet below
the deepest footings in areas where formational materials are anticipated at
shallow depth.
6.2 Foundation Desiqn Considerations
As discussed in the preceding section, we anticipate that the proposed improvements will
be supported on spread footings, drilled piles, and/or mat slabs. The following sections
address the recommendations for these types of foundation systems.
6.2.1 Conventional Spread Foundations
Footings should extend at least 18-inches beneath the lowest adjacent finish
grade. At these depths, footings founded in properly compacted fill soil or
formational material may be designed for a maximum allowable bearing pressure
3,500 psf The allowable pressures may be increased by one-third when
considering loads of short duration such as wind or seismic forces. The minimum
recommended width of footings is 15 inches for continuous footings and 18
inches for square or round footings. Footings should be designed in accordance
with the stmctural engineer's requirements and have a minimum reinforcement of
four No. 5 reinforcing bars (two top and two bottom).
The recommended allowable bearing capacity for spread footings is based on a
maximum allowable total and differential settlements of 1-inch and 3/4-inch.
Since settlements are fimctions of footing size and contact bearing pressures,
some differential settlement can be expected between adjacent columns, where
large diflferential loading conditions exist. With increased footing depth to width
ratios, differential settlement should be less.
We recommend a horizontal setback distance from the face of slopes and
retaining wall for all stmctural footings and settlement-sensitive stmctures. The
distance is measured from the outside edge of the footing, horizontally to the
slope face (or to the face of a retaining waU) and should be a minimum of H/2 and
need not be greater than 15 feet. Utility trenches that parallel or nearly parallel
stmctural footings should not encroach within a 1:1 plane extending downward
from the outside edge of footing. Please note that the soil within the stmctural
setback area posses poor lateral stability, and improvements (such as retaining
walls, sidewalks, fences, pavements, etc) constmcted within this setback area may
be subject to lateral movement, and/or differential settlement. Potential distress to
such improvements may be mitigated by providing a deepened footing or a pier
-18-
960151-034
and grade beam foimdation system to support the improvement. Deepened
footings should meet the setback as described above.
6.2,2 Drilled Pile Foundations
Drilled piles may be designed for the skin friction capacities shown in Figure 4
plus 7,000 psf for end bearing. The capacity of the pile should be reduced by the
capacity within the influence zone of the agricultural debris. Upward capacity
equal to one-half the value on Figure 4 may be utilized to resist tensile loads. Pier
settlement is anticipated to be less than 1/4 inch under design loads and normal
service conditions. The design chart contained in the accompanying Figure 4 is
based on center to center pile spacings of at least 3 pile diameters. Where piles are
spaced more closely, reduction in pile capacity is necessary. Constmction of piles
should be sequenced such that the concrete of constmcted piles are allowed to
setup prior to constmction of piles within 3 diameters. Lateral loads on the face of
caissons/piers may be resisted by using a lateral bearing of 300 psf/foot elevation.
Where piles are situated at least 5 diameters (center to center) apart, the effective
diameter of the pile may be increased by 1.5 for resisting lateral loads.
Intermediate cases can be evaluated on a case-by-case basis.
6.2.3 Structural Foundations on Grade
A soil modulus of 150 pounds per cubic inch is recommended for design of
stmctural slab foundations. Stmctural foundations should be designed by the
project stmctural engineer utilizing the parameters outlined below in Table 3 and
an allowable bearing pressure of 2,000 psf
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ma a B a 960151-034
Table 3
Structural Foundation Design Parameters
Expansion Index
Design Cnteria E.I. < 70
Edge Moisture Center Lift: 5.5 feet
Variation, e™ Edge Lift: 4.5 feet
Differential Swell, ¥,„
Center Lift: 1.5 inches
Differential Swell, ¥,„
Edge Lift: 0.6 inches
Modulus of Subgrade Reaction: 100 pci
Analysis of uniform mat, conventional ribbed mat and post-tensioned foundation
should be performed in accordance with the Post-Tensioning Institute procedures
(PTI, 2008).
6.3 Floor Slab Considerations
Slab on grade floors should be at least 5 inches thick and reinforced with a minimum of
No. 3 rebars at 18 inches on center each way, placed at mid height in the slab. Slabs
should be underlain by a 2-inch layer of clean sand or clean cmshed gravel. We
recommend that the architect follow the guidance of ACI 302.2R-06 for design of the
under slab moisture protection measures and development of constmction specifications.
We recommend control joints be provided across the slab at appropriate intervals as
designed by the project architect.
Prior to placement of the vapor barrier, the upper 6-inches of slab subgrade should be
moisture conditioned to a moisture content at or above the laboratory optimum.
6.4
The potential for slab cracking may be fiirther reduced by careful control of water/cement
ratios. The contractor should take the appropriate precautions during the pouring of
concrete in hot weather to minimize cracking of slabs. We recommend that a slip-sheet
(or equivalent) be utilized above the concrete slab if crack-sensitive floor coverings are to
be placed directly on the concrete slab. If heavy vehicle or equipment loading is proposed
for the slabs, greater thickness and increased reinforcing may be required.
Retaining Wall Design
-20-
960151-034
For design puiposes, the following lateral earth pressure values in Table 4 for level or
sloping backfill are recommended for walls backfilled with very low to low expansion
potential (Expansion Index less than 50).
Table 4
Static Equivalent Fluid Weight (pcf)
Conditions Level 2:1 Slope
Active 35 55
At-Rest 55 85
Passive 300
(maximum of 3 ksf)
150
(sloping down)
Retaining stmctures should be provided with a drainage system, as illustrated in
Appendix D, to prevent buildup of hydrostatic pressure behind the wall. For sliding
resistance, a friction coefficient of 0.35 may be used at the soil-concrete interface. The
lateral passive resistance can be taken into account only if it is ensured that the soil
against embedded stmctures will remain intact with time.
Retaining wall footings should have a minimum embedment of 12 inches below the
adjacent lowest grade unless deeper footings are needed for other reasons.
6.5 Earthwork
We anticipate that earthwork at the site will consist of remedial grading of the near-
surface soils; grading of the building pad and associated improvements; optimal removal
of the agricultural debris beneath the proposed hotel and pool complex; utility
constmction; subgrade preparation in pavement areas; foundation excavation; and
retaining wall constmction and backfill operations. We recommend that earthwork on the
site be performed in accordance with the following recommendations and the General
Earthwork and Grading Specifications for Rough Grading included in Appendix E. In
case of conflict, the following recommendations shall supersede those in Appendix E.
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960151-034
6.5.1 Site Preparation
If additional grading, such as fill placement, is planned on the site, the areas to
receive stmctural fill, engineered structures, or hardscape should be cleared of
surface and subsurface obstmctions, including any existing debris and
undocumented or loose fill soils, and stripped of vegetation. Removals should
extend the competent documented fill soils and/or competent formational soils.
Removed vegetation and debris should be properly disposed off site. Holes
resulting from the removal of buried obstmctions which extend below finish site
grades should be replaced with suitable compacted fill material. All areas to
receive fill and/or other surface improvements should be scarified to a minimum
depth of 12 inches, brought to above optimum moisture conditions, and
recompacted to at least 90 percent relative compaction based on ASTM Test
Method D1557. If clayey soils that are more expansive (EI>70) are encountered,
increased moisture and revised recommendations may be needed.
6.5.2 Excavations and Oversize Material
Shallow excavations of the onsite materials may generally be accomplished with
conventional heavy-duty earthwork equipment. Localized heavy ripping or
drilling may be required if cemented and concretionary lenses are encountered in
deeper excavations.
Shallow, temporary excavations, such as utility trenches with vertical sides, in the
engineered fill and formational materials should remain stable for the period
required to constmct the utility, provided they are free of adverse geologic
conditions or seeps. In accordance with OSHA requirements, excavations deeper
than 5 feet should be shored or be laid back if workers are to enter such
excavations. Temporary sloping gradients should be determined in the field by a
"competent person" as defined by OSHA. For preliminaiy planning, sloping of
surficial soils at 1:1 (horizontal to vertical) may be assumed. Excavations greater
than 20 feet in height will require an alternative sloping plan or shoring plan
prepared by a Califoraia registered civil engineer.
6.6 Proposed Swimming Pool
The swimming pool and spa should be designed by a stmctural engineer to resist the
forces lateral earth pressures soils and differential settlement of the fill. The following
items should be taken into consideration in the design and constmction of the swimming
pool and spa:
-22-
960151-034
Installation of a pressure release valve system beneath the pool bottom is also
recommended.
The pool contractor should provide a sufficient level of inspection and control to
assure that approved pool plans and specifications are implemented during
constmction.
Observation/testing should be performed by a geotechnical consultant during pool
excavation and backfill operations to verify that exposed soil conditions are
consistent with the design assumptions.
6.6.1 Pool Deck Recommendations
We recommend that the pool deck be a minimum of 5-inches thick, reinforced
with No. 3 rebars at 18 inches on center each way, and underlain by a minimum 2
inch layer of clean sand. The clean sand should be underlain by a 10-mil visqueen
moisture barrier properly lapped and sealed, which is in-tum underlain by an
additional of 2 inches of sand (minimum). The moisture barrier should be sloped
away from the pool at a minimum gradient of 2 percent. The perimeter of the
decking should be constmcted with a perimeter footing a minimum of 8 inches
wide and deep. The deck should have appropriate crack control and expansion
joints to reduce the potential for the formation of unsightly cracks as the deck
responds to the underlying expansive soils. In general, the constmction joints
should be a minimum of 5 feet on center (each way) and extend to a depth of at
least 1/3 of the concrete thickness. The joints should not cut the rebar
reinforcement. Special attention should be given to ensure that the joint between
the pool decking and pool coping is properly sealed with a flexible, watertight
caulking to prevent water infiltration. The concrete decking should be sloped to
area drains with sufficient gradient to maintain active flow, even if the deck is
subject to minor movement.
6.7 Surface Drainage and Erosion
Surface drainage should be controlled at all times. The proposed stmctures should have
appropriate drainage systems to collect mnoff Positive surface drainage should be
provided to direct surface water away from the stmcture toward suitable drainage
facilities. In general, ponding of water should be avoided adjacent to the stmcture or
pavements. Over-watering of the site should be avoided. Protective measures to mitigate
excessive site erosion during constmction should also be implemented in accordance
with the latest City of Carlsbad grading ordinances.
-23-
960151-034
6.8 Infiltration
/Due to the presence of potentially compressible agricultural debris beneath the site,
infiltration of surface waters should be avoided within the area of agricultural debris
influence and east of those limits. This office should review proposed LID solutions to
confirm they are consistent with the intent of our recommendations. Where pervious
paving is proposed, underdrains should be provided at low points of the pavement
subgrade.
6.9 Geochemical Considerations
We recommend that concrete in contact with earth materials be designed in accordance
with Section 4 of ACI 318-08 A(ACI, 2008). Due to the low resistivity of the onsite
materials, the soils are considered con-osive to buried fen'ous metals and measures to
mitigate corrosion should be incorporated in the design of those elements. Section 855 of
the Caltrans Highway Design Manual provides guidance a measure to mitigate Corrosion
for underground utilities. Measures to mitigate corrosion should be incorporated in the
design and implemented during construction as per the guidance of the project corrosion
engineer.
6.10 Vehicular Pavements
The pavement section design below is based on an assumed Traffic Index (TI), our visual
classification of the subject site soils, and laboratory testing (we have utilized a R-Value
of 11). The TI values were chosen based on our experience with similar projects. Actual
pavement recommendations should be based on R-value tests performed on bulk samples
of the soils that are exposed at the finished subgrade elevations across the site at the
completion of the grading operations. Flexible pavement sections have been evaluated in
general accordance with the Caltrans method for flexible pavement design. The
recommended flexible pavement section for this condition is given in Table 5 below:
-24-
960151-034
Table 5
Preliminary Pavement Sections
Traffic Description Assumed Traffic
Index (TI)
Asphalt Concrete
(inches)
Aggregate Base
(inches)
Auto Parking 4.5 4.0 5.0
Driveways 5.0 4.0 7.0
Flexible pavements should be constmcted in accordance with current Caltrans Standard
Specifications. Aggregate base should comply with the Caltrans Standard Specifications
of Section 26. Aggregate base should be compacted to a minimum of 95 percent relative
compaction (ASTM D 1557).
For areas subject to regular tmck loading (i.e., trash tmck apron), we recommend a fiall
depth of Portland Cement Concrete (P.C.C.) section of 7.5 inches with appropriate steel
reinforcement and crack-control joints as designed by the project stmctural engineer. We
recommend that sections be as nearly square as possible. A 3,250-psi mix that produces a
550-psi modulus of mpture should be utilized. Additional City of Carlsbad specifications
are presented on Detail GS-16 of the City of Carlsbad Engineering Standards Volume 3 -
Standard Drawing and Notes.
All pavement section materials conform to and be placed in accordance with the latest
revision of the Califomia Department of Transportation Standard Specifications
(Caltrans) and American Concrete Institute (ACI) codes. The upper 8 inches of subgrade
soil and all aggregate base should be compacted to a relative compaction of at least 95
percent (based on ASTM Test Method D1557).
If pavement areas are adjacent to heavily watered landscape areas, we recommend some
measure of moisture control be taken to prevent the subgrade soils from becoming
saturated. It is recommended that the concrete curing separating the landscaping area
from the pavement extend below the aggregate base to help seal the ends of the sections
where hea-vy landscape watering may have access to the aggregate base. Concrete swales
should be designed in roadway or parking areas subject to concentrated surface mnoff
6.11 Foundation Review
Foundation plans should be reviewed by Leighton to confirm that the recommendations
in this report are incoiporated in project plans.
-25-
960151-034
6.12 Construction Observation
The recommendations provided in this report are based on preliminary design
information, our experience during rough grading, and subsurface conditions disclosed
by widely spaced excavations. The inteipolated subsurface conditions should be checked
in the field during constmction. Construction observation of all onsite excavations and
should be performed by a representative of this office so that constmction is in
accordance with the recommendations of this report. All footing excavations should be
reviewed by this office prior to steel placement.
-26-
STORM WATER MANAGEMENT PLAN
FOR
LEGOLAND CALIFORNIA
NEW PARKING TOLL BOOTHS
December 20,2012
Wayne W. Chang, MS, PE 46548
Civil Engineering ° Hydrology ° Hydraulics ° Sedimentation
P.O. Box 9496
Rancho Santa Fe, CA 92067
(858) 692-0760
FOR REVIEW ONLY
-TABLE OF CONTENTS -
1.0 Introduction 1
1.1 Vicinity Map 1
1.2 Project Description 2
1.3 Site Map 2
1.4 Constraints and Opportunities 2
2.0 Water Quality Environment 2
2.1 Beneficial Uses 2
2.1.1 Inland S urface Waters 3
2.1.2 Groundwater 3
3.0 Pollutants and Conditions of Concem : 4
3.1 Pollutants Irom Project Area 4
3.2 Pollutants of Concern in Receiving Waters 5
4.0 Permanent Storm Water Best Management Practices 5
4.1 Standard Site Design BMPs 5
4.2 Source Control BMPs 6
4.3 Low Impact Development Site Design BMPs 8
4.4 Treatment Control BMPs 8
4.5 Hydromodification 8
5.0 Storm Water BMP Maintenance 9
6.0 Summary/Conclusions 10
7.0 Certification 10
Storm Water Standards Questionnaire, E-34
Site Map (Grading Plan)
APPENDIX
A. Low Impact Development and Hydromodification Analyses
FOR REVIEW ONLY
1.0 INTRODUCTION
This Storm Water Management Plan (SWMP) addresses water quality requirements
associated with LEGOLAND California's new toll booth project in the city of Carlsbad. This
SWMP follows the criteria outlined in the City of Carlsbad's January 14, 2011, Standard
Urban Storm Water Management Plan (SUSMP).
According to the City's Storm Water Standards Questionnaire E-34 (attached following this
report text), the development is in the "Streets, roads, highways, and freeways" priority
project category and is also considered a significant redevelopment project. The SUSMP
outlines the SWMP objectives, which are to identify site opportunities and constraints,
identify pollutants and conditions of concem, follow low impact development design
objectives, describe best management practices (BMPs), and outline maintenance
requirements. BMPs will be utilized to the maximum extent practicable to provide a long-
term solution for addressing runoff water quality.
1.1 Vicmity Map
CITY OF OCEANSIDE
HIGHWAYj,^,^
NOT TO
SCALE
CITY OF VISTA
CITY OF
SAN MARCOS
PACIFIC \\\
OCEAN
CITY OF ENCINITAS
1.2 Project Description
LEGOLAND Califomia proposes to install two new toll booths at the existing entrance to the
park. The new toll booths will be just southwest of the existing toll booths and along
Legoland Drive. The project will require widening of Legoland Drive to accommodate the
toll booths and to provide additional travel lanes. The westerly edge of Legoland Drive will
be widened by about 40 feet at the maximum location. The widening will encroach into the
landscape area between Legoland Drive and Armada Drive requiring regrading and
replanting of the landscape area.
Under pre-project conditions, the project vicinity contains Legoland Drive, three existing toll
booths, and adjacent landscaping. Surface runoff from this area generally flows onto
Legoland Drive and is conveyed in a southerly direction along the street. The runoff
ultimately enters curb inlets within the site. The curb inlets connect to a storm drain system
that discharges into a large detention basin along the southerly end of the park.
Under post-project conditions, the on-site flow patterns will generally be maintained. Runoff
will continue to be directed onto Legoland Drive and ultimately enter the existing detention
basin. However, due to current water quality regulations, a bioretention basin will be
constructed and storm drains will be used to direct the 10-year and lower flows to the basin.
1.3 Site Map
A Site Map is included following this report text.
1.4 Constraints and Opportunities
As shown on the site map, the development will occur within and alongside the existing
access road to the park. Some of the adjacent landscaping will need to be removed to
accommodate the new toll booths and associated drive lanes. The pre-project drainage
pattems are generally being maintained by the project. A review of the existing site revealed
that the required bioretention basin could either be constructed along the westerly edge of
Legoland Drive or within a landscape area further south along the easterly edge of Legoland
Drive. It was determined that the second location was preferable because the area associated
with the first location was confined due to the roadway widening and the adjacent Armada
Drive immediately to the west.
2.0 WATER QUALITY ENVIRONMENT
2.1 Beneficial Uses
The beneficial uses for the hydrologic unit (see Section 3.1) are included in Tables 1 and 2.
These tables were obtained from the Water Quality Control Plan for the San Diego Basin (9)
compiled on August 28, 2012. The following contains definitions ofthe beneficial uses in the
tables:
MUN - Municipal and Domestic Supply: Includes uses of water for community,
military, or individual water supply systems including, but not limited to, drinking
water supply.
RECl - Contact Recreation: Includes uses of water for recreational activities
involving body contact with water, where ingestion of water is reasonably possible.
These uses include, but are not limited to, swimming, wading, water-skiing, skin and
SCUBA diving, surfing, white water activities, fishing, or use of natural hot springs.
REC2 - Non-Contact Recreation: Includes the uses of water for recreational
involving proximity to water, but not normally involving body contact with water,
where ingestion of water is reasonably possible. These uses include, but are not
limited to, picnicking, sunbathing, hiking, camping, boating, tide pool and marine life
study, hunting, sightseeing, or aesthetic enjoyment in conjunction with the above
activities.
WARM - Warm Freshwater Habitat: Includes uses of water that support warm
water ecosystems including, but not limited to, preservation or enhancement of
aquatic habitats, vegetation, fish or wildlife, including invertebrates.
WILD - Wildlife Habitat: Includes uses of water that support terrestrial ecosystems
including, but not limited to, preservation and enhancement of terrestrial habitats,
vegetation, wildlife, (e.g., mammals, birds, reptiles, amphibians, invertebrates), or
wildlife water and food sources.
2.1.1 Inland Surface Waters
Inland surface waters for the Encinas Hydrologic Area (see Section 3.1) have the beneficial
uses shown in Table 1:
Table 1. Beneficial Uses for Inland Surface Waters
Hydrologic
Unit p
Code . c 00
o o o O "o o OH
s < a; O DH s U a;
904.40 -1-0 • • •
+ Exempted by the Regional Board from the municipal used designation.
• Existing Beneficial Use
o Potential Beneficial Use
2.1.2 Groundwater
Groundwater beneficial uses for the Encinas Hydrologic Area are shown in Table 2:
Table 2. Beneficial Uses for Groundwater
Hydrologic
Unit
Code c o
< o
u
a. 904.40 -1-
+ Excepted from MUN
3.0 POLLUTANTS AND CONDITIONS OF CONCERN
3.1 Pollutants from Project Area
The project is located within the Encinas Hydrologic Area (904.40), which is within the
Carlsbad Hydrologic Unit (904.00). The total drainage area of the hydrologic unit is
approximately 210 square miles. Runoff from portions of the hydrologic area ultimately
drains to the Pacific Ocean, which is west of the project site. All of the project rimoff will
ultimately enter the Pacific Ocean. The project site represents less than one percent of the
overall watershed.
The following table lists pollutants of concem that are anticipated or can potentially exist at
proposed priority development project sites. The pollutants are from the city of Carlsbad's
SUSMP. The project falls within the detached residential development and streets, highways
& freeways priority project categories (highlighted yellow in the table). All of the listed
pollutants are either anticipated or can potentially exist at the developed site.
Table 3. Priority Project Pollutants
Priority
Project
Categories
Sediments Nutrients Heavy
Metals
Organic
Compounds
Trash
&
Debris
Oxygen
Demanding
Substances
Oil
&
Grease
Bacteria
&
Viruses
Pesticides
Detached
Residential
Development
X X X X X X X
Attached
Residential
Development
X X X pd) p(2) P X
Commercial
Development
> one acre
pd) pd) X p(2) X p(5) X p(3) p(5)
Heavy
Industry X X X X X X
Automotive
Repair Shops X X('')(5) X X
Restaurants X X X X pd)
Hillside
Development
>5,000 ft'
X X X X X X
Parking Lots pd) pd) X X pd) X pd)
Retail
Gasohne
Outlets
X X X X X
Streets,
Highways &
Freeways
X p(i) X X p(5) X X p(l)
X = Anticipated
P = Potential
(1) A potential pollutant if landscaping exists on-site
(2) A potential pollutant if the project includes uncovered parking areas
(3) A potential pollutant if land use involves food or animal waste products
(4) Including petroleum hydrocarbons
(5) Including solvents
3.2 Pollutants of Concern in Receiving Waters
The receiving water for the site is Encinas Creek just to the south, which then flows into the
Pacific Ocean. According to the 2008 303(d) list approved by the State Water Resources
Control Board (and by the US EPA in November 2010), neither Encinas Creek nor the
Pacific Ocean near Encinas Creek is 303(d) listed. Based on this information, the project
does not generate pollutants of concem in the receiving waters.
4.0 PERMANENT STORM WATER BEST MANAGEMENT PRACTICES
To address water quality for the project, best management practices (BMPs) will be
implemented. The following discusses the Standard Site Design, Source Control, and Low
Impact Development design BMPs for the project.
4.1 Standard Site Design BMPs
The City of Carlsbad's standard objectives are required for all projects. The project will
accomplish these goals through the following standard site design BMPs, which are from the
Carisbad SUSMP:
Standard Stormwater Requirements
Minimize Impervious Surfaces. The project will include pervious surfaces through
landscaping within the development area. The paved roadway surfaces have been minimized
to only what is needed for the additional toll booths.
Disconnect Discharges. The proposed pedestrian walkway shall be allowed to drain to
existing landscaping, where feasible. The pavement runoff will be directed to a bioretention
basin.
Conserve Natural Areas. The existing landscaping along the project area will be preserved to
the extent possible. There are no native areas in the vicinity of the site.
Stenciling Inlets and Signage. The catch basins constructed by the project will be stenciled
with prohibitive language such as "No Dumping -1 live downstream" or approved similar.
Landscape Design. A landscape plan will be prepared that uses drought-tolerant species in
accordance with the City's landscape manual. Existing trees, shmbs, and groundcover will be
preserved beyond the majority of the mass-graded pad in order to maximize canopy
interception and promote water conservation. The project will only use water as needed to
support the landscaping.
Water Efficient Irrigation. The irrigation systems will be designed to each landscaped areas
water requirements to avoid over irrigation.
Protect Slopes And Channels. The grading design does not include large slopes or any
channels. The design will prevent mnoff from flowing uncontrolled over the tops of
manufactured slopes. The proposed sloping ground will be landscaped. Riprap energy
dissipaters will be used at storm drain outfalls.
Vegetate slopes with native or drought tolerant vegetation. There are no native plants in the
vicinity. Drought tolerant vegetation will be used to the extent feasible.
Trash Receptacles. The parking lot adjacent to the project site includes trash receptacles.
Material Storage Areas. The project does not propose material storage areas.
4.2 Source Control BMPs
Source control BMPs will consist of measures to prevent polluted mnoff The following
addresses the source control BMPs from Appendix 1 of the Carlsbad SUSMP:
Table 4. Pollutant Sources and Source Control Checldist
Potential Source
of Runoff Pollutants
Permanent Source
Control BMPs
Operational Source
Control BMPs
On-site storm drain
inlets
Mark all inlets with "No
Dumping -1 live downstream"
Maintain and periodically
repaint inlet markings
Provide stormwater pollution
information to owners, lessees,
and operators (Fact sheet SC-
44 from the CASQA
Stormwater Quality Handbook
at -www.cabmphandbooks.com)
Owner/lessee agreements shall
state "Tenant shall not allow
anyone to discharge anything to
storm drains or to store or
deposit materials so as to create
a potential discharge to storm
drains.
Landscape/Outdoor Final landscape plans will Maintain landscaping using
Pesticide Use accomplish all of the
following.
• Preserve existing trees,
shmbs, and ground cover to
the maximum extent possible.
• Design landscaping to
minimize irrigation and
runoff, to promote surface
infiltration where
appropriate, and to minimize
the use of fertilizers and
pesticides that can contribute
to stormwater pollution.
• Where landscaped areas can
retain or detain stormwater,
specify plants that are
tolerant of saturated soil
conditions.
• Consider using pest-resistant
plants, especially adjacent to
hardscape.
• To ensure successful
establishment, select plants
appropriate to site soils,
slopes, climate, sun, wind,
rain, land use, air movement,
ecological consistency, and
plant interactions
minimum or no pesticides.
See applicable operational BMPs
in Fact Sheet SC-41, "Building and
Grounds Maintenance," and TC-
30, "Vegetated Swale," in the
CASQA Stormwater Quality
Handbooks at
www.cabmphandbooks.com
Integrated Pest Management (e.g.,
the EPA's Citizen's Guide to Pest
Control and Pesticide Safety)
information shall be provided to
owners, lessees, and operators.
Plazas, sidewalks,
and parking lots.
The proposed walkway shall be
swept regularly to prevent the
accumulation of litter and debris.
Debris from pressure washing shall
be collected to prevent entry into
the storm drain system. Wash
water containing any cleaning
agent or degreaser shall be
collected and discharged to the
sanitary sewer and not discharged
to a storm drain.
4.3 Low Impact Development Site Design BMPs
Low Impact Development (LID) BMPs must be incorporated into the site design to meet the
City of Carlsbad's January 14, 2011 SUSMP requirements. The integrated LID outlines four
strategies:
1. Optimize the site layout by preserving natural drainage features and designing
buildings and circulation to minimize the amount of roofs and paving.
2. Use pervious surfaces such as turf, gravel, or pervious pavement—or use surfaces that
retain rainfall. All drainage from these surfaces is considered to be "self-retained".
3. Disperse mnoff from impervious surfaces on to adjacent pervious surfaces (e.g.,
direct a roof downspout to disperse runoff onto a lawn).
4. Drain impervious surfaces to engineered Integrated Management Practices (IMPs),
such as bioretention facilities. IMPs infiltrate mnoff to groundwater and/or percolate
mnoff through engineered soil and allow it to drain away slowly.
The project design is in compliance with these strategies. The site layout has been designed
to preserve the landscaping areas beyond the proposed pavement and toll booths. Shared
drive aisles are being used to minimize the pavement area.
Water quality runoff from the project area will ultimately enter a bioretention basin.
Bioretention basins provide high to medium removal effectiveness for the pollutants
generated by the project, which are listed in Table 3. Sizing is included in Appendix A of this
report using the County of San Diego's BMP Sizing Calculator.
4.4 Treatment Control BMPs
Treatment control BMPs were selected to treat the project pollutants of concern identified in
Table 3. A bioretention basin will be used because it has a medium to high pollutant removal
efficiency for the project's pollutants of concem. For treatment control only, a bioretention
basin's surface area must be at least 4 percent of the total area determined from the Drainage
Management Areas. For the project, the bioretention basin will also provide
hydromodification flow control, so will be larger than the 4 percent. The sizing is discussed
in the next section.
4.5 Hydromodification
The January 14, 2011 SUSMP requires hydromodification (flow control) for priority
development projects to ensure that post-development peak flows do not exceed pre-
development peak flows. The toll booth project is a priority development project and must
meet the hydromodification requirement. This can be accomplished by sizing the proposed
bioretention facility using the criteria in the Coimty of San Diego's SUSMP.
Data entry for the hydromodification analysis includes the lower flow threshold, soil group,
slope, and rain gage. A lower flow threshold of 0.1 Q2 was used because a downstream
channel screening assessment has not been performed. The site is within the Oceanside
rainfall basin and contains soil groups C and D. The average slope along the mass-graded pad
is in the range of 5 to 10 percent, which is within the "moderate" category. The drainage
management areas were divided into existing paving, proposed paving on existing paving,
proposed paving on existing landscaping, and proposed landscaping. Appendix A contains
the DMA exhibit and Calculator results. The bioretention basin will not need to contain an
impervious liner according to the geotechnical engineer, Leighton. The Calculator provides
the surface area sizing, surface volume sizing, and subsurface volume sizing (1,228 cubic
feet; 1,023 square feet, and 737 square feet, respectively). The plans are based on the
Calculator results.
5.0 STORM WATER BMP MAINTENANCE
The developer, LEGOLAND Califomia, will be responsible for funding and implementing
the operations and maintenance of the project BMPs. Provisions will be made to transfer
operations and maintenance to the new owner in the event of a change in ownership.
Bioretention basin
The drainage outlet from the basin shall be inspected monthly and after large storm events.
Debris, sediment, and other obstmctions shall be removed immediately from the outlet. The
habitat shall also be inspected annually and replanted as needed to maintain an adequate
cover.
Landscaping
Maintenance will be performed by landscaping personnel. The vegetation will be maintained
and inspected on a monthly or more frequent basis by landscape maintenance staff and will
be replaced or replanted, as necessary, to maintain a dense, healthy cover. The vegetation
will also be inspected after major storm events. Maintenance shall include periodic mowing,
weed control, irrigation, reseeding/replanting of bare areas, and clearing of debris. The
private drainage system will shall be kept clear of debris and inspect prior to and during the
rainy season to ensure it is free-flowing.
Efficient Irrigation
The landscaping personnel shall inspect and maintain the irrigation system on a regular basis.
This will occur during the routine maintenance activities. All valves, heads, shutoff devices,
lines, etc. shall be kept in a properly fiinctioning condition. Any defective parts shall be
replaced immediately. The irrigation system shall be adjusted to prevent excessive runoff
from landscape areas. The irrigation schedule shall be adjusted based on seasonal needs.
Inlet Stenciling
Any stenciling shall be inspected at the beginning and end of each rainy season and repaired
or replaced, as needed.
Hazardous Wastes
Suspected hazardous wastes will be analyzed to determine disposal options. Hazardous
materials are not expected to be generated on-site; however, if discovered, hazardous
materials will be handled and disposed of according to local, state, and federal regulations. A
solid or liquid waste is considered a hazardous waste if it exceeds the criteria listed in the
California Code of Federal Regulations, Title 22, Article 11 (State of Califomia, 1985).
6.0 SUMMARY/CONCLUSIONS
This final SWMP has been prepared in accordance with the City of Carlsbad's January 14,
2011, Standard Urban Storm Water Management Plan, and has evaluated and addressed
potential pollutants associated with the Muroya project and its effects on water quality. This
SWMP has been based on the final engineering plans. A summary of the facts and findings
associated with the project and the measures addressed by this SWMP are as follows:
• The beneficial uses for the receiving waters have been identified. BMPs will be used
to protect the beneficial uses as outlined by the SUSMP.
• The project will not significantly alter drainage patterns and will meet
hydromodification requirements.
• Permanent BMPs will be incorporated into the project design in the form of site
design, source control, and LID treatment control.
• The proposed BMPs address mitigation measures to protect water quality and
beneficial uses to the maximum extent practicable.
7.0 CERTIFICATION
The selection, sizing, and preliminary design of stormwater treatment and other control
measures in this plan meet the requirements of Regional Water Quality Control Board Order
R9-2007-0001 and subsequent amendments.
December 20, 2012
Wayne W. Chang, RCE 46548 Date
10
^ STORMWATER „ , .
QTAKinAPHQ Development Services
oTANDARDo Engineering Department
^ CITY OF OIJESTIONNAIRF 1635 Faraday Avenue
CARLSBAD E-34 760-602-2750
www.carlsbadca.gov
INSTRUCTIONS:
To address post-development pollutants that may be generated from development projects, the City requires that new
development and significant redevelopment pnority projects incorporate Permanent Storm Water Best Management
Practices (BMP's) into the project design per the City's Standard Urban Stormwater Management Plan (SUSMP).
Initially this questionnaire must be completed by the applicant in advance of submitting for a development application
(subdivision, discretionary permits and/or construction permits). The results ofthe questionnaire determine the level of
storm water standards that must be applied to a proposed development or redevelopment project. Depending on the
outcome, your project will either be subject to 'Standard Stormwater Requirements' or be subject additional cnteria
called 'Priority Development Project Requirements'. Many aspects of project site design are dependent upon the
storm water standards applied to a project
Applicant responses to the questionnaire represent an initial assessment of the proposed project conditions and
impacts. City staff has responsibility for making the fmal assessment after submission of the development application.
If staff determines that the questionnaire was incorrectly filled out and is subject to more stringent storm water
standards than initially assessed by the applicant, this will result in the return of the development application as
incomplete In this case, please make the changes to the questionnaire and resubmit to the City
If applicants are unsure about the meaning of a question or need help in determining how to respond to one or more of
the questions, they are advised to seek assistance from Land Development Engineenng staff.
A separate completed and signed questionnaire must be submitted for each new development application submission
Only one completed and signed questionnaire is required when multiple development applications for the same project
are submitted concurrently In addition to this questionnaire, applicants for construction permits must also complete,
sign and submit a Project Threat Assessment Form to address construction aspects of the project
Please answer the questions below, follow the instructions and sign the form at the end.
1. Is your project a significant redevelopment?
DEFINITION:
Significant redevelopment is defined as the creation, addition or replacement of at least 5,000 square feet of
impervious surface on an already existing developed site.
Significant redevelopment includes, but is not limited to: the expansion of a building footprint; addition to or
replacement of a structure; structural development including an increase in gross floor area and/or exterior
construction remodeling; replacement of an impervious surface that is not part of a routine maintenance activity; and
land disturbing activities related with structural or impervious surfaces. Replacement of impervious surfaces includes
any activity that is not part of a routine maintenance activity where impervious materiai(s) are removed, exposing
underlying soii during construction.
If your project IS considered significant redevelopment, then please s/c/p Section 1 and proceed with Section 2
If your project IS NOT considered significant redevelopment, then please proceed to Section 1.
E-34 Pagel of3 REV3/23/10
CITY OF
CARLSBAD
STORM WATER
STANDARDS
QUESTIONNAIRE
E-34
Development Services
Engineering Department
1635 Faraday Avenue
760-602-2750
www.carlsbadca.gov
SECTION 1 NEW DEVELOPMENT
PRIORITY PROJECT TYPE
Does you project meet one or more of the following criteria: YES NO
1 Housina subdivisions of 10 or more dwellina units. Examples sinqle family homes, multi-family homes,
condominium and apartments X
2 Commercial-areater than 1-acre Anv develooment other than heavv industrv or residential Examples hospitals,
laboratones and other medical facilities, educational institutions, recreational facilities, municipal facilities, commercial
nursenes, multi-apartment buildings, car wash facilities, mini-malls and other business complexes, shopping malls,
hotels, office buildings, public warehouses, automotive dealerships, airfields, and other light industnal facilities
X
3 Heaw Industrial / Industrv areater than 1 acre. Examoles manufactunng plants, food processinq plants, metal
working facilities, printing plants, and fleet storage areas (bus, truck, etc) X
4 Automotive repair shoo A facility cateqorized in anv one of Standard Industnal Classification (SIC) codes 5013,
5014, 5541, 7532-7534, and 7536-7539 X
5 Resfaoranfs Anv facility that sells prepared foods and dnnks for consumption, includina stationarv lunch counters
and refreshment stands selling prepared foods and dnnks for immediate consumption (SIC code 5812), where the
land area for development is greater than 5,000 square feet Restaurants where land development is less than 5,000
square feet shall meet all SUSMP requirements except for structural treatment BMP and numenc sizing critena
requirements and hydromodification requirements
X
6 Hillside development. Anv develooment that creates 5.000 souare feet of impervious surface and is located in an
area with known erosive soil conditions, where the development will grade on any natural slope that is twenty-five
percent (25%) or greater
X
7 Environmentallv Sensitive Area (ESA]\ All development located wrthin or directly adiacent^ to or discharqina
directly^ to an ESA (where discharges from the development or redevelopment will enter receiving waters within the
ESA), which either creates 2,500 square feet of impervious surface on a proposed project site or increases the area
of imperviousness of a proposed project site fo 10% or more of its naturally occurnng condition
X
8 Parkina lot Area of 5,000 sauare feet or more, or wrth 15 or more parkinq spaces, and potentially exposed to urban
runoff X
9 Streets, roads, hiahwavs. and freewavs. Any oaved surface that is 5,000 sauare feet or qreater used for the
transportation of automobiles, trucks, motorcycles, and other vehicles X
10 RetaiV Gasoline Outlets Servinq more than 100 vehicles per day and qreater than 5,000 sauare feet X
11 Coastal Develooment Zone Any proiect located within 200 feet of the Pacific Ocean and (1) creates more than
2500 square feet of impermeable surface or (2) increases impermeable surface on property by more than 10% X
12 More than 1-acre of disturbance Proiect results in the disturbance of more than 1-acre or more of land and is
considered a Pollutant-generating Development Project" X
1 Environmentally Sensitive Areas include but are not limited to all Clean Water Act Section 303(d) impaired water bodies, areas designated as Areas of Special
Biological Significance by the State Water Resources Control Board (Water Quality Control Plan for the San Diego Basin (1994) and amendments), water bodies
designated with the RARE beneficial use by the State Water Resources Control Board (Water Quality Control Plan for the San Oiego Basin (1994) and amendments),
areas designated as preserves or their equivalent under the Multi Species Conservation Program within the Cities and County of San Diego, and any other equivalent
environmentally sensitive areas which have been identified by the Copermittees
2 "Directly adjacent" means situated within 200 feet of the Environmentally Sensitive Area
3 "Discharging directly to" means outflow from a drainage conveyance system that is composed entirely of flows from the subject development or redevelopment site, and
not commingled with flow from adjacent lands
4 Pollutant-generating Development Projects are those projects that generate pollutants at levels greater than background levels In general, these include all projects
that contnbute to an exceedance to an impaired water body or which create new impervious surfaces greater than 5000 square feet and/or introduce new landscaping
areas that require routine use of fertilizers and pesticides In most cases linear pathway projects that are for infrequent vehicle use, such as emergency or maintenance
access, or for pedestrian or bicycle use, are not considered Pollutant-generating Development Projects if they are built with pervious surfaces or if they sheet flow to
surrounding pervious surfaces
Section 1 Results:
If you answered YES to ANY of the questions above your project is subject to Priority Development Project requirements Please check the
"meets PRIORITY DEVELOPMENT PROJECT requirements" box m Section 3. A Storm Water Management Plan, prepared in accordance with City
Storm Water Standards, must be submitted at time of application
If you answered NO to ALL of the questions above, then your project is subject to Standard Stormwater Requirements Please check the "does
not meet PDP requirements" box in Section 3
E-34 Page 2 of 3 REV 3/23/10
^ CITY OF
CARLSBAD
STORM WATER
STANDARDS
QUESTIONNAIRE
E-34
Development Services
Engineering Department
1635 Faraday Avenue
760-602-2750
www.carlsbadca.gov
SECTION 2 SIGNIFICANT REDEVELOPMENT
Complete the questions below regarding your redevelopment project: YES NO
1 Project results in the disturbance of more than 1 -acre or more of land and is considered a Pollutant-generating
Development Project (see definrtion in Section 1) X
If you answered NO, please proceed to question 2
If you answered YES, then you ARE a significant redevelopment and you ARE subject to PRIORITY DEVELOPMENT PROJECT
requirements. Please check the "meets PRIORITY DEVELOPMENT PROJECT requirements" box in Section 3 below.
2 Is the project redeveloping an existing pnonty project type*? (Pnonty projects are defined in Section 1) X
If you answered YES, please proceed to question 3
If you answered NO, then you ARE NOT a significant redevelopment and your project is subject to STANDARD STORMWATER
REQUIREMENTS. Please check the "does not meet PDP requirements" box in Section 3 below
3 Is the project solely limited to just one of the following X
a Trenching and resurfacing associated with utility work"? X
b Resurfacing and reconfigunng existing surface parking lots'? X
c New sidewalk construction, pedestnan ramps, or bike lane on public and/or private existing roads'? X
d Replacement of existing damaged pavemenf? X
If you answered NO to ALL of the questions, then proceed to question 4
If you answered YES to ANY of the questions then you ARE NOT a significant redevelopment and your project is subject to Standard
Stormwater Requirements Please check the "does not meet PDP requirements" box in Section 3 below.
4 Will your redevelopment project create, replace, or add at least 5,000 square feet of impervious surfaces on an existing
development or, be located within 200 feet ofthe Pacific Ocean and (l)create more than 2500 square feet of
impermeable surface or (2) increases impermeable surface on the property by more than 10%'?
X
If you answered YES, you ARE a significant redevelopment, and you ARE subject to PRIORITY DEVELOPMENT PROJECT requirements
Please check the "meets PRIORITY DEVELOPMENT PROJECT requirements" box in Section 3 below.
If you answered NO, then you ARE NOT a significant redevelopment and your project is subject to STANDARD STORMWATER
REQUIREMENTS. Please check the "does not meet PDP requirements" box in Section 3 below.
SECTION 3
Questionnaire Results:
IS My project meets PRIORITY DEVELOPMENT PROJECT (PDP) requirements and must comply with additional stormwater cntena
per the SUSMP and must prepare a Storm Water Management Plan for submittal at time of application.
• My project does not meet PDP requirements and must only comply with STANDARD STORMWATER REQUIREMENTS per the
SUSMP
Applicant Information and Signature Box This Box for City Use Only
Adctrsss
1 Legoland Dr., Carlsbad, CA
92008
Assessor's Parcel Number(s)
211-100-09
Applicant Name
Mr. Christopher Romero
1 A
Applicant Title
Director of Maintenance
Applidailt Sign^ile Date
City Concurrence YES NO
By
Project ID
E-34 Page 3 of 3 REV 3/23/10
120.0 fl
3 WDE SPIU.WAY WTH 2 1 SOE
SLOPES W/ NO 3 BACKING
RIPRAP PAD (T=0 6) OVER Ml'
GRAVa RLTER BLANKET (T=l 0 )
SPILLWAY DETAIL
PROPOSED
• 2+"!(24" GRATED
CATCH BASIN
INSTALL CONCRETE
LUG PER SDRSD D-63
///
/•J- 6" PVC, 11 0 LF O 89 5!5
11
EXISTING 60" RCP
STORM DRAIN
0 5 10
TOLL BOOTH ISLANDS
GENERAL NOTES
1 CONTRACTOR TO VERIFY LOCATION OF EXISTING UTIUTIES WITH USA
Z CONTRACTOR TO COORDINATE WTH LEGOLAND ON REMOVAL AND/OR
RELOCATION OF EXISTING SIGNS UGHTS. GATES FENCES ETC MTHIN
FOOTPRINT OF WORK AREA.
3 LANDSCAPING AND IRRIGATION TO BE INSTALLED PER LANDSCAPE
PLANS. EXISTING TREES AND PLANTS TO BE RELOCATED ANO/OR
REMOVED PER LANDSCAPE PLANS.
4 BIORETENTION BASIN TO BE PLANTED PER LANDSCAPE PLANS BASIN
SHAU. CONTAIN A 1 5 THICK UYER OF GROWING MEDIUM OVER A 2.5
THICK MINIMUM LAYER OF CRAVa (40% VOIDS RATIO) GRAVa SHALL
BE 1 5 THICK MINIMUM ABOVE INVERT OF PERFORATED PIPE AND 1
THICK BELOW INVERT BOTTOM OF BIOREIENTION BASN BaOW GRAVtl
TO SLOPE AT 1% TOWARDS PERFORATED PIPE.
5 PAVEMENT STRIPING TO BE INSTALLED PER SITE PLAN
CONSTRUCTION NOTES
LEGOLAND
CALlFORfVIA
1 LEGOLAND DRIVE
CARLSBAD CA 92008
(760)918-5300
Prepared by
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ACCESS RAMP SCALE 1 =10 I
®
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JOIN EXISTING CURB AND GUTTER
TRANSITION FROM 6" TYPE G-2 C4G TD
TYPE G-4A ROLLED CURB PER G-4B
J' WIDE SPiaWAY WITH 2.1 SIDE SLOPES W/ NO 3
BACKING RIPRAP PAO (T=0 6) OVER Mt GRAVa
FILTER BLANKET (T=1 0) SEE SPILLWAY DETAIL
12" PVC RISER INSTAU. 3 CF CONCRETE ANCHOR
AROUND BASE OF BSER 119 53 TDP 115 70 IE
PRELIMINARY
ABBREVIATIONS
STORM DRAIN DETAIL
BC BESN CURVE / BOTTOM OF CURB PCC POINT OF COMPOUND CURVATURE
EC END CURVE PVC PaYVINYL CHLORIDE
EP EDffi OF PAVEMENT RCP REINFORCED CONCRETE PIPE
a aOW UNE SF SQUARE FEn
FS FINISHED SURFACE TC TOP OF CURB
IE INVERT ElEVATION TF TOP OF FOUNDATION
U^ UNEAR FEET TG TDP OF GRATE
Ta= OF BASIN -
PRECISE GRADING PLAN SCALE 1 =20 I
CONSTRUCTION DRAWINGS
NEW PARKING TOLL
BOOTHS
PRECISE
GRADING PLAN
Scale as shown
DEC 21,2012
Sheet Number
C-1
APPENDIXA
LOW IMPACT DEVELOPMENT
AND HYDROMODIFICATION ANALYSES
SUMMARY
The SUSMP requires that Drainage Management Areas (DMA) be delineated for various surface
types. DMAs were determined for existing paving, proposed paving on existing paving,
proposed paving on existing landscaping, and proposed landscaping. These were subdivided into
soil groups C and D, and are shown on the DMA Exhibit in this appendix. The DMA
information was entered into the County's BMP Sizing Calculator. The Calculator results are
attached (Plan Area = 1,228 feet; Volume 1 = 1,023 sf; and Volume 2 = 737 sf) and were the
basis for the bioretention basin design.
Project Summary
Project Name Legoland New Parking Toll Booths
Project Applicant Legoland California
Jurisdiction City of Carlsbad
Parcel (APN) 211-100-09
Hydrologic Unit Carlsbad
Compliance Basin Summary
Basin Name: Unnamed On-site Area
Receiving Water Bioretention Basm
Rainfall Basin Oceanside
Mean Annual Precipitation (inclies) 133
Project Basin Area (acres). 0 95
\Alaterslied Area (acres)' 0 00
SCCWRP Lateral Channel Susceptiblity (H, M, L).
SCCWRP Vertiflcal Channel Susceptiblity (H, M, L):
Overall Channel Susceptibility (H, M, L)' HIGH
Lower Flow Threshold (% of 2-Year Flow): 0 1
Drainage Management Area Summary
ID Type BMP ID Description Area (ac) Pre-Project Cover Post Surface Type Drainage Soli Slope
23132 Drains to LID BMP 1 DMA 1 0 22 Impervious (Pre) Concrete or asphalt Type C (slow infiltration) Moderate (5-10%)
23133 Drains to LID BMP 1 DMA 2 0 02 Impervious (Pre) Concrete or asphalt Type C (slow infiltration) Moderate (5-10%)
23134 Drams to LID BMP 1 DMA 3 0 17 Impervious (Pre) Concrete or asphalt Type D (high runoff - clay
SOI Moderate (5 -10%)
23135 Drains to LID BMP 1 DMA 4 0 08 Impervious (Pre) Concrete or asphalt Type D (high runoff - clay
SOI Moderate (5 -10%)
23136 Drains to LID BMP 1 DMA 5 0 19 Pervious (Pre) Concrete or asphalt Type D (high runoff - clay
SOI Moderate (5-10%)
23137 Drains to LID BMP 1 DMA 6 0 27 Pervious (Pre) Landscaping Type D (high runoff - clay
SOI Moderate (5-10%)
LID Facility Summary
U 1 J ./•T ii,;i_mr„i 1 i/cii4..,'-r n^.vm i.r» O..:J 1 T o/Ti-7 o.i-; j c<rA/-i AAAI O._;. 1 /a A A 1 O
ix^^^^i ixtjj^ip ^j^P ^^^1 ^^^1 ^^^1 ^^^1 ^^^B |^9B BB9 ^^^S ^^^9 ^^^B ^^^9
BMP ID Type Description Plan Area (sqft) Volume 1(cft) Volume 2(cft) Orifice Flow (cfs) Orifice Size (inch)
BMP 1 Bioretention Bioretention Basin 1228 1023 737 0 037 1 00
-i^-./T^ ii-:i_ n\ r_ -1 ]/ci;4.„T- iu:i/T> tr> ii r).-:4 1 oo/ri T o.i-; J—c<r-\/-' AAAI O._;— IO/'^A/OAI'^
NOTE;
THIS EXHIBIT SHOWS THE DRAINAGE
MANAGEMENT AREAS TRIBUTARY TO
THE PROPOSED BIORETENTION BASIN.
EXISTING PAVEMENT
PROPOSED PAVEMENT ON EXISTING PAVEMENT
PROPOSED PAVEMENT ON EXISTING LANDSCAPING
PROPOSED LANDSCAPING ON EXISTING LANDSCAPING
® HYDROLOGIC SOIL GROUP
LEGOLAND TOLL BOOTHS
DRAINAGE MANAGEMENT AREAS
STORM DRAIN
TO
BIORETENTION
BASIN
DRAINAGE REPORT
FOR
LEGOLAND CALIFORNIA
NEW PARKING TOLL BOOTHS
December 20, 2012
Wayne W. Chang, MS, PE 46548
Chang )DQ§a]LDaoi]§
Civil Engineenng ° Hydrology ° Hydraulics - Sedimentation
P.O. Box 9496
Rancho Santa Fe, CA 92067
(858) 692-0760
FOR REVIEW ONLY
TABLE OF CONTENTS
Introduction
Drainage Analyses.
Conclusion
.1
.2
.3
APPENDICES
A. Rational Method Analyses and Supporting Data
B. Hydraulic Analyses
FOR REVIEW ONLY
INTRODUCTION
LEGOLAND Califomia proposes to install two new toll booths at the existing entrance to the
park. The new toll booths will be just southwest of the existing toll booths and along Legoland
Drive. The project will require widening of Legoland Drive to accommodate the toll booths and
to provide additional travel lanes. The westerly edge of Legoland Drive will be widened by about
40 feet at the maximum location. The widening will encroach into the landscape area between
Legoland Drive and Armada Drive requiring regrading and replanting of the landscape area.
SITE
•\\ OP
Vicinity Map
The project will be a Priority Development Project, so a bioretention basin will be constructed to
meet treatment control and hydromodification requirements. Private drainage facilities will be
construc^ted as part of the water quality design. A catch basin will be installed along the westerly
curb and gutter near the upstream end of the project footprint to intercept the tributary 10-year
flows before they reach the project footprint. This is being done to reduce the amount of
commingling of flows. Since hydromodification only applies up to the 10-year storm event, this
interceptor system was designed for this event. A second catch basin will be installed along the
curb and gutter near the downstream end of the project footprint to capture and convey the 10-
year project flows to the bioretention basin near the south end of the project area. Any flows
greater than the 10-year will ultimately be captured and conveyed by the existing on-site
drainage facilities.
This report contains drainage analyses for the proposed project. The analyses were performed for
both the 10- and 100-year events. They were used to size the proposed private drainage facilities
that are part of the project.
DRAINAGE ANALYSES
Hydrologic analyses were performed to determine the 10- and 100-year flow rates at the project
site. The County of San Diego's 2003 Hydrology Manual rational method procedure was used
for the hydrologic analyses. The rational method input parameters are summarized below and the
supporting data is included in Appendix A:
Precipitation: The 10-year, 6- and 24-hour precipitation values are 1.7 and 3.0 inches,
respectively. The 100-year, 6- and 24-hour precipitation values are 2.5 and 4.4 inches,
respectively.
Drainage areas: The drainage basins were primarily delineated from recent base topography
prepared for the project and the grading plan. The topography did not cover the northerly
portion of the overall drainage area, so the City of Carlsbad's 2005 mapping was used for
thisj area. The Carlsbad mapping is on NAVD 88 vertical datum, so the elevations were
reduced by 2 feet to convert to NGVD 29 vertical datum. See the Rational Method Work
Map in Appendix A for the basin boundaries, rational method node numbers, and basin
areas.
Hydrologic soil groups: The hydrologic soil groups were determined fi-om the Natural
Resources Conservation Service's (NRCS) Web Soil Survey. The soil groups in the study
area are classified as C and D. The soil groups have been delineated on the work map.
Runoff coefficients: The site currently contains pavement and landscaping and the post-
project uses will be similar. The land uses were selected based on the percent of impervious
area. For example, if a drainage subbasin is approximately 50 percent impervious, the
medium-density residential (14.5 DU/A) land use category was selected because this reflects
a 50 percent impervious area.
• Flow lengths and elevations: The flow lengths and elevations were obtained from the base
topography and engineering plans.
The existing and proposed condition rational method results are included in Appendix A. The
study area contains a Major Basin 10 (rational method node numbers 10 to 14) that is tributary to
the upper catch basin at node 14 as well as a Major Basin 20 (rational method node numbers 20
to 24) that is tributary to the lower catch basin. The proposed condition 100-year flow rate at
Major B^asin 10 is 7.2 cubic feet per second (cfs) and at a Major Basin 20 is 4.5 cfs. The existing
condition analysis shows that the 100-year flow rate at Major Basin 20 is 4.0 cfs. An existing
conditioii analysis was not performed for Major Basin 10 because this area is not affected by the
propose^ development. Based on these results, the project will cause a minor increase of about
0.5 cfs jto the 100-year flow rate. Since the runoff will enter on-site drainage facilities that
discharge into a large on-site detention basin serving the park, this minor increase will not cause
adverse off-site impacts.
The project is a Priority Development Project subject to the City's current treatment control and
hydromodification requirements. Consequently, a bioretention basin will be constructed within
an existing landscape area at the south end of the project. Since hydromodification applies up to
the 10-year event, the associated drainage facilities have been designed for the 10-year flow.
Proposed condition 10-year analyses were performed and are included in Appendix A. The
results indicate that the flow rate at the upper and lower catch basins will be 4.7 and 3.0 cfs,
respectively.
The catch basins were sized to capture these flow rates. The flow depth along the curb
approaching each catch basin was estimated using Figure 3-3 from the County of San Diego's
Hydrology Manual (see Appendix B). The weir flow routine from the Flowmaster program was
then used to determine the flow that can enter each basin under the given head. The weir
analyses assumed that each catch basin was along a curb on one side and 50 percent clogged.
The results indicate that the upper catch basin can be a 24-inch by 24-inch grated inlet and the
lower catch basin can be an 18-inch by 24-inch grated inlet.
Next, the Flowmaster normal depth routine was used to size the proposed pipes as well as the
emergency spillway in the bioretention basin. The pipes from each catch basin were sized for the
10-year flow. The results are included in Appendix B and show that upper pipe should be a 6-
inch PVC, while the lower pipe should be a 12-inch PVC. A 12-inch PVC riser will be installed
in the bioretention basin to convey the 10-year flow. The riser crest will be 10 inches above the
basin floor in accordance with standard bioretention design guidelines. The Flowmaster weir
routine included in Appendix B shows that the riser can convey the 10-year flow with 6 inches of
head. Consequently, the emergency spillway crest was set at the elevation of the riser crest plus 6
inches. The Flowmaster weir routine shows that the emergency spillway (3-foot bottom width
and 2:1 side slopes) can convey the 10-year flow at a 6-inch depth.
Finally, the outflow velocity from the 12-inch PVC riser discharging into the bioretention basin
is 5.5 feet per second per the normal depth results. This velocity requires No. 3 Backing riprap
according to the Greenbook Supplement. The riprap and filter blanket have been sized based on
the Supplement. The same riprap will be used on the emergency spillway since this will be
subject to minor flows.
CONCLUSION
Hydrologic and hydraulic analyses have been performed for LEGOLAND Califomia's new
parking toll booths at the park entrance. The analyses show that the project will cause a very
minor increase in the 100-year flow rate. The increase will not impact off-site areas particularly
since the park is served by a large on-site detention basin. The analyses were used to size the on-
site drainage facilities for the 10-year event in order to satisfy the current hydromodification
requirements.
APPENDIX A
RATIONAL IMETHOD ANALYSES
AND SUPPORTING DATA
LEGEND:
DRAINAGE BASIN BOUNDARY
OVERLAND FLOW PATH
PROPOSED STORM DRAIN
3.62 AC DRAINAGE BASIN AREA
iiol RATIONAL METHOD NODE NUMBER
HYDROLOGIC SOIL GROUP
r = 100'
LEGOLAND TOLL BOOTHS
RATIONAL METHOD WORK MAP
100
20 30
Minutes
Duration
Directions for Application:
(1) From precipitation maps determine 6 hr and 24 hr amounts
for the selected frequency. These maps are included in the
County Hydrology IVIanual (10,50, and 100 yrmaps included
in the Design and Procedure Manual).
(2) Adjust 6 hr precipitation (if necessary) so that it Is within
the range of 45% to 65% of the 24 hr precipitation (not
applicaple to Desert).
(3) Plot 6 hr precipitation on the right side of the chart.
(4) Draw a line through the point parallel to the plotted lines.
(5) This line is the intensity-duration curve for the location
being analyzed.
Application Form:
(a) Selected frequency 10
(b) P( = 1.7 in., P 24 -
(2)= 1.7
_ ysar
3.0
'P
57 0/^(2)
24
in. (c) Adjusted Pg'
(d) tj5 = min.
(e) I = in Ihr.
Note: This chart replaces the Intensity-Duration-Frequency
curves used since 1965.
1 1
P6 1 1 1.5 2 i 2.5 i 3 , ~3.5 "4.5' "B."5 6'"
Duration i V i 'i l " 1 " "1 1 { "1 I 1 r S Z63 i395 5 37'6.59 7,90 9 22 10 54! 11 86 13.17114.49 15,81
7 "sTa '•a 18 4 24] 5.30! 6 3617 42 8 48 ! 9 54 rO.eO! 11.66 12,72
io 1 68 12.53 3 37j"4~2r'5 05'5i6 6,74'; *7 .58" 8 42 9 27 10 n
1.30 Uss 2.S'9; 3 24""¥'8"9f4"S4 5I9"' '5 84 "6.49 "7'13 ""7",78"
20 1,08 i 1 62 2 15 ' 2 69 3 23 3 77 4.31 i 4 '85* '5.39 •5 "93" '"6"46'
25 0.93 11.40 1 87 2 33.2.8013.27 '3,73 : 4 20 4"67 "5 13' 'S60
"30 0 83 J t 24 ! 66 i 2,07:2.49 2 90 3" 32 : '373" 4 15 4,5S" 1"98
40 '6.69 ' i 03 1 38, 1.72;207i241 2 76 i 3.10 "3' 45 3 79 "4l3
50 '0.60 '0.9'd f 19(1,49'i'79'209 2,39 i 2 69 2 98 i 3 28 ~3 58
go 0 53 jo.a'o 1,06; 1 33 • 1 59 1 86 2.12: 2 39 2 65 2 92 "3 18
" "lo 63r 0.61 0 82; 1.02 ;i 2311 43
d 6170,85 il 02; 1 19
1 63 11 84 2 04 1 2.25 2*45'
" " 120 0 34" \o7sJ
0 82; 1.02 ;i 2311 43
d 6170,85 il 02; 1 19 1.36 ' 1,53 1 70 1 87 2 04
ISO 0,29 iO.44 0 59, 6 7316 88; I'os 'i 18 ; 1 32 1 47 1 62' 1 76
........ 0 26 '0.39 0.52 0 65:0 78 091 j'o'4 '1 18 l'31 1 44 1 57'
'0 22 6.33;0,43. 0 54 !0 65 0 76 0.87 "• '098' 1 08 119 1 30'
366 '019 '0.28 038 047:0 56
033' 0,4210,50
0 66 0 7S 0 85' "6 94' 1.03 "lla •"'"360 0 17 .0.25
038 047:0 56
033' 0,4210,50 058 "6,67 675" 0 84 0 92 1,00'
FIGURE
Intensity-Duration Design Chart - Template
S 6 7 8 g 10 15 20 30 40 SO 1
Minutes
Duration
3 4 S 6
Hours
Directions for Application:
(1) From precipitation maps determine 6 hr and 24 hr amounts
for the selected frequency. These maps are included in the
County Hydrology Manual (10,50, and 100 yr maps induded
in the Design and Procedure Manual)
(2) Adjust 6 hr precipitation (if necessary) so that it is within
the range of 45% to 65% of the 24 hr precipitation (not
applicaple to Desert)
(3) Plot 6 hr precipitation on the right side of the chart
(4) Draw a line through the point parallel to the plotted lines
(5) This line is the intensity-duration curve for the location
being analyzed.
Application Form:
(a) Selected frequency 1 year
(b) Po = 2.5 in., p-,, = 4.4 24 •P 57
(c) Adjusted P^^^) = 2.5 24
in.
(d) l,=
(e) I = _
mm
in./lir
Note: This chart replaces the Intensity-Duration-Frequency
curves used since 1965.
PS
Duration
.„
• 10
^15
20
25
30
""' • 40
50
60
90
120
' ISO
180
"1 24"6
300
"••"360
1,5 I
1 'i 2.63 ,3,95(5 27
'2"i2'''3.18!4 24
r68"i275'3i3.37
1 30"1l""9|,'2.5'9
i o's'J'i h?.;2J5
0 93 j1,4bi VB7
0 83 1,24; i 66
I I ! 1
4.5
"I
5.5
I
! 38
ri9
!".06
0 82
0.68
0 69 ; 1 03
0 00 0 90
dsj"''0.8d
0 41 ^0 6!
0 34 :Q.5\
0,29 '0.4410 59
0 26^;0."39i0.52
'0 22 ."0,'3'3jO.i3
0'l9''a28io'38
0 17 '0251033
6 59
536'
i'ai'
3 24 '
269"
2 33
'2,07
1 72'
1.49 i
I 33
1 02'
0 85'
0 73'
0 65:
0 54 '
7 9019 22
6 36i'7.42
'5 osi.5 90
"3 8914 54
3'23;3 77i
2,80'3.27'
2.49; 2'901
2 07 '(2 4'I'
I'fp'i 09
I S9|1 86
1 23: 1 43f
!'02;1.19j
0 88 1 03 i
ofsjogi!
0 65i076| 0 47'056>066|
0,42 ' 0 50 i 0.58 S
10 54'
8.48 i
6,74" j
'sl'g •
'4,'3i '
'3 73 '
3 32';
2" 76 J
2,39l
2 12 '
1.63 '
I "36 ,
i 18
l.d'i '
0,87'
0 75"
6,"67 '
11 86;
9 54 I
7 58 i
'5 84 1'
"4 85'j
4.20I
'3 73 •
3 10 j
"2 69 i'
2 39 j
1 84 j
1.5.3 j
t 32'1'
I'lS'l'
'0 98 i
0 85 r
QJGj_
13 17|
10 60;
8 '42 I
6"49'T
,5 39 !'
4 67 r
'4 15 [
3 45;
2.98'i'
14 49;
h.eb.
§ zf,
I'li]
5'93';'
5.13't
'4 58 T
379
3 28
2 65
2 04
I '70'
l'47
1.31
1 08
0 94'
0.34
' 2.92
2 25"
I 87'
1 62
1.44
i I 19
1.03
'0 92
15 81
!"2.72
ioji
'7 78
"6' 46'
5 60
4 98
4'13'
3 58
3 18
2 45
2 04'
'! 76
r.57
1 30
1 60
FIGURE
Intensity-Duration Design Cliart - Template
County of San Diego
Hydrology Manual
Rainfall Isopluvials
10 Year Rxiiifall Evrat-lHovrs
Isopiuvial (Inches)
P6=1.7
GIS SmGIS
Wc Hive San l>icgo Cin-ercdl
wiyiJa^wcujBDiqtBifri«TuiiiEaTO.TMEi>w^iww^^
3 0 3 Miles
33*30^
-'33T)0'-
Onange
10 Year Rainfall Event - 24 Honrs
County of San Diego
Hydrology Manual
Rainfall Isopluvials
Isopiuvial (Inches)
P24=3-0"
^Gis SffiGIS
Wc Have San C/ivcrtti!
. „ . ..gngtimi - ----
OF MEHCHNnMiuTTMO Fcncta FQR A nvcnCuun nxMC-
_ TT»BHOi1l nnmW>li»,nia,iilWip»lMBl)<OnWW«* -T7 W»M»W»W»—W****"" — —
County of San Diego
Hydrology Manual
San Diego County Hydrology IVIanual
Date June 2003
Section
Page
3
6 of 26
Table 3-1
RUNOFF COEFFICIENTS FOR URBAN AREAS
Land Use Runoff Coefficient "C"
Soil Type
NRCS Elements County Elements % IMPER A B C D
Undisturbed Natiiral Terrain (Natural) Pennanent Open Space 0* 0 20 0 25 0 30 0 35
Low Density Residential (LDR) Residential, 1 0 DU/A or less 10 0-27 0 32 0 36 0 41
Low Density Residential (LDR) Residential, 2 0 DU/A or less 20 0 34 038 0 42 0 46
Low Density Residential (LDR) Residential, 2 9 DU/A or less 25 0 38 041 0 45 0 49
Medium Density Residential OvIDR) Residential. 4 3 DU/A or less 30 041 0 45 0 48 0.52
Medium Density Residential (IvIDR) Residential 7 3 DV/A or less 40 0 48 0 51 0 54 0 57
Medium Density Residential (MDR) Residential, 10 9 DU/A or less 45 0 52 0 54 0 57 0 60
Medium Density Residential (MDR). Residential, 14 5 DU/A or less 50 0 55 0 58 0 60 0 63
High Density Residential (HDR) Residential, 24 0 DU/A or less 65 0 66 0 67 0 69 0 71
High Density Residential (HDR) Residential, 43 0 DU/A or less 80 0 76 0 77 0 78 0 79
Commercial/Industrial (N Com) iNleighborhood Commercial 80 0 76 0 77 0 78 0 79
Commercial/Industrial (G Com) General Commercial 85 0 80 0 80 0 81 0 82
Commercial/Industrial (0 P Com) Office Professional/Commercial 90 0 83 0 84 0 84 0 85
Comm ere laLTndustnal (Limited I) Limited Industrial 90 0.83 0 84 0 84 0 85
Commercial/Industrial (General I) General Industrial 95 0 87 0 87 0 87 0 87
*The values associated with 0% mipervious may be used for direct calculation of the runoff coefficient as described m Section 3 12 (representmg the pervious runoff
coefficient, Cp, for the soil type), oi for areas that will remain undisturbed m perpetuity Justification must be given that the area will remain natural forever (e g, the area
IS located m Cleveland National Forest)
DU/A = dwelling units per acre
NRCS = National Resources .Conservation Service
3-6
San Diego County Hvdrologv Manual
Date June 2003
Section
Page
3
12 of 26
Note t]iat the Initial Time of Concentration should be reflective of the general land-use at the
upstream end of a drainage basin. A single lot with an area of two or less acres does not have
a significant effect where the drainage basin area is 20 to 600 acres.
Table 3-2 provides limits of the length (Maximum Length (LM)) of sheet flow to be used in
hydrology studies. Initial T, values based on average C values for the Land Use Element are
also included. These values can be used in planning and design applications as described
below. Exceptions may be approved by tlie "Regulating .Agency" when submitted with a
detailed study.
Table 3-2
MAXIMUM OVERLAND FLOW LENGTH (LM)
Element* DU/
Acre
.5% 1% 2% 3% 5% 10% Element* DU/
Acre LM T, LM T, LM T, LM T. LM T, LM T,
Natural 50 13.2 70 12.5 85 10.9 100 10.3 100 8.7 100 6.9
LDR 1 50 12.2 70 11.5 85 10.0 100 9.5 100 8.0 100 6.4
LDR 2 50 11.3 70 10.5 85 9.2 100 8.8 100 7.4 100 5.8
LDR 2.9 50 10.7 70 10.0 85 8.8 95 8.1 100 7.0 100 5.6
MDR 4.3 50 10.2 70 9.6 80 8.1 95 7.8 100 6.7 100 5.3
MDR 7.3 50 9.2 65 8.4 80 7.4 95 7.0 100 6.0 100 4.8
MDR 10.9 50 8.7 65 7.9 80 6.9 90 6.4 100 5.7 100 4.5
MDR 145 50 8.2 65 7.4 80 6.5 90 6.0 100 5.4 100 4.3
HDR 24 50 6.7 65 6.1 75 5.1 90 4.9 95 4.3 100 3.5
HDR 43 50 5.3 65 47 75 4.0 85 3.8 95 3.4 100 2.7
N. Com 50 5.3 60 4.5 75 4.0 85 3.8 95 3.4 100 2.7
G. Com 50 4.7 60 4.1 75 3.6 85 3.4 90 2.9 100 2.4
O.P./Com 50 4.2 60 3.7 70 3.1 80 2.9 90 2.6 100 2.2
Limited I. 50 4.2 60 3.7 70 3.1 80 2.9 90 2.6 100 2.2
General I. 50 3.7 60 3.2 70 2.7 80 2.6 90 2.3 100 1.9
*See Table 3-1 for more detailed description
3-12
100
I-
UJ LU LL
UJ o z <
w
OT
a:
o o ac
UJ
UJ
2
Q 2
UJ > o
EXAMPLE.
Given: Watercourse Distance (D) = 70 Feet
Slope (s) =1.370
Runoff Coefficient (C) = 0.41
Overland Flow Time (T) = 9.5 Minutes
1.8 (1.1-C)VD"
SOURCE: Airport Drainage, Federal Aviation Administration, 1965
FIGURE
Rational Formula - Overland Time of Flow Nomograph
San Diego County Rational Hydrology Program
CIVILCADD/CIVILDESIGN Engineering Software, (c)1991-2009 Version 7
Rational method hydrology program based on
San Diego County Flood Control Division 2003 hydrology manual
Rational Hydrology Study Date: 12/20/12
LEGOLAND California
New Parking Toll Booths
Existing Conditions
100-Year Storm Event
********* Hydrology Study Control Information **********
Program License Serial Number 4028
Rational hydrology study storm event year is 100.0
English (in-lb) input data Units used
Map data precipitation entered:
6 hour, precipitation(inches) = 2.500
24 hour precipitation(inches) = 4.400
P6/P24 = 56.8%
San Diego hydrology manual 'C values used
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Process from Point/Station 20.000 to Point/Station 22.000
**** INITIAL AREA EVALUATION ****
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 1.000
Decimal fraction soil group D = 0.000
[INDUSTRIAL area type ]
(General Industrial )
Impervious value, Ai = 0.950
Sub-Area C Value = 0.870
Initial subarea total flow distance = 100.000(Ft.)
Highest elevation = 147.800(Ft.)
Lowest elevation = 142.500(Ft.)
Elevation difference = 5.300(Ft.) Slope = 5.300 %
INITIAL AREA TIME OF CONCENTRATION CALCULATIONS:
The maximum overland flow distance is 90.00 (Ft)
for the top area slope value of 5.30 %, in a development type of
General Industrial
In Accordance With Figure 3-3
Initial Area Time of Concentration = 2.25 minutes
TC = [1.8* (1.1-C) *distance (Ft. )-^.5) / (% slope'^ (1/3) ]
TC = [1. 8* (1.1-0 . 8700) * ( 90.000".5)/( 5 . 300^^ (1/3) ] = 2.25
Calculated TC of 2.253 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 6.587(In/Hr) for a 100.0 year storm
Effective runoff coefficient used for area (Q=KCIA) is C = 0.870
Subarea runoff = 0.229(CFS)
Total initial stream area = 0.040(Ac.)
Process from Point/Station 22.000 to Point/Station 24.000
**** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION ****
Top of street segment elevation = 142.500(Ft.)
End of street segment elevation = 126.200(Ft.)
Length of street segment = 394.000(Ft.)
Height of curb above gutter flowline = 6.0(In.)
Width of half street (curb to crown) = 18.000(Ft.)
Distance from crown to crossfall grade break = 8.000(Ft.)
Slope from gutter to grade break (v/hz) = 0.020
Slope from grade break to crown (v/hz) = 0.020
Street flow is on [1] side(s) of the street
Distance from curb to property line = 10.000(Ft.)
Slope from curb to property line (v/hz) = 0.020
Gutter width = 1.500(Ft.)
Gutter hike from flowline = 1.500(In.)
Manning's N in gutter = 0.0150
Manning's N from gutter to grade break = 0.0180
Manning's N from grade break to crown = 0.0180
Estimated mean flow rate at midpoint of street = 2.070(CFS)
Depth of flow = 0.245(Ft.), Average velocity = 3.276(Ft/s)
Streetflow hydraulics at midpoint of street travel:
Halfstreet flow width = 7.488(Ft.)
Flow velocity = 3.28(Ft/s)
Travel time = 2.00 min. TC = 4.26 min.
Adding area flow to street
Calculated TC of 4.257 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 6.587(In/Hr) for a 100.0 year storm
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 0.220
Decimal fraction soil group D = 0.780
[MEDIUM DENSITY RESIDENTIAL ]
(14.5 DU/A or Less )
Impervious value, Ai = 0.500
Sub-Area C Value = 0.623
Rainfall intensity = 6.587(In/Hr) for a 100.0 year storm
Effective runoff coefficient used for total area
(Q=KCIA) is C = 0.634 CA = 0.602
Subarea runoff = 3.737(CFS) for 0.910(Ac.)
Total runoff = 3.966(CFS) Total area = 0.950(Ac.)
Street flow at end of street = 3.966(CFS)
Half street flow at end of street = 3.966(CFS)
Depth of flow = 0.293(Ft.), Average velocity = 3.790(Ft/s)
Flow width (from curb towards crown)= 9.875(Ft.)
End of computations, total study area = 0.950 (Ac.)
San Diego County Rational Hydrology Program
CIVILCADD/CIVILDESIGN Engineering Software,(c)1991-2009 Version 7,
Rational method hydrology program based on
San Diego County Flood Control Division 2003 hydrology manual
Rational Hydrology Study Date: 12/20/12
LEGOLAND California
New Parking Toll Booths
Proposed Conditions
100-Year Storm Event
********* Hydrology Study Control Information *** *******
Program License Serial Number 4028
Rational hydrology study storm event year is 100.0
English (in-lb) input data Units used
Map data precipitation entered:
6 hour, precipitation(inches) = 2.500
24 hour precipitation(inches) = 4.400
P6/P24 = 56.8%
San Diego hydrology manual 'C values used
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Process from Point/Station 10.000 to Point/Station 12.000
**** INITIAL AREA EVALUATION ****
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 1.000
Decimal fraction soil group D = 0.000
[UNDISTURBED NATURAL TERRAIN ]
(Permanent Open Space )
Impervious value, Ai = 0.000
Sub-Area C Value = 0.300
Initial subarea total flow distance = 100.000(Ft.)
Highest elevation = 164.400(Ft.)
Lowest elevation = 151.800(Ft.)
Elevation difference = 12.600(Ft.) Slope = 12.600 %
INITIAL AREA TIME OF CONCENTRATION CALCULATIONS:
The maximum overland flow distance is 100.00 (Ft)
for the top area slope value of 12.60 %, in a development type of
Permanent Open Space
In Accordance With Figure 3-3
Initial Area Time of Concentration = 6.19 minutes
TC = [1. 8* (1.1-C) *distance (Ft. ) 5) / (% slope'^ (1/3) ]
TC = [1.8* (1.1-0.3000)* ( 100.000".5)/( 12.600^(1/3)]= 6.19
Rainfall intensity (I) = 5.740(In/Hr) for a 100.0 year storm
Effective runoff coefficient used for area (Q=KCIA) is C = 0.300
Subarea runoff = 0.207(CFS)
Total initial stream area = 0.120(Ac.)
Process from Point/Station 12.000 to Point/Station 14.000
**** STREET FLOW- TRAVEL TIME + SUBAREA FLOW ADDITION ****
Top of street segment elevation = 151.800(Ft.)
End of street segment elevation = 141.000(Ft.)
Length of street segment = 788.000(Ft.)
Height of curb above gutter flowline = 6.0(In.)
Width of half street (curb to crown) = 18.000(Ft.)
Distance from crown to crossfall grade break = 8.000(Ft.)
Slope from gutter to grade break (v/hz) = 0.020
Slope from grade break to crown (v/hz) = 0.020
Street flow is on [1] side(s) of the street
Distance from curb to property line = 10.000(Ft.)
Slope from curb to property line (v/hz) = 0.020
Gutter width = 1.500(Ft.)
Gutter hike from flowline = 1.500(In.)
Manning's N in gutter = 0.0150
Manning's N from gutter to grade break = 0.0180
Manning's N from grade break to crown = 0.0180
Estimated mean flow rate at midpoint of street = 3.666(CFS)
Depth of flow = 0.334(Ft.), Average velocity = 2.436(Ft/s)
Streetflow hydraulics at midpoint of street travel:
Halfstreet flow width = 11.973(Ft.)
Flow velocity = 2.44(Ft/s)
Travel time = 5.39 min. TC = 11.58 min.
Adding area flow to street
Rainfall intensity (I) = 3.832(In/Hr) for a 100.0 year storm
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 0.730
Decimal fraction soil group D = 0.270
[MEDIUM DENSITY RESIDENTIAL ]
(14.5 DU/A or Less )
Impervious value, Ai = 0.500
Sub-Area C Value = 0.608
Rainfall intensity = 3.832(In/Hr) for a 100.0 year storm
Effective runoff coefficient used for total area
(Q=KCIA) is C = 0.596 CA = 1.879
Subarea runoff = 6.992(CFS) for 3.030(Ac.)
Total runoff = 7.199(CFS) Total area = 3.150(Ac.)
Street flow at end of street = 7.199(CFS)
Half street flow at end of street = 7.199(CFS)
Depth of flow = 0.408(Ft.), Average velocity = 2.862(Ft/s)
Flow width (from curb towards crown)= 15.633(Ft.)
Process from Point/Station 12.000 to Point/Station 14.000
**** CONFLUENCE OF MAIN STREAMS ****
The following data inside Main Stream is listed:
In Main Stream number: 1
Stream flow area = 3.150(Ac.)
Runoff from this stream = 7.199(CFS)
Time of concentration = 11.58 min.
Rainfall intensity = 3.832(In/Hr)
Program is now starting with Main Stream No. 2
Process from Point/Station 20.000 to Point/Station 22.000
**** INITIAL AREA EVALUATION ****
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 1.000
Decimal fraction soil group D = 0.000
[INDUSTRIAL area type ]
(General Industrial )
Impervious value, Ai = 0.950
Sub-Area C Value = 0.870
Initial subarea total flow distance = 100.000(Ft.)
Highest elevation = 147.800(Ft.)
Lowest elevation = 142.500(Ft.)
Elevation difference = 5.300(Ft.) Slope = 5.300 %
INITIAL AREA TIME OF CONCENTRATION CALCULATIONS:
The maximum overland flow distance is 90.00 (Ft)
for the top area slope value of 5.30 %, in a development type of
General Industrial
In Accordance With Figure 3-3
Initial Area Time of Concentration = 2.25 minutes
TC = [1. 8* (1.1-C) *distance (Ft. ). 5) / (% slope'-(1/3) ]
TC = [1. 8* (1.1-0 . 8700) * ( 90.OOO'-.5) / ( 5 . SOO'-(1/3) ] = 2.25
Calculated TC of 2.253 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 6.587(In/Hr) for a 100.0 year storm
Effective runoff coefficient used for area (Q=KCIA) is C = 0.870
Subarea runoff = 0.229(CFS)
Total initial stream area = 0.040(Ac.)
Process from Point/Station 22.000 to Point/Station 24.000
**** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION ****
Top of street segment elevation = 142.500(Ft.)
End of street segment elevation = 126.200(Ft.)
Length of street segment = 394.000(Ft.)
Height of curb above gutter flowline = 6.0(In.)
Width of half street (curb to crown) = 18.000(Ft.)
Distance from crown to crossfall grade break = 8.000(Ft.)
Slope from gutter to grade break (v/hz) = 0.020
Slope from grade break to crown (v/hz) = 0.020
Street flow is on [1] side(s) of the street
Distance from curb to property line = 10.000(Ft.)
Slope from curb to property line (v/hz) = 0.020
Gutter width = 1.500(Ft.)
Gutter hike from flowline = 1.500(In.)
Manning's N in gutter = 0.0150
Manning's N from gutter to grade break = 0.0180
Manning's N from grade break to crown = 0.0180
Estimated mean flow rate at midpoint of street = 2.313(CFS)
Depth of flow = 0.252(Ft.), Average velocity = 3.356(Ft/s)
Streetflow hydraulics at midpoint of street travel:
Halfstreet flow width = 7.860(Ft.)
Flow velocity = 3.36(Ft/s)
Travel time = 1.96 min. TC = 4.21 min.
Adding area flow to street
Calculated TC of 4.209 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 6.587(In/Hr) for a 100.0 year storm
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 0.220
Decimal fraction soil group D = 0.780
[HIGH DENSITY RESIDENTIAL ]
(24.0 DU/A or Less )
Impervious value, Ai = 0.650
Sub-Area C Value = 0.706
Rainfall intensity = 6.587(In/Hr) for a '100.0 year storm
Effective runoff coefficient used for total area
(Q=KCIA) is C = 0.713 CA = 0.677
Subarea runoff = 4.229(CFS) for 0.910(Ac.)
Total runoff = 4.459(CFS) Total area = 0.950(Ac.)
Street flow at end of street = 4.459(CFS)
Half street flow at end of street = 4.459(CFS)
Depth of flow = 0.302(Ft.), Average velocity = 3.894(Ft/s)
Flow width (from curb towards crown)= 10.363(Ft.)
Process from Point/Station 22.000 to Point/Station 24.000
**** CONFLUENCE OF MAIN STREAMS ****
The following data inside Main Stream is listed:
In Main Stream nurr±)er: 2
Stream flow area = 0.950(Ac.)
Runoff from this stream = 4.459(CFS)
Time of concentration = 4.21 min.
Rainfall intensity = 6.587(In/Hr)
Summary of stream data:
Stream Flow rate TC Rainfall Intensity
No. (CFS) (min) (In/Hr)
1 7.199 11.58 3.832
2 4.459 4.21 6.587
Qmax(l) =
1.000 * 1.000 * 7.199) +
0.582 * 1.000 * 4.459) + = 9.793
Qmax(2) =
1.000 * 0.364 * 7.199) +
1.000 * 1.000 * 4.459) + = 7.076
Total of 2 main streams to confluence:
Flow rates before confluence point:
7.199 4.459
Maximum flow rates at confluence using above data:
9.793 7.076
Area of streams before confluence:
3.150 0.950
Results of confluence:
Total flow rate = 9.793(CFS)
Time of concentration = 11.579 min.
Effective stream area after confluence = 4.100(Ac.)
End of computations, total study area = 4.100 (Ac.
San Diego County Rational Hydrology Program
CIVILCADD/CIVILDESIGN Engineering Software,(c)1991-2009 Version 7.8
Rational method hydrology program based on
San Diego County Flood Control Division 2003 hydrology manual
Rational Hydrology Study Date: 12/20/12
LEGOLAND California
New Parking Toll Booths
Proposed Conditions
10-Year Storm Event
********* Hydrology Study Control Information **********
Program License Serial Number 4028
Rational hydrology study storm event year is 10.0
English (in-lb) input data Units used
Map data precipitation entered:
6 hour, precipitation{inches) = 1.700
24 hour precipitation(inches) = 3.000
P6/P24 = 56.7%
San Diego hydrology manual 'C values used
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Process from Point/Station 10.000 to Point/Station 12.000
**** INITIAL AREA EVALUATION ****
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 1.000
Decimal fraction soil group D = 0.000
[UNDISTURBED NATURAL TERRAIN ]
(Permanent Open Space )
Impervious value, Ai = 0.000
Sub-Area C Value = 0.300
Initial subarea total flow distance = 100.000(Ft.)
Highest elevation = 164.400(Ft.)
Lowest elevation = 151.800(Ft.)
Elevation difference = 12.600(Ft.) Slope = 12.600 %
INITIAL AREA TIME OF CONCENTRATION CALCULATIONS:
The maximum overland flow distance is 100.00 (Ft)
for the top area slope value of 12.60 %, in a development type of
Permanent Open Space
In Accordance With Figure 3-3
Initial Area Time of Concentration = 6.19 minutes
TC = [1. 8* (1.1-C) *distance (Ft. ) " . 5) / (% slope'-(1/3) ]
TC = [1. 8* (1.1-0 . 3000) * ( 100 . 000'-. 5) / ( 12 . 600'-(1/3) ] = 6.19
Rainfall intensity (I) = 3.904 (In/Hr) for a 10.0 year storm
Effective runoff coefficient used for area (Q=KCIA) is C = 0.300
Subarea runoff = 0.141(CFS)
Total initial stream area = 0.120(Ac.)
Process from Point/Station 12.000 to Point/Station 14.000
**** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION ****
Top of street segment elevation = 151.800(Ft.)
End of street segment elevation = 141.000 (Ft.)
Length of street segment = 788.000(Ft.)
Height of curb above gutter flowline = 6.0(In.)
Width of half street (curb to crown) = 18.000(Ft.)
Distance from crown to crossfall grade break = 8.000(Ft.)
Slope from gutter to grade break (v/hz) = 0.020
Slope from grade break to crown (v/hz) = 0.020
Street flow is on [1] side(s) of the street
Distance from curb to property line = 10.000(Ft.)
Slope from curb to property line (v/hz) = 0.020
Gutter width = 1.500(Ft.)
Gutter hike from flowline = 1.500(In.)
Manning's N in gutter = 0.0150
Manning's N from gutter to grade break = 0.0180
Manning's N from grade break to crown = 0.0180
Estimated mean flow rate at midpoint of street = 2.403(CFS)
Depth of flow = 0.297(Ft.), Average velocity = 2.207(Ft/s)
Streetflow hydraulics at midpoint of street travel:
Halfstreet flow width = 10.087(Ft.)
Flow velocity = 2.21(Ft/s)
Travel time = 5.95 min. TC = 12.14 min.
Adding area flow to street
Rainfall intensity (I) = 2.528(In/Hr) for a 10.0 year storm
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 0.730
Decimal fraction soil group D = 0.270
[MEDIUM DENSITY RESIDENTIAL ]
(14.5 DU/A or Less )
Impervious value, Ai = 0.500
Sub-Area C Value = 0.608
Rainfall intensity = 2.528(In/Hr) for a 10.0 year storm
Effective runoff coefficient used for total area
(Q=KCIA) is C = 0.596 CA = 1.879
Subarea runoff = 4.608(CFS) for 3.030(Ac.)
Total runoff = 4.749(CFS) Total area = 3.150(Ac.)
Street flow at end of street = 4.749(CFS)
Half street flow at end of street = 4.749(CFS)
Depth of flow = 0.360(Ft.), Average velocity = 2.590(Ft/s)
Flow width (from curb towards crown)= 13.274(Ft.)
Process from Point/Station 12.000 to Point/Station 14.000
**** CONFLUENCE OF MAIN STREAMS ****
The following data inside Main Stream is listed:
In Main Stream number: 1
Stream flow area = 3.150(Ac.)
Runoff from this stream = 4.749(CFS)
Time of concentration = 12.14 min.
Rainfall intensity = 2.528(In/Hr)
Program is now starting with Main Stream No. 2
Process from Point/Station 20.000 to Point/Station 22.000
**** INITIAL AREA EVALUATION ****
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 1.000
Decimal fraction soil group D = 0.000
[INDUSTRIAL area type ]
(General Industrial )
Impervious value, Ai = 0.950
Sub-Area C Value = 0.870
Initial subarea total flow distance = 100.000(Ft.)
Highest elevation = 147.800(Ft.)
Lowest elevation = 142.500(Ft.)
Elevation difference = 5.300(Ft.) Slope = 5.300 %
INITIAL AREA TIME OF CONCENTRATION CALCULATIONS:
The maximum overland flow distance is 90.00 (Ft)
for the top area slope value of 5.30 %, in a development type of
General Industrial
In Accordance With Figure 3-3
Initial Area Time of Concentration = 2.25 minutes
TC = [1. 8* (1.1-C) *distance (Ft. ) ^ . 5) / (% slope-^ (1/3) ]
TC = [1.8* (1.1-0.8700) * ( 90 . 000'^. 5) / ( 5.300^^(1/3)]= 2.25
Calculated TC of 2.253 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 4.479(In/Hr) for a 10.0 year storm
Effective runoff coefficient used for area (Q=KCIA) is C = 0.870
Subarea runoff = 0.156(CFS)
Total initial stream area = 0.040(Ac.)
Process from Point/Station 22.000 to Point/Station 24.000
**** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION ****
Top of street segment elevation = 142.500(Ft.)
End of street segment elevation = 126.200(Ft.)
Length of street segment = 394.000(Ft.)
Height of curb above gutter flowline = 6.0(In.)
Width of half street (curb to crown) = 18.000(Ft.)
Distance from crown to crossfall grade break = 8.000(Ft.)
Slope from gutter to grade break (v/hz) = 0.020
Slope from grade break to crown (v/hz) = 0.020
Street flow is on [1] side(s) of the street
Distance from curb to property line = 10.000(Ft.)
Slope from curb to property line (v/hz) = 0.020
Gutter width = 1.500(Ft.)
Gutter hike from flowline = 1.500(In.)
Manning's N in gutter = 0.0150
Manning's N from gutter to grade break = 0.0180
Manning's N from grade break to crown = 0.0180
Estimated mean flow rate at midpoint of street = 1.551(CFS)
Depth of flow = 0.226(Ft.), Average velocity = 3.081(Ft/s)
Streetflow hydraulics at midpoint of street travel:
Halfstreet flow width = 6.574(Ft.)
Flow velocity = 3.08(Ft/s)
Travel time = 2.13 min. TC = 4.38 min.
Adding area flow to street
Calculated TC of 4.384 minutes is less than 5 minutes,
resetting TC to 5.0 minutes for rainfall intensity calculations
Rainfall intensity (I) = 4.479(In/Hr) for a 10.0 year storm
Decimal fraction soil group A = 0.000
Decimal fraction soil group B = 0.000
Decimal fraction soil group C = 0.220
Decimal fraction soil group D = 0.780
[HIGH DENSITY RESIDENTIAL ]
(24.0 DU/A or Less )
Impervious value, Ai = 0.650
Sub-Area C Value = 0.706
Rainfall intensity = 4.479(In/Hr) for a 10.0 year storm
Effective runoff coefficient used for total area
(Q=KCIA) is C = 0.713 CA = 0.677
Subarea runoff = 2.876(CFS) for 0.910(Ac.)
Total runoff = 3.032(CFS) Total area = 0.950(Ac.)
Street flow at end of street = 3.032(CFS)
Half street flow at end of street = 3.032(CFS)
Depth of flow = 0.272(Ft.), Average velocity = 3.565(Ft/s)
Flow width (from curb towards crown)= 8.828(Ft.)
Process from Point/Station 22.000 to Point/Station 24.000
**** CONFLUENCE OF MAIN STREAMS ****
The following data inside Main Stream is listed:
In Main Stream number: 2
Stream flow area = 0.950(Ac.)
Runoff from this stream = 3.032(CFS)
Time of concentration = 4.38 min.
Rainfall intensity = 4.479(In/Hr)
Suinmary of stream data:
Stream
No.
Flow rate
(CFS)
TC
(min)
Rainfall Intensity
(In/Hr)
1
2
Qmax(1) =
4 .749
3.032
1. 000
0.564
Qmax(2) =
1
1
000
000
12 .14
4.38
000 *
000 *
0.361 *
1.000 *
2.528
4 . 479
4.749) +
3.032) + =
4.749) +
3.032) + =
6. 460
4.747
Total of 2 main streams to confluence:
Flow rates before confluence point:
4.749 3.032
Maximum flow rates at confluence using above data:
6.460 4.747
Area of streams before confluence:
3.150 0.950
Results of confluence:
Total flow rate = 6.460(CFS)
Time of concentration = 12.138 min.
Effective stream area after confluence =
End of computations, total study area =
4.100(Ac.)
4.100 (Ac.
APPENDIX B
HYDRAULIC ANALYSES
1^ -1 5'-•*-l
20.
18.
16.
14-
12.
10-
9-
8-
7 .
6 •
5 .
4 —
ID CL
-2 3.
(U <U
&
o 2 •
1 8 •
1 6 .
1 4 •
1 2-
1 0 .
09 .
0.8 .
07 .
OS-
OS .
04 •
Concrete
Gutter
5 6 7 8 9 10
Discharge (CFS)
EXAMPLE:
Given: Q = 10 S = 2.5%
Chart gives: Depth = 0.4, Velocity = 4.4 f.p.s.
SOURCE San Diego County Department of Special Distnct Services Design Manual
FIGURE
Gutter and Roadway Discharge - Velocity Chart
Worksheet for Weir Flow - Upper 24"x24" Grated Inlet
jProject Descnptjqn ^
Solve For
|g£ut5ata^^
Headwater Elevation
Crest Elevation
Weir Coefficient
Crest Length
Discharge
iiSilillLjS.
Discharge
Headwater Height Above Crest
Flow Area
Velocity
Wetted Perimeter
Top Width
•iSfr?'*''"'''
141 70 ft
140 90 ft
3 00 US
4 00 ft
8 59 ft%
0 80 ft
3 20 ft^
2 68 ft/s
5 60 ft
4 00 ft
Bentley Systems, Inc. Haestad Methods ScSMtiAtoyaetdsMaster VSi (SELECTseries 1) [08.11.01 03]
12/20/2012 5 26-10 PM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1
Worksheet for Weir Flow - Lower 18"x24" Grated Inlet
[Projei^-Description- . K^fei 'r,,'^c:g/ ' -i:/l*iSilli^^
Solve For Discharge
Input Data
Headwater Elevation 126 75 ft
Crest Elevation 126 20 ft
Weir Coefficient 3 00 US
Crest Length 3.50 ft
Discharge 4 28 ft%
Headwater Height Above Crest 0.55 ft
Flow Area 1 92 ft^
Velocity 2.22 ft/s
Wetted Penmeter 4.60 ft
Top Width 3 50 ft
Bentiey Systems, inc. Haestad Methods ScBsMtsjCEIitoMaster V81 (SELECTseries 1) [08.11.01.03]
12/20/2012 5-13:26 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page lof 1
Worksheet for 6" PVC Pipe
PlltiiiriM§ig^
Friction Method
Solve For
Manning Formula
Normal Depth
Roughness Coefficient
Channel Slope
Diameter
Discharge
0013
0 90000 ft/ft
0 50 ft
4.90 ftVs
Mormal Depth 0 38 ft
Flow Area 0 16 ft^
Wetted Perimeter 1 05 ft
Hydraulic Radius 0 15 ft
Top Width 0 43 ft
Cntical Depth 0 50 ft
Percent Full 75 7 %
Critical Slope 0 75825 ft/ft
Velocity 30.74 ft/s
Velocity Head 14 69 ft
Specific Energy 15 07 ft
Froude Number 8 89
Maximum Discharge 5 73 ftVs
Discharge Full 5 32 ft%
Slope Full 0 76269 ft/ft
Flow Type SuperCntical
Qffii inpiJt^SW-l^tes-il " i, 'ijh. 7...Ji
Downstream Depth 0 00 ft
Length 0 00 ft
Number Of Steps 0
Upstream Depth 0 00 ft
Profile Descnption
Profile Headloss 0 00 ft
Average End Depth Over Rise 0 00 %
Normal Depth Over Rise 75 66 %
Downstream Velocity Infinity ft/s
Bentley Systems, Inc. Haestad Methods ScBetitteyC&titoMaster VSi (SELECTseries 1) [08.11.01.03]
12/11/2012 11 13.55 AM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 2
Worksheet for 6" PVC Pipe
Upstream Velocity Infinity ft/s
Normal Depth 0 38 ft
Critical Depth 0 50 ft
Channel Slope 0 90000 ft/ft
Cntical Slope 0 75825 ft/ft
Bentley Systems, inc. Haestad Methods S(AstMte)CEW»Master V8i (SELECTseries 1) [08.11.01.03]
12/11/2012 11 13 55 AM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 2 of 2
Worksheet for 12" PVC Pipe
•Prgect^Descnptionr'tf«^f:..|.>:;„. / .cti^ :
Fnction Method
Solve For
Manning Formula
Normal Depth
Roughness Coefficient
Channel Slope
Diameter
Discharge
0 013
0 01000 ft/ft
1 00 ft
3 00 ft%
•Results'***
Normal Depth 0 70 ft
Flow Area 0 59 ft^
Wetted Penmeter 1 99 ft
Hydraulic Radius 0 30 ft
Top Width 0 91 ft
Cntical Depth 0 74 ft
Percent Full 70.3 %
Cntical Slope 0 00873 ft/ft
Velocity 5 08 ft/s
Velocity Head 0 40 ft
Specific Energy 1 10 ft
Froude Number 1 12
Maximum Discharge 3 83 ft%
Discharge Full 3 56 ft%
Slope Full 0 00709 ft/ft
Flow Type SuperCntical
Downstream Depth
Length
Number Of Steps
0 00 ft
0 00 ft
0
IGVF OutputOata i#i"/v*-ifl*is<-",,"--. r
Upstream Depth
Profile Description
Profile Headloss
Average End Depth Over Rise
Normal Depth Over Rise
Downstream Velocity
0 00 ft
0 00 ft
0 00 %
70 30 %
Infinity ft/s
12/20/2012 5-14:55 PM
Bentley Systems, Inc. Haestad Methods ScOstititiyCEMarMaster V8i (SELECTseries 1) [08.11.01.03]
27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 2
Worksheet for 12" PVC Pipe
G>^;duteutData,s2; v^ll^ ^..-.-'OB'\: i':>E^">'- \^.^MdI:: .'..siME
Upstream Velocity ~ Infinity ft/s
Normal Depth 0 70 ft
Cntical Depth 0 74 ft
Channel Slope 0 01000 ft/ft
Critical Slope 0 00873 ft/ft
Bentley Systems, inc. Haestad Methods ScBisMteyCeWwMaster VSi (SELECTseries 1) [08.11 01.03]
12/20/2012 5.14:55 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 08795 USA +1-203-755-1666 Page 2 of 2
Worksheet for 12" Riser
J'rojecf Descrit)tidn^ _2:iM'Sl'£j.^jjS£. 'K'"^"
Solve For Headwater Elevation
Discharge
Crest Elevation
Weir Coefficient
Crest Length
Headwater Elevation
Headwater Height Above Crest
Flow Area
Velocity
Wetted Perimeter
Top Width
3 00 ft%
11953 ft
3 00 US
3 14 ft
120 00 ft
0 47 ft
1 46 ft^
2 05 ft/s
4 07 ft
3 14 ft
Bentley Systems, Inc. Haestad Methods ScSuEtMlayE^eMisMaster VSi (SELECTseries 1) [08.11.01 03]
12/20/2012 5 29 59 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page lof 1
Worksheet for Emergency spillway
Solve For Headwater Elevation
irt|ut'Data-*ife"' ' W*'t •^l^'^^^v^f!^^ - •?f?^r,i5^'^'3f*'.i '•iF'^i-^^^^ffv'f'' .e£M.4^^1^^J9fP'\9fH
Discharge 3.00 ft^/s
Crest Elevation 120 00 ft
Weir Coefficient 3 00 US
Crest Length 3 00 ft
•Results.;il54^>..,-7.3Sf;': li|^^/r!5*'%4!^^ . s ^ ^'tl^ "1^ ' • ' Slpii^^-m^^'r^
Headwater Elevation 120 48 ft
Headwater Height Above Crest 0 48 ft
Flow Area 1 44 ft^
Velocity 2 08 ft/s
Wetted Perimeter 3 96 ft
Top Width 3 00 ft
Bentley Systems, Inc. Haestad Methods ScBuMteyCSIitsMaster VSi (SELECTsenes 1) [OS 11.01.03]
12/20/2012 5:30 47 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page lof 1
CITY OF
CARLSBAD
PLUMBING,
ELECTRICAL,
MECHANICAL
WORKSHEET
B-18
Development Services
Building Department
1635 Faraday Avenue
760-602-2719
www carlsbadca.gov
Project Address: ( 6€27d3C/H^ ^^iS^^)^^'''^''
Information provided below refers to worb being done on the above mentioned permit only.
This form must be completed and returned to the Buildinq Department before the permit can be issued.
Building Dept. Fax: (760) 602-8558
Number of new or relocated fixtures, traps, or fioor drains
New building sewer line? Yes No
Number of new roof drains?
Install/alter water line?
Number of new water heaters?
Number of new, relocated or replaced gas outlets?
Number of new hose bibs?
Upgrade existing panel? Yes No ^
From Amps to Amps
Number of new panels or subpanels?
Single Phase Number of new amperes 16
Three Phase Number of new amperes
Three Phase 480 Number of new amperes
Remodel (relocate existing outlets/switches or add outlets/switches)?
Yes X No
Number of new furnaces, A/C, or heat pumps?
New or relocated duct worh? Yes No
Number of new fireplaces?
Number of new exhaust fans?
Relocate/install vent?
Number of new exhaust hoods?
Number of new boilers or compressors? Number of HP
B-18 Page 1 of 1 Rev 03/09
CITY OF
CARLSBAD
STORM WATER COMPLIANCE FORM
TIER 1 CONSTRUCTION SWPPP
E-29
Development Services
Land Development Engineering
1635 Faraday Avenue
760-602-2750
www carlsbadca gov
STORIVI WATER COMPLIANCE CERTIFICATE
My project is not in a category of permit types exempt from the Construction
SWPPP requirements
My project is not located inside or withm 200 feet of an environmentally
sensitive area with a significant potential for contributing pollutants to nearby
receiving waters by way of storm water runoff or non-storm water
discharge(s)
My project does not require a grading plan pursuant to the Carlsbad
Grading Ordinance (Chapter 15 16 of the Carlsbad Municipal Code)
My project will not result in 2,500 square feet or more of soils disturbance
including any associated construction staging, stockpiling, pavement
removal, equipment storage, refueling and maintenance areas that meets
one or more ofthe additional following cntena
• located within 200 feet of an environmentally sensitive area or the
Pacific Ocean, and/or,
• disturbed area is located on a slope with a grade at or exceeding 5
honzontal to 1 vertical, and/or
• disturbed area is located along or within 30 feet of a storm dram inlet, an
open drainage channel or watercourse, and/or
• construction will be initiated dunng the rainy season or will extend into
the rainy season (Oct 1 through Apnl 30)
I CERTIFY TO THE BEST OF MY KNOWLEDGE THAT ALL OF THE ABOVE
CHECKED STATEMENTS ARE TRUE AND CORRECT. I AM SUBMITTING
FOR CITY APPROVAL A TIER 1 CONSTRUCTION SWPPP PREPARED IN
ACCORDANCE WITH THE REQUIREMENTS OF CITY STANDARDS
1 UNDERSTAND AND ACKNOWLEDGE THAT I MUST (1) IMPLEMENT BEST
MANAGEMENT PRACTICES (BMPS) DURING CONSTRUCTION ACTIVITIES
TO THE MAXIMUM EXTENT PRACTICABLE TO MINIMIZE THE
MOBILIZATION OF POLLUTANTS SUCH AS SEDIMENT AND TO MINIMIZE
THE EXPOSURE OF STORM WATER TO CONSTRUCTION RELATED
POLLUTANTS, AND, (2) ADHERE TO, AND AT ALL TIMES, COMPLY WITH
THIS CITY APPROVED TIER 1 CONSTRUCTION SWPPP THROUGHOUT THE
DURATION OF THE CONSTRUCTION ACTIVITIES UNTIL THE
CONSTRUCTION WORK IS COMPLETE AND APPROVED BY THE CITY OF
CARLSBAD
OWNERte)/pWNB?n'S AGENT NAME (PRINT)
0WNERT;S)/0WNER'S AGENT NAME (SIGNATURE) DATE
STORM WATER POLLUTION PREVENTION NOTES
1 ALL NECESSARY EQUIPMENT AND MATERIALS
SHALL BE AVAILABLE ON SITE TO FACILITATE
RAPID INSTALLATION OF EROSION AND
SEDIMENT CONTROL BMPS WHEN RAIN IS
EMINENT
2 THE OWNER/CONTRACTOR SHALL RESTORE
ALL EROSION CONTROL DEVICES TO
WORKING ORDER TO THE SATISFACTION OF
THE CITY ENGINEER AFTER EACH RUN-OFF
PRODUCING RAINFALL
3 THE OWNER/CONTRACTOR SHALL INSTALL
ADDITIONAL EROSION CONTROL MEASURES
AS MAY BE REQUIRED BY THE CITY
ENGINEERING OR BUILDING INSPECTOR DUE
TO UNCOMPLETED GRADING OPERATIONS OR
UNFORESEEN CIRCUMSTANCES WHICH MAY
ARISE
4 ALL REMOVABLE PROTECTIVE DEVICES SHALL
BE IN PLACE AT THE END OF EACH WORKING
DAY WHEN THE FIVE (5) DAY RAIN
PROBABILITY FORECAST EXCEEDS FORTY
PERCENT (40%) SILT AND OTHER DEBRIS
SHALL BE REMOVED AFTER EACH RAINFALL
5 ALL GRAVEL BAGS SHALL BE BURLAP TYPE
WITH 3/4 INCH MINIMUM AGGREGATE
6 ADEQUATE EROSION AND SEDIMENT
CONTROL AND PERIMETER PROTECTION BEST
MANAGEMENT PRACTICE MEASURES MUST BE
INSTALLED AND MAINTAINED
SPECIAL NOTES
PROJECT INFORMATION
Site Address
Assessor's Parcel Number
Project ID
Construction Pemiit No
Estimated Constmction Start Date
Project Duration Months
Emergency Contact
Name
ency Contact
m€/i^
24 hour Phone "7l^Q Q^H^
Perceived Threat to Stomi Water Quality
,/ledium
O Low
If medium box is checked, must attach a site plan
sheet showing proposed work area and location
of proposed structural BMPs
For City Use Only
CITY OF CARLSBAD
STANDARD TIER 1 SWPPP
Approved By
Date
E-29 Page 1 of 3 REV 4/30/10
CITY OF
CARLSBAD
STORM WATER
COMPLIANCE
ASSESSMENT
B-24
Development Services
Building Division
1635 Faraday Avenue
760-602-2719
www carlsbadca gov
am applying to the City of Carlsbad for the following type(s) of construction pernnit:
El Building Pernnit • Right-of-Way Permit
• My project is categorically EXEMPT from
the requirement to prepare a storm water
pollution prevention plan (SWPPP) because it
only requires issuance of one or more of the
following permit types:
Electrical
Fire Additional
Fire Alarm
Fixed Systems
Mechanical
Mobile Home
Plumbing
Patio/Deck
Re-Roofing
Sign
Spa-Factory
Sprinkler
Water Discharge
Project Storm Water Threat Assessment Criteria*
No T/jreaMssessmenf Criteria
• My project qualifies as NO THREAT and is exempt from the requirement to prepare a storm water pollution prevention plan (SWPPP) because
it meets the "no threat" assessment cntena on the City's Project Threat Assessment Worksheet for Determination of Construction SWPPP Tier
Level My project does not meet any of the High, Moderate or Low Threat criteria described below
Tierl - Low Ttireat Assessment Criteria
• My project does not meet any of the Significant or Moderate Threat cntena, is not an exempt permit type (See list above) and the project
meets one or more of the following cntena
• Results in some soil disturbance, and/or
• Includes outdoor construction activities (such as saw cutting, equipment washing, matenal stockpiling, vehicle fueling, waste stockpiling)
r^er 2 - iWoderafe Threaf Assessment Criteria
A)l project does not meet any of the Significant Threat assessment Cntena described below and meets one or more of the following cntena
' Project requires a grading plan pursuant to the Carlsbad Grading Ordinance (Chapter 15 16 ofthe Carlsbad Municipal Code), or,
• Project will result in 2,500 square feet or more of soils disturbance including any associated construction staging, stockpiling, pavement
removal, equipment storage, refueling and maintenance areas and project meets one or more of the additional following cntena
• Located within 200 feet of an environmentally sensitive area or the Pacific Ocean, and/or
• Disturbed area is located on a slope with a grade at or exceeding 5 honzontal to 1 vertical, and/or
• Disturbed area is located along or within 30 feet of a storm dram inlet, an open drainage channel or watercourse, and/or
• Constmction will be initiated dunng the rainy season or will extend into the rainy season (Oct 1 through April 30)
Tier 3 - Significant Threat Assessment Criteria
• My project includes cleanng, grading or other disturbances to the ground resulting in soil disturbance totaling one or more acres including any
associated construction staging, equipment storage, stockpiling, pavement removal, refueling and maintenance areas and/or
• My project is part of a phased development plan that will cumulatively result in soil disturbance totaling one or more acres including any
associated construction staging, equipment storage, refueling and maintenance areas or,
• My project is located inside or within 200 feet of an environmentally sensitive area (see City ESA Proximity map) and has a significant
potential for contnbuting pollutants to nearby receiving waters by way of storm water runoff or non-storm water discharge(s)
ijer z -
I certify to t/ie best of my knowledge that the above
checlted statements are true and correct. I understand
and acknowledge that even though this project does
not require preparation of a construction SWPP, I must
still adhere to, and at all times during construction
activities for the permit type(s) check above comply
with the storm water best management practices
pursuant to Title 15 ofthe Carisbad Municipal Code
and to Citv Standards.
'The City Engineer may authorize minor vanances from the Storm
Water Threat Assessment Cntena in special circumstances where it
can be shown that a lesser or higher Construction SWPPP Tier Level is
warranted
B-24 Rev 03/09
^ CITY OF
CARLSBAD
STORM WATER
COMPLIANCE
ASSESSMENT
B-24
Development Services
Building Division
1635 Faraday Avenue
760-602-2719
www carlsbadca gov
I am applying to the City of Carlsbad for the following type(s) of construction permit:
• Building Permit • Right-of-Way Permit
• IVly project is categorically EXEMPT from
the requirement to prepare a storm water
pollution prevention plan (SWPPP) because it
only requires issuance of one or more of the
following permit types:
Electrical
Fire Additional
Fire Alarm
Fixed Systems
Mechanical
Mobile Home
Plumbing
Patio/Deck
Photo Voltaic
Re-Roofing
Sign
Spa-Factory
Spnnkler
Water Discharge
Project Storm Water Threat Assessment Criteria*
No ThreaMssessmenf Criteria
• My project qualifies as NO THREAT and is exempt from the requirement to prepare a storm water pollution prevention plan (SWPPP) because
it meets the "no threat" assessment criteria on the City's Project Threat Assessment Worksheet for Determination of Construction SWPPP Tier
Level My project does not meet any of the High, Moderate or Low Threat cntena descnbed below
Tierl •
•
Tier 2 •
S4
7/er3 •
•
Low T/ireaf/^ssess/nenf Criteria
My project does not meet any of the Significant or Moderate Threat cnteria, is not an exempt permit type (See list above) and the project
meets one or more of the following cntena
• Results in some soil disturbance, and/or
• Includes outdoor construction activities (such as saw cutting, equipment washing, matenal stockpiling, vehicle fueling, waste stockpiling)
Moderafe Threaf Assessmenf Criteria
My project does not meet any of the Significant Threat assessment Cntena described below and meets one or more of the following cntena
• Project requires a grading plan pursuant to the Carlsbad Grading Ordinance (Chapter 15 16 of the Carlsbad Municipal Code), or,
• Project will result in 2,500 square feet or more of soils disturbance including any associated construction staging, stockpiling, pavement
removal, equipment storage, refueling and maintenance areas and project meets one or more of the additional following cntena
• Located within 200 feet of an environmentally sensitive area or the Pacific Ocean, and/or
• Disturbed area is located on a slope with a grade at or exceeding 5 honzontal to 1 vertical, and/or
• Disturbed area is located along or within 30 feet of a storm dram inlet, an open drainage channel or watercourse, and/or
• Construction will be initiated during the rainy season or will extend into the rainy season (Oct 1 through Apnl 30)
Significant Threat Assessment Criteria
My project includes clearing, grading or other disturbances to the ground resulting in soil disturbance totaling one or more acres including any
associated construction staging, equipment storage, stockpiling, pavement removal, refueling and maintenance areas and/or
My project is part of a phased development plan that will cumulatively result m soil disturbance totaling one or more acres including any
associated construction staging, equipment storage, refueling and maintenance areas or.
My project is located inside or within 200 feet of an environmentally sensitive area (see City ESA Proximity map) and has a significant
potential for contnbuting pollutants to nearby receiving waters by way of storm water runoff or non-storm water discharge(s)
/ certify to the best of my knowledge that the above
checked statements are true and correct I understand
and acknowledge that even though this project does
not require preparation of a construction SWPP, I must
still adhere to, and at all times during construction
activities for the permit type(sj check above comply
with the storm water best management practices
pursuant to Title 15 ofthe Carlsbad Municipal Code
and to City Standards.
'The City Engineer may authorize minor vanances from the Storm
Water Threat Assessment Criteria in special circumstances where it
can be shown that a lesser or higher Construction SWPPP Tier Level is
warranted
Project Address Assessor Parcel No
sr/Qwner's Authorized Aoest Name I Title T* Owner/Q.wner's Authorized Aoest Name
City Concurrence
• YES QNO
Date
Date
Project ID.
B-24 Page 1 of 1 Rev 03/09
CB 122746 1 LEGOLAND DR
LEGOLAND
INSTALL 2 PREFAB TOLL BOOTHS AT PARKING LOT
nnaiinsp Approved Date By
BUILDING
PLANNING
ENGINEERING / / -
FIRE Expedite? CuJ
AFS Ctieckedby —
HazMat
APCD
Health
Forms/Fees sent Reed Due? By
Encina
•
Y N
Fire —^—. Y N
HazHealthAPCD Y N
PE&M Y N
School Y N
Sewer Y N
Stormwater /^/^///^ Y N
Special Inspection Y N
CFD Y N
LandUse Density ImpArea FY Annex Factor
PFF Y N
Comments Date Date Date Date
Building
Planning
Engineering
Fire
1
Need?
• Done
• Done
• Done
• Done
• Done