HomeMy WebLinkAboutCT 14-09; UPTOWN BRESSI RANCH; LIME/CEMENT-TREATED PAVEMENT SECTION RECOMMENDATIONS; 2017-07-21RECEIVED.
Shea Homes JUL 212017
9990 Mesa Rim Road -
San Diego, California 92121 LAND DEVELOPMENT
ENGNEERI.NG .
Attention: Mr. Greg Ponce
Subject LIME/CEMENT-TREATED PAVEMENT SECTION RECOMMENDATIONS
UPTOWN BRESSI RANCH RETAIL
LOTS 29 THROUGH 3
CARLSBAD, CALIFORNIA
2
Reference Update Report and Chazge of Geotechnical Engineei of Record Bressi Ranch Lots 29
through 32 Carlsbad California prepared by Geocon Incorporated, dated April 24,
2017.
Dear Mr. Ponce:
In accordance with your request, we.have performed supplemental geotechnical services to evaluate
alternative pavement recoiimendatins for the roadways at the subject site Based on recent laboratory
testing and our experience with similar soil, ye expect in-situ R:values to range between 0 and 10
Based on recent discussions regarding alternative pavement designs, 've understand that a lime or
cement-treated pavement section is bbing c\onsidered as an alternative to a conventional pavement
section considering the low sub grade support characteristics
The scope of our services included obtaining representative subgrade soil samples and performing
laboratory tests to aid in determming the appropriate lime or cement-treated pavement qesign sfibgrade
soils in the area are predominately clayey sands, sandy clays and clays and typically exhibit relatively
low R-Value characteristics Laboratory soluble sulfate content testing was performed in accordance
with California Test Method 417 and the test results are presented in Table I These tests were
perfohiied to.-determine the feasibility of using lime or cement as an additive to stabilize the existing
clayey subgrade soils
TABLEI
SUMMARY OF LABORATORY WATER-SOLUBLE SULFATE CONTENT TEST RESULTS
CALIFORNIA TEST METHOD 417
e N Samplo Water-Soluble Sulfate Content (%) 2016 CRC Classification
S 1 0 063 Not Aplicable (SO)
S_`2 .0.100_"Moderate (S1)(
The laboratory tests indicate that the subgrade soils have a water-soluble sulfate content of less than
5,000 parts per million (ppm). Therefore, using lime or cement as an additive to the clayey soils is
feasible.
Resistance Value (R-Value) tests were performed on subgrade soils utilizing lime and cement as an
additive. The amount of lime or cement content needed to stabilize the clayey subgrade soil was
determined by the Texas Method, which consists of performing a series of plasticity index (PT) tests at
different lime and cement contents until the P1 generally stabilizes at its lower bound. The test results
are presented in Tables II and III. Based on the results of our testing, we recommend a lime or cement
content of approximately 7 percent by weight or greater. R-value testing was performed at quick lime
and cement contents of 7 percent to evaluate the treated R-Value characteristics. The laboratory R-
value, tests results are presented in Table IV.
TABLE II
SUMMARY OF LABORATORY PLASTICITY INDEX VS. QUICK LIME CONTENT TEST RESULTS
ASTMD43I8
Sample Plasticity Index
0% 2% 4% 6% 8%
S-i ' 36- 37 22 9 NP
S-2 33 26 12 12 NP
NP = Non-Plastic
TABLE III
SUMMARY OF LABORATORY PLASTICITY INDEX VS. CEMENT CONTENT TEST RESULTS
ASTMD43I8
Sample Plasticity Index
0% 2% 4% 6% 8% 10%
S-I --- 34 26 26 18 NP
S-2 . 32 30 ' 23 24 27 NP
NP = Non-Plastic
The R-Value samples treated with lime or cement contents of 7 percent by dry weight yielded R-
Values ranging between 51 and 57. Laboratory R-Value tests were performed in accordance with
ASTM D 2844-07 (California Test Method No. 301) and the test results are presented in Table IV.
/
TABLE IV
SUMMARY OF LABORATORY R-VALUE TEST RESULTS
CALIFORNIA TEST METHOD 301
Sample No. Geologic Unit No Additive
R-Value
.7% Quick Lime by
11-Value
7% Cement by Dry
Dry Weight ' Weight
S-i Santiago Formation . --- --- . 51
S-2 ' Santiago Formation --- . 57
Project No. G2108-32-01 . . . -2- . ' . July 21,017
Traffic indices ranging between 4.5 and 7.0 were used to evaluate the pavement sections presented in
Table V. Based on the above information and laboratory testing, we recommend the lime or cement-
treated pavement sections indicated on Table V. Pavement section presented below utilized the City of
Carlsbad's Standard Drawing GS-1 7, Structural Section of Streets and Alleys. These recommended
pavement recommendations should be considered preliminary with final sections to be approved by
the City, of Carlsbad.
Based on the above information, the following pavement recommendations are proyided in Table V.
An average R-Value of 50 with 'a lime or cement content of 7 percent by weight was used for design
purposes.
TABLE
PAVEMENT SECTION RECOMMENDATIONS
QUICK-LIME OR CEMENT TREATED SUBGRADE SOILS AT 7% BY DRY WEIGHT
Location Traffic
In
' R-Value
Asphalt
Concrete
(inches)
Aggregate
Base (inches)
Depth of Lime-
Treated Subgrade'
- Soil (inches)
Cul-de-Sac 4.5 50 4 4 12 -
Local Street 5.0 50 4 .- 4 12
Collector 6.0 50 4 6 12
Light Industrial 7.0 50 4 6. 12
We recommend that the lime or cement-treated subgrade and aggregate base be moisture conditioned,
and compacted to a minimum of 95 percent relative compaction based on ASTM D 1557 Asphalt
concrete should be compacted to at least 95 percent of the laboratory Hveem density in accordance
- with ASTM D 2726
The lime/cement-treated subgrade soils should be placed and compacted in accordance with the
recommendations contained in Section 27 of the Caltrans Manual and Section 301 of the Standard
SpecifIcations for Public Works Construction
The subgrade stabilization should be observed and tested by Geocon Incorporated to verify that the
project specifications discussed above have been met and the typical stabilization procedures provided
in Section 27 of the Caltrans Manual and Section 301 of the Standard SpecifIcations for Public Works
Construction were achieved
The performance of pavement is highly dependent on providing positive surface drainage away from
the edge of the pavement. Ponding of water on or adjacent to the pavement will likelyr. result in
pavement distress and subgrade failUre. To reduce the occu'rrence of such situations,. 'we recommend
that a minimum drainage gradient of one percent be maintained for pavement surfaces Drainage from
landscaped areas' should be directed to controlled drainage structures. It is very important to' prevent
any ponding and/or excessive landscape irrigation within open areas adjacent to the curb/gutter areas
FCC PAVEMENT RECOMMENDATIONS
A rigid Portland cement concrete (PCC) pavement section should be placed in driveway entrance
'aprons and trash bin loading/storage 'areas. The concrete pad for trash truck areas should be large
enough such that the truck wheels will be positioned on the concrete during loading We calculated the
Project No. G2108-2-0I :' ' ' -3 u1y 21, 2017
I
rigid pavement section in general conformance with the procedure recommended by the American
Concrete Institute report ACI 330R-08 Guide for Design and Construction of Concrete Parking Lots
using the parameters presented in Table VI. The parameters preented below are,, considered
appropriate considering a lime/cement treated subgrade soils exhibiting laboratory R-values of 50 or
greater.
TABLE VI
RIGID PAVEMENT DESIGN PARAMETERS
Design Parameter Design Value
Modulus of subgrade reaction, k 200 pci
Modulus of rupture for concrete, MR 500 psi
Traffic Category, TC A and C
Average daily truck traffic, ADTF 10 and 100
Based on the criteria presented herein, the PCC pavement sections should have a minimum thickness
as presented in Table VII'.
TABLE VII
RIGID PAVEMENT RECOMMENDATIONS
Location . Portland Cement Concrete (inches)
Automobile Parking Areas (TC=A) 5.0
Heavy Truck and Fire Lane Areas (TCC) 6.5
The PCC pavement should be placed over subgrade soil that is compacted to a dry density of at least
95 percent of the laboratory maximum dry, density near to slightly above optimum moisture content.
This pavement section is based on a minimum concrete compressive strength of approximately 3,000
psi (pounds per square inch).
A thickened edge or integral curb should be constructed on the outside of concrete slabs subjected to
wheel loads. The thickened edge should, be 1.2 times the slab thickness or a minimum thickness of
2 inches, whichever results in a thicker edge, and taper back to the recommended slab thickness 4 feet
behind the face of the slab (e.g.,. a 7-inch-thick slab would have a 9-inch-thick edge). Reinforcing steel
will not be necessary within the concrete for geotechnical purposes with the possible exception of
dowels at construction joints as discussed herein. . . .
To control the location .and spread of concrete shrinkage cracks, crack-control joints (weakened plane
joints)' should be included in the design of the concrete pavement slab. Crack-control joints should not
exceed 30 times the slab thickness with a maximum spaCing of 1,2.5 feet and 15'feet for the 5.5- and 7-
inch-thick slabs, respectively, and should be sealed with an 'appropriate sealant to prevent the
migration of water through the control joint to the subgrade materials. The depth of the, crack-control'
joints, should be determined by the referenced ACI report.
Concrete curb/gutter should be placed on soil subgrade compacted' to a dry. density of at least
90 percent of the laboratory maximum dry density near to slightly above optimum moisture content.
Cross-gutters should be placed on subgrade soil compacted to a dry density .of'at least 95 percent of
Project No:'G2108-32-01 ' . ' . ' -4- . . July 21, 2017