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1372 CYNTHIA LN; ; CB081501; Permit
10-20-2008 City of Carlsbad 1635 Faraday Av Carlsbad, CA 92008 Electrical Permit Permit No CB081501 Building Inspection Request Line (760) 602-2725 Job Address 1372 CYNTHIA LN CBAD Permit Type ELEC Status ISSUED Parcel No 1562315600 Lot# 0 Applied 08/05/2008 Entered By RMA Reference* Plan Approved 10/20/2008 PC# Issued 10/20/2008 Project Title WATT RES-PHOTO VOLTAIC SYSTEM Inspect Area W/ROOF MOUNTED COLLECTORS & NO STORAGE BATTERIES Applicant WATT DAVID&GINA 1372CYNTHIALN CARLSBAD CA 92008 Owner WATT DAVID&GINA 1372CYNTHIALN CARLSBAD CA 92008 Electric Issue Fee Single Phase per AMP Three Phase per AMP Three Phase 480 Per AMP Remodel/Alteration per AMP Remodel Fee Temporary Service Fee Test Meter Fee Other Electrical Fees Additional Fees 0 0 0 0 $1000 $000 $000 $000 $000 $000 $000 $000 $11000 $000 TOTAL PERMIT FEES $12000 Total Fees $12000 Total Payments To Date $12000 Balance Due $000 .IN STORAGE .ATTACHED Inspector Clearance NOTICE Please take NOTICE that approval of your project includes the "imposition" of fSes, dedications, reservations, or other exactions hereafter collectively referred to as "fees/exactions" You have 90 days from the date this permit was issued to protest imposition of these fees/exactions If you protest them, you must follow the protest procedures set forth in Government 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 proiect NOR DOES IT APPLY to any fees/exactions of which you have previously been given a NOTICE similar to this, or as to which the statute of limitations nas previously otherwise expired I City of Carlsbad 1635 Faraday Ave , Carlsbad, CA 92008 760-602-2717 / 27l8 / 2719 Fax 760-602-8558 www carlsbadca gov Building Permit Application Plan Check No. Est. Value Plan Ck. Deposit JOB ADDRESS 4 1 "1 1 C_W*«-V'k' L*A^ CT/PROJECT #LOT#PHASE ## OF UNITS # BEDROOMS SUITE#/SPACE#/UNIT# # BATHROOMS APN ' / O<^ " ^3) ~^V ~ $& TENANT BUSINESS NAME CONSTR TYPE OCC GROUP DESCRIPTION OF WORK Include Square Feet of Affected Area(s) EXISTING USE PROPOSED USE GARAGE (SF)PATIOS (SF)DECKS (SF)FIREPLACE YES D #NO D AIR CONDITIONING YES D NO D FIRE SPRINKLERS YES a NOD CONTACT NAME (If Different Fom Applicant)£) > \APPLICANT NAME ADDRESS CITY STATE ZIP ""a/Is!**STATU 2'P PHONE FAX PHONE FAX EMAIL EMAIL PROPERTY OWNER NAME CONTRACTOR BUS NAME ADDRESS ~Cm ADDRESS STATE ZIP CITY ZIP EMAIL FAX PHONE FAX EMAIL ARCH/DESIGNER NAME & ADDRESS STATE LIC #STATE LIC # 1 CITY BUS LIC * ^^^^^^^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^^^^j^^/^^^^^^^^^^^^^^^^^^^^^^^^^-^-^^^^^^^^^.^.^^^^^^^^^^^^^^^^^^^^^^^^^ (Sec 70315 Business and Professions Code Any City or County which requires a permit to construct, alter, improve demolish or repair any structure, pnor 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 70315 by any applicant for a permit subjects the applicant to a civil penalty of not more than five hundred dollars {$500}) Workers' Compensation Declaration / hereby affirm under penalty of perjury one of the following declarations L~) 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 C!J I have and will maintain workers' compensation, as required by Section 3700 of the Labor Code, for 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 sgchoirneed not be completed if the permit is for one hundred dollars ($100) or less ^^Certificate of Exemption I certify that in the performance of the work for which this permit is issued I shall not employ any person in any manner so as to become subject to the Workers Compensation Laws of California WARNING Failure to secure workers' compensation coverage is unlawjulraticffhall subject an employer to criminal penalties and civil fines up to one hundred thousand dollars (&100,000), in addition to the cost of compensation, damages as,proyide3for in Section SJWrjiEtnVCabor code, interest and attorney's fees J&$ CONTRACTOR SIGNATURE* I hereby affirm that I am exempt from Contractor's License Law for the following reason O I as owner of the property or my employees with wages as their sole compensation will do the work and the structure is not intended or offered for sale (Sec 7044 Business and Professions Code The Contrxtor's 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 the burden of proving that he did not build or improve for the purpose of sale) O I as owner of the property, am exclusively contracting with licensed contractors to construct the project (Sec 7044, Business and Professions Code The Contractor s License Law does not apply to an owner of property who builds or improves thereon and contracts for such projects with contractor(s) licensed pursuant to the Contractor's License Law) D ) am exempt under Section Business and Professions Code for this reason 1 I personally plan to provide the major labor and materials for construction of the proposed property improvement D Yes O No 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 supervise 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) ^PROPERTY OWNER SIGNATURE DATE '"" a " " Is the applicant or future building occupant required to submit a business plan acutely hazardous materials registration form or risk management and prevention program under Sections 25505 25533 or 25534 of the Presley-Tanner Hazardous Substance Account Acf a Yes a No Is the applicant or future building occupant required to obtain a permit from the air pollution control district or air quality management district' d Yes d No Is the facility to be constructed within 1,000 feet of the outer boundary of a school site' O Yes a No IF ANY OF THE ANSWERS ARE YES, / 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 I certify that I have read the application and state that the above information is correct and that the information on the plans is accurate I agree to comply with all City ordinances and State laws relating to building construction I hereby authorize representative of the City of Cartsbad to enter upon the above mentioned property for inspection purposes 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 permit is required for excavations over 5'0' deep and demolition or construction of structures over 3 stones in height EXPIRATION Every permit issued by the Building Official under the provisions of Ihis Code shall expire by limitation and become null and void if the building or work authonzed by such permit is not commenced within 180 days from the date of such permit or if Ihebujrjing or wort authonzed by spctf permit is suspended or abandoned at any tone after the work is commenced for a penod of 180 days (Section 106 4 4 Uniform Building Code) ^APPLICANT'S SIGNATURE ~s^ -' /I //fvU \ DATE 8/V/09 City of Carlsbad Bldg Inspection Request For 01/27/2009 Permit* CB081501 Title WATT RES-PHOTO VOLTAIC SYSTEM Inspector Assignment Description W/ROOF MOUNTED COLLECTORS & NO STORAGE BATTERIES Type ELEC Sub Type Job Address 1372 CYNTHIA LN Suite Lot 0 Location OWNER WATT DAVID&GINA Owner WATT DAVID&GINA Remarks PV SYSTEM Phone 7604199808 Inspector Total Time CD Description 34 Rough Electric Act ^ Comments Requested By DAVE WAT Entered By CHRISTINE Comments/Notices/Holds Associated PCRs/CVs Original PC# Inspection History Date Description Act Insp Comments EsGil Corporation In (Partnership with (government for <Kui[d~ing Safety DATE October 10, 2008 JURISDICTION Carlsbad PLAN CHECK NO 08-1501 SET III PROJECT ADDRESS 1372 Cynthia Lane PROJECT NAME Watt 3300 Solar Photovoltaic The plans transmitted herewith have been corrected where necessary and substantially comply with the jurisdiction's building codes XI 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 The plans transmitted herewith have significant deficiencies identified on the enclosed check list and should be corrected and resubmitted for a complete recheck The check list transmitted herewith is for your information The plans are being held at Esgil Corporation until corrected plans are submitted for recheck The applicant's copy of the check list is enclosed for the jurisdiction to forward to the applicant contact person The applicant's copy of the check list has been sent to X] Esgil Corporation staff did not advise the applicant that the plan check has been completed Esgil Corporation staff did advise the applicant that the plan check has been completed Person contacted Telephone # Date contacted (by ) Fax # unk Mail Telephone Fax In Person XI REMARKS Revised single line diagram included in packet By Eric Jensen Enclosures Esgil Corporation D GA D MB D EJ D PC 10/6 9320 Chesapeake Drive, Suite 208 ^ San Diego, California 92123 ^ (858)560-1468 + Fax (858) 560-1576 EsGii Corporation In (Partners/lip with government for <Buifd~ing Safety DATE September 15, 2O08 JURISDICTION Carlsbad a PLAN REVIEWER a FILE PLAN CHECK NO 08-1501 SET II PROJECT ADDRESS 1372 Cynthia Lane PROJECT NAME Watt 330O Solar Photovoltaic The plans transmitted herewith have been corrected where necessary and substantially comply with the jurisdiction's building 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 The plans transmitted herewith have significant deficiencies identified on the enclosed check list and should be corrected and resubmitted for a complete recheck XI The check list transmitted herewith is for your information The plans are being held at Esgil Corporation until corrected plans are submitted for recheck The applicant's copy of the check list is enclosed for the jurisdiction to forward to the applicant contact person XI The applicant's copy of the check list has been sent to Sears Construction 1387 Cynthia Lane Carlsbad CA 92008 Esgil Corporation staff did not advise the applicant that the plan check has been completed XI Esgil Corporation staff did advise the applicant that the plan check has been completed Person contacted / Telephone # 760 720-9548 Date contacted ^l^/0 \by$$ Fax # unk Mail^ Telephone Fax In Person REMARKS By Eric Jensen Enclosures Esgil Corporation - D GA D MB D EJ D PC 9/9/2008 9320 Chesapeake Drive, Suite 208 + San Diego, California 92123 * (858)560-1468 * Fax (858) 560-1576 Carlsbad 08-1501 September 15, 2008 GENERAL PLAN CORRECTION LIST JURISDICTION Carlsbad PLAN CHECK NO 08-15O1 PROJECT ADDRESS 1372 Cynthia Lane DATE PLAN RECEIVED BY DATE REVIEW COMPLETED ESGIL CORPORATION 9/9/2008 September 15, 2008 REVIEWED BY Eric Jensen FOREWORD (PLEASE READ): This plan review is limited to the technical requirements contained in the International Building Code, Uniform Plumbing Code, Uniform Mechanical Code, National Electrical Code and state laws regulating energy conservation, noise attenuation and disabled access This plan review is based on regulations enforced by the Building Department You may have other corrections based on laws and ordinances enforced by the Planning Department, Engineering Department or other departments The following items listed need clarification, modification or change All items must be satisfied before the plans will be in conformance with the cited codes and regulations The approval of the plans does not permit the violation of any state, county or city law • Please make all corrections and submit two new complete sets of prints to ESGIL CORPORATION • To facilitate recheckmg, please identify, next to each item, the sheet of the plans upon which each correction on this sheet has been made and return this sheet with the revised plans • Please indicate here if any changes have been made to the plans that are not a result of corrections from this list If there are other changes, please briefly describe them and where they are located on the plans Have changes been made not resulting from this list? a Yes a No Carlabad 08-1501 ' September 15, 2OO8 ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) PLAN REVIEWER: Eric Jensen ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) 1 Include a site specific single line diagram The submitted single line is boilerplate and does not address this specific installation—Include Conductor sizing, number of strings, series DC fusing, and calculations (current, voltage, etc ) • Include the maximum series fuse sizing on the DC side (10 ampere/see module specifications) • Clarify the wiring design on the DC side From the pull box (3)+ & (3)- the conduit description changes to (3) X #8, (1) X #10 If the "pull box" is a combiner box with the 600 volt 10 ampere series rated fuse only (2) conductors (+ & -) plus the equipment ground would be shown in the conduit If the series fusing is an integral part of the inverter or the DC fused disconnect there would be (6) conductors plus the equipment ground in the conduit (See above italicized comment A maximum 10 ampere per series string fuse protection is required for module protection) • Provide a contact phone number and/or fax number to ease communication The phone number provided did not answer (760 720-9548) • The jurisdiction has contracted with Esgil Corporation located at 9320 Chesapeake Drive, Suite 208, San Diego, California 92123, telephone number of 858/560-1468, to perform the plan review for your project If you have any questions regarding these plan review items, please contact Eric Jensen at Esgil Corporation Thank you ad O8-1501 .ember 15, 2008 ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) REVIEWER: Eric Jensen ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) ^ Delude a site specific single line diagram The submitted single line is boilerplate and dees not address this specific installation—Include Conductor sizing, number of strings, series DC fusing, and calculations (current, voltage, etc ) • Include the maximum series fuse sizing on the DC side (10 ampere/see module specifications) • Clarify the wiring design on the DC side From the pull box (3)+ & (3)- the conduit description changes to (3) X #8, (1) X#10 If the "pull box" is a combiner box with the 600 volt 10 ampere series rated fuse only (2) conductors (+ & -) plus the equipment ground would be shown in the conduit If the series fusing is an integral part of the inverter or the DC fused disconnect there would be (6) conductors plus the equipment ground in the conduit (See above italicized comment A maximum 10 ampere per series string fuse protection is required for module protection) • Provide a contact phone number and/or fax number to ease communication The phone number provided did not answer (760 720-9548) • The jurisdiction has contracted with Esgil Corporation located at 9320 Chesapeake Drive, Suite 208, San Diego, California 92123, telephone number of 858/560-1468, to perform the plan review for your project If you have any questions regarding these plan review items, please contact Eric Jensen at Esgil Corporation Thank you 7 7^0 -3,70 -S-75T-Z- __— EsGil Corporation In Partners/tip -witfi government for <Buififing Safety DATE September 15, 2008 JURISDICTION Carlsbad PLAN CHECK NO 08-1501 SET II PROJECT ADDRESS 1372 Cynthia Lane PROJECT NAME Watt 33OO Solar Photovoltaic PLAN REVIEWER a FILE The plans transmitted herewith have been corrected where necessary and substantially comply with the jurisdiction's building 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 The plans transmitted herewith have significant deficiencies identified on the enclosed check list and should be corrected and resubmitted for a complete recheck XI The check list transmitted herewith is for your information The plans are being held at Esgil Corporation until corrected plans are submitted for recheck The applicant's copy of the check list is enclosed for the jurisdiction to forward to the applicant contact person The applicant's copy of the check list has been sent to Sears Construction 1387 Cynthia Lane Carlsbad CA 92008 Esgil Corporation staff did not advise the applicant that the plan check has been completed Esgil Corporation staff did advise the applicant that the plan check has been completed Person contacted / Telephone # 760 720-9548 Date contacted //^/ (byx^re? Fax # unk Maiiy^ Telephone Fax In Person REMARKS By Eric Jensen Enclosures Esgil Corporation n GA n MB n EJ n PC 9/9/2003 9320 Chesapeake Dme, Suite 208 + San Diego, California 92123 + (858)560-1468 4 Fax (S5S) 560-1576 EsGil Corporation In (Partnership with government for <BuiCdmg Safety DATE August 14, 2008 a AEeUGANT cTETjuRis J> JURISDICTION Carlsbad a PLAN REVIEWER a FILE PLAN CHECK NO O8-15O1 SET I PROJECT ADDRESS 1372 Cynthia Lane PROJECT NAME Watt 3300 Solar Photovoltaic The plans transmitted herewith have been corrected where necessary and substantially comply with the jurisdiction's building 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 The plans transmitted herewith have significant deficiencies identified on the enclosed check list and should be corrected and resubmitted for a complete recheck The check list transmitted herewith is for your information The plans are being held at Esgil Corporation until corrected plans are submitted for recheck The applicant's copy of the check list is enclosed for the jurisdiction to forward to the applicant contact person XI The applicant's copy of the check list has been sent to Sears Construction 1387 Cynthia Lane Carlsbad CA 92008 Esgil Corporation staff did not advise the applicant that the plan check has been completed XI Esgil Corporation staff did advise the applicant that the plan check has been completed Person contacted / , Telephone # 760 720-9548 Date contactedJyV ^/#0 (by/$^) Fax # unk Maili/Telephone y Fax In Person REMARKS J By Eric Jensen Enclosures Esgil Corporation D GA D MB D EJ D PC 8/7 9320 Chesapeake Drive, Suite 208 + San Diego, California 92123 + (858)560-1468 *• Fax (858) 560-1576 Carlsbad O8-15O1 August 14, 2O08 GENERAL PLAN CORRECTION LIST JURISDICTION Carlsbad PLAN CHECK NO 08-1501 PROJECT ADDRESS 1372 Cynthia Lane DATE PLAN RECEIVED BY DATE REVIEW COMPLETED ESGIL CORPORATION 8/7 August 14, 2008 REVIEWED BY Eric Jensen FOREWORD (PLEASE READ): This plan review is limited to the technical requirements contained in the International Building Code, Uniform Plumbing Code, Uniform Mechanical Code, National Electrical Code and state laws regulating energy conservation, noise attenuation and disabled access This plan review is based on regulations enforced by the Building Department You may have other corrections based on laws and ordinances enforced by the Planning Department, Engineering Department or other departments The following items listed need clarification, modification or change All items must be satisfied before the plans will be in conformance with the cited codes and regulations The approval of the plans does not permit the violation of any state, county or city law • Please make all corrections and submit two new complete sets of prints to ESGIL CORPORATION • To facilitate rechecking, please identify, next to each item, the sheet of the plans upon which each correction on this sheet has been made and return this sheet with the revised plans • Please indicate here if any changes have been made to the plans that are not a result of corrections from this list If there are other changes, please briefly describe them and where they are located on the plans Have changes been made not resulting from this list? Q Yes a No Carlsbad OS-ISO! • August 14, 2O08 ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) PLAN REVIEWER: Eric Jensen ELECTRICAL (2005 NATIONAL ELECTRICAL CODE) 1 Include a site specific single line diagram The submitted single line is boilerplate and does not address this specific installation Include Conductor sizing, number of strings, series DC fusing, and calculations (current, voltage, etc ) 2 Formalize the site layout Include all items on the above single line in a readable manner • The jurisdiction has contracted with Esgil Corporation located at 9320 Chesapeake Drive, Suite 208, San Diego, California 92123, telephone number of 858/560-1468, to perform the plan review for your project If you have any questions regarding these plan review items, please contact Eric Jensen at Esgil Corporation Thank you Carlsbad 08-1501 -August 14, 2008 VALUATION AND PLAN CHECK FEE PLAN CHECK NO 08-1501 DATE August 14, 2008 JURISDICTION Carlsbad PREPARED BY Eric Jensen BUILDING ADDRESS 1372 Cynthia Lane BUILDING OCCUPANCY TYPE OF CONSTRUCTION BUILDING PORTION Air Conditioning Fire Sprinklers TOTAL VALUE Jurisdiction Code Rlrln Pprmir FPP hu Orrlina AREA ( Sq Ft ) cb nrp T : Valuation Multiplier By Ordinance Reg Mod VALUE ($) Plan Check Fee by Ordinance Type of Review j~~l Repetitive Fee Repeats $12000 Complete Review D Other m Hourly Structural Only 1 Hour* Esgil Plan Review Fee $9600 * Based on hourly rate Comments Sheet 1 of 1 macvalue doc PLANNING/ENGINEERING APPROVALS PERMIT NUMBER CB081501 DATE 8/5/08 ADDRESS 1372 CYNTHIA LN RESIDENTIAL ADDITION- MINOR (< 17,000.00) RETAINING WALL VILLAGE FAIRE POOL/SPA TENANT IMPROVEMENT COMPLETE OFFICE BUILDING OTHER SOLAR PANELS PLANNER GINA RUIZ ENGINEER DATE 8/5/08 DATE II \AllJHX\l HI X Fl II/I'I,\\M\I,/I \(,l.\'l I HIM, AITOIVALS •QD 1 of 179 Installation Guide And Owner's Manual SunWize® Grid-Tie Systems (GTS) Utility Interactive Solar Electricity Featuring Xantrex GT Inverters Unirac® SolarMount® SunWize' 05/2007 Rev 15 5 of 179 Table of Contents Section General Information • Safety Precautions • Mounting Considerations • Codes and Standards Operation Principals • Factors Affecting Solar Output GTS Parts List Electrical Diagrams • System Wiring Diagrams 3 . 4 Support Structure Installation • Support Structure - Asphalt Shingle Roof Installation • UniRac SolarMount Instructions • Mechanical preparation assembly Electrical Installation • Wire Size Table • Solar Array Electrical Wiring • Solar Array Grounding Power Center Installation • Installation Instructions and Drawings System Start Up • Installation check list • Commissioning Inverter Major Component Data • Solar Module Specifications • Inverter Specification • AC/DC Disconnects Appendix • Glossary of Terms 10 05/2007 Rev 15 *PM353030 25 of 179 Section 4 Electrical Diagrams 05/2007 Rev 15 *PM353030 27 of 179 ) ca^P'S' uiS'S^Ste 5 1^§3 g££§y11 jsfi still*i isi!& is : i| I ^I * ? =i Mi i eS ; i 'y 1 ' 1 ; ' i ri iii! i ri 3? ,i 4§ ' s ^v g ° 1 1 :> tf 1ji * 1 feC/)<. o: LJ z|UJo cc |!o Q_ 1 1 L o|ri.i ^- - £/) CD £?Lo "— — J •*•1 **,3° 51 03 r~~~ji.~~~ "If « I LV, +r~i' v, i i ^£ i ^ ^i S i 2cS§ •rr1-, t Q^o l <? | ^i" i._» +p' »...._n ^_x z —?> » j ^>- Q ^ ' 1^(/) Q 3 N °(^l(0 \~).0 nrf z ;sl 3 E\ J : CM ^"""N ^*V- V3 r'7~ s-rT'-^^ • r? '! T-1 ±1 ' p ~3— AV + t , J -i L^i i (/ // l~ _J, |lL i L_ ^|rj| ce LJi—S r i i-1i L — + // rif4//'/ [o^o 1 :.> rVP..Shu.. ^~Lj_r- — J— o^ ^fl u<8^ i L § _^j- §st R^i^ S^p < — 1 « _ 5 Q< e> ° _ ' Q 5 ' Q- -J_Z ^ U + Q ' Q 1 ._ LJ 1 oJ" i ^^li° rto z§ j- Q^ L a ^ '8§ »Sr— -ITLT±:. 1 L 1 l o®l ' rr-j— ' I_L_I_ J"l 1 1 1 . i 1' 1 Y* ^-S>_1_ - j ^HozQ I 2 LUz--•>i2|t zj ce oS° >CJ . Q: iLdLJ•771- hqt -T1 'OLJ>xt-> zg 95 < o§3 * 0 ' 1 Qy-j— Hi-g J 1 ^ '-'^ 1 -^UJ 1 ?)=^£ 1 1 1 11 1 1 . 1 J1.^ i CJ E Kto I "r ^U) (SI g tol 1K j ^- ^ SI ^ ^^vh * i— -<<•S| oi oo 18- >- o_gl CO sTOvji u piHi *eicrw i il" ^ !i • 1*8 1 1 I i >>cc g <•, a: c £ 1LJ 0 Ld O , OT C J— h O ^ t u Q £ <"o: o s ^o: to ^ E3 Ss e ii " « 5tg (/) t fK °< o:5^ o *~^ ^t *°*s - z ^ ^g ^ L Q Q i DO |5-l | O/j ^X| I b* ' CM 08 0!- Si*"J^1 -1 1 1 to « 5 T £ I ^:|© i <g a. J£o. go a.PV STRING Isc@STCPV STRING Voc@STCUjO 3 Owsz* — u 5 c. "™ ^ u >: CL j 4t 5 CO ^ LI OT5 05/2007 Rev 15 •PM353030 29 of 179 Section 5 Rack and Support Structure 05/2007 _ HC RW15 *PM353030 30oM79 05/2007 Rev 15 *PM353030 31 of 179 Support Structure Installation-Overview Recommended Tools and Materials • 7/16", 1/2" and 9/16" open end wrenches and sockets • chalk line and crayon • stud finder and tape measure • screwdrivers, small slotted & medium cross tip • cordless drill and 3/8" drive extension • 3/16" drill bit • 5/16" lag bolts with flat washers (See Unirac instructions) • UV resistant rooftop sealant or Flashing material Asphalt Shingle Roof Installation The support structure of the GTS packages is designed to be installed directly onto a typical asphalt shingle roof If your application requires the use of standoff and/or flashing, please refer to the Unirac's documents covering these roofing materials in this section Standoffs, flashing and tilt legs are sold separately and are not specifically covered by this manual Plan the array's layout carefully, away from shaded area during the hour of 9AM and 4PM Do not position the array near obstructions such as parapet walls, fireplace chimneys, vent pipes, or any other item causing shade While planning the position of the array, also plan for the location of the wires and the conduits to the Power Center or to the inverter Position the junction box of the solar module in a way that they can be easily accessed at later date if maintenance is required Careful planning will minimize the need to remove modules when maintenance is needed Please refer to the Sunwize drawings in this section and also Section 6 for recommended installation method of the different components located on the roof Carefully read Unirac's instructions included in this Section of the manual These instructions give important information concerning the layout of the rails, spacing of the L-Feet and other important considerations Junction Box installation The GTS kits come with two type of roof top junction box Plastic and Metal The plastic enclosure (704BOXASSYAPB-3) is taller than the 4 5" height at which solar module are typically mounted For that reason, the APB-3 is normally located close to the array and mounted directly to the roof For aesthetics reasons it is recommended to locate the box out of sight as much as possible The roof penetrations will have to be properly sealed using UV resistant rooftop sealant If your kit includes a 704BOXASSYPJB or 704BOXASSYAPB-2, the metal enclosure will be mounted on two %" bolt (included in the kit) that will slide in the slot on the top side of the rail It is recommended that the enclosure be installed under the solar module closest to the end of the string for extra protection against direct sunlight The metal conduit and the home run wires should be installed before the solar module covering them is finalized Please see drawing in this section and also section 6 of this manual for installation detail 08/2006 Rev D *PM353030 05/2007 Rev 15 *PM353030 32 of 179 05/2007 Rev 15 •PM353030 33 of 179 05/2007 Rev 15 *PM353030 34 of 179 05/2007 Rev 15 *PM353030 35 of 179 fcii!CO a: o CO a:CL o -4- 8 co O) < — 05/2007 Rev 15 *PM353030 36 of 179 THE STANDARD IN PV MOUNTING STRUCTURES' SOIARMOUNT U S Des Patent No D496.248S, 0496,2498 Other patents pending Code-Compliant Planning and Assembly with California Building Code Certification .:- ---: ;Bosed.on UniKaca . v JristdHation'Mahual'214 •'; Contents Letter of certification 2 Parti Scope, certification and installer responsibility 3 Part II Procedures for code-compliant installations using the SolarMount Module Mounting System 4 Part III Installing SolarMount with top mounting clamps 9 PartIV Installing SolarMount with bottom mounting clips 15 Warranty 20 Pub 060807-l'ii August 200&' "© 2006 by UmRac, Inc • '^ , :.r;. All rights reserved -j. . --^'-" 05/2007 Rev 15 *PM353030 37 of 179 SolarMount® Code-Compliant Planning and Assembly (California) T E C T O N I: 1600 °AF« AVFMilF = MFRY\.II I F TAI IFORH 4 9 j G o a"V'fin i'TEL VoTi'6 2400 T "AX 510 740 240^ *wv tecTcnics <IP ron- 29 March 2004 Mr John Liebendorfer UmRac, Inc 3201 University Blvd SE, Suite 110 Albuquerque, NM 87106-5635 Subject Engineering Certification for UmRac s SolarMount™ Universal PV Module Mounting System Dear Mr Liebendorfer, Attached is the UmRac Calculation worksheet and Installation Manual #2)4, Pub 040316-In, Copyrignted by UmRac, Inc , March 2004,20 pages I have reviewed these calculations, and certify their results are accurate The calculations determine the design level forces for wind, as prescribed m the California Building Code The adequacy of the UNIRAC structure is demonstrated by the calculations The calculations also correctly determine the anchorage requirements for the installation, and this requirement is properly represented in Installation Manual #214 The calculations are based upon 1 "The 2001 California Building Code, California Code of Regulations", based on the 1997 "Uniform Building Code. Volume 2 Structural Engineering Design Provisions", by InternaUonal Conference of Building Officials, Whittier, Ca, 1997, and California Building Standards Commission. Sacramento, California, 2001 2 'Manual of Steel Construction Load Resistance Factor Design", 3rd Ed, American Institute of Steel Construction, Chicago. 1L , 2001 3 ' Aluminum Design Manual Specifications and Guidelines for Aluminum Structures' , The Aluminum Association, Washington D C , 2000 4 Mechanical Properties of UNIRAC extiuded rails and related components based on data , pbtamed from Walter Gerstle, PE. Department of Civil Engineering, University of New Mexico, Albuquerque, NM With this letter, I certify that UmRac SolarMount products will be structurally adequate and will satisfy the building codes listed above when they are installed per the ' SolarMount Code- Compliant Planning, and Assembly' Installation Manual #214. Pub 040316-111 Copyrighted by UmRac, Inc March 2004 Please call me if y,c«jhaxe<3ny questions* Jf*sl*tfEr0*i,\s - Sincerely or concerns Brian Spn TECTONICS Architects / Planners / \ r i. It i c e L t s <-,(. •> FRANCESCO EMER1VILLF. 05/2007 Rev 15 •PM353030 38 of 179 SolarMount® Code-Compliant Planning and Assembly (California) SUilWiZG? T E C H M O L>O 4» I 9=. * Part I. Scope, certification, and installer responsibility Please review this manual thor- oughly before installing your SolarMount system This manual provides (1) sup- porting documentation for building permit applications re- lating to UniRac's SolarMount®' Universal PV Module Mount- ing system, and (2) planning and assembly instructions for SolarMount SolarMount products, when installed in accordance with this bulletin, will be structur- ally adequate and will meet the 2001 California Budding Code and the Uniform Budding Code, 1997, hereafter UBC1997 UniRac also provides a limited warranty on SolarMount prod- ucts (see p 20) The mstalleris sQlely^respbnsible for: '; "=•<*!. •" •;i • Cpmplying;witrgall applicable locator national building codes',' includmg any that maysupercede this manual; / "•"'-• Ensuring that UniRa'c arid other products are' appropri- ,. •;. ate for-the particularanstallation and the installation ^,' environment, • "" " " ' """ '': • Ensuring that the rodf, its rafters, connections, arid' '?>> ';... other structural^support members can support thet array underbuilding live Ipad'conditions;(this'total assembly -:,. is.-hereafter,referredJto asithe roof rafter assembly;)., ^, ^ ^* ^~' ~ 3%$*' "•; ~ g~ .-/V- ^''- ' -ff* / ,*•* (;-;jJ7 ^ '>*£*' > <l , • IJsing.pnly.pniRac parts and installer-suppHed p.arts as. ". specified ftyVUriiRac ^substitution of parts may vpid the: ;" .warranty and invalidate the letter of certificatiori.pn ,;t: fy •Erisiinng tfeafelag screws ihave'adequate pullout strength and shear capacities as installed; „ , ;,:-""' V?. K;-.-%--- -^/">k~ - I- ,".-•'. 'H ' '-: ••:•:•.'• ,*;.F. Maintaining tKe waterproof integrity of the roof,' mclud- mg selection oftappropnate-flashing, and >- ,>,j . , ;;i .O ^i< < . .1 \^ • L f -, ttf ~-^r-f^ , ~~- ' •. " * < '""' • '~j£ : ."•;;*•"» Ensuring safe iristalfatiohXof all electrical aspectsJof the-.'Y. --v'*- *-" ,-f • •-•!. .-ft: -~f-~v : ;. ,^_ r- \r • ' '-.>-.' PV arra v *.- ^ ' -^: "'* -- '^ -^ ' "^ . - PV array 05/2007 Rev 15 *PM353030 39 of 179 SolarMount® Code-Compliant Planning and Assembly (California) UilnZ0a Part II. Procedures for code-compliant installations using the SolarMount Module Mounting System This bulletin is designed to support, applications for build- ing permits for installations using SolarMount™ PV Module Mounting System, manufactured by UmRac, Inc Follow the six steps below and the installation instructions on pages 9-20 to install SolarMount in compliance with the 2001 California Building Code and the UBC1997 Before proceeding, note the following • This bulletin addresses only wind loads on the as- sumption that wind produces the maximum load factor affecting an installation Verify that other local factors, such as snow loads and earthquake effects, do not ex- ceed the wind loads Give precedence to any factor that does Wind loads are considered to act on the entire projected area, or may be perpendicular to any surface • The roof on which the SolarMount will be installed must have the capacity to resist the combined Design Dead Load and Live Load per footing listed m Tables 2 and 3 on pages 6-7 1. Determine the Basic Wind Speed at your installation site For the United States, see "Minimum Basic Wind Speeds in Miles per Hour," reproduced below If your installation is outside the United States or if you need further assistance, consult a local professional engineer or your local building authority Figure J Minimum Basic Wind Speeds Reproduced from UBC, Vol 2, Structural Engineering Design Provisions, Chap 16, Div III, Wind Design, Fig 16 1, "Minimum Basic Wind Speeds m Miles per Hour," p 36 The map has been adopted by the 2001 California Building Code (Fig 16-1, vol 2 p 36) 05/2007 Rev 15 *PM353030 40 of 179 SolarMount® Code-Compliant Planning and Assembly (California) U '•>-'•' TE C HC H N O l_t>0 I ES 2. Determine the exposure category of your installation site The California Budding Code* defines wind exposure catego- ries as follows EXPOSURE B has terrain with buildings, forests or sur- face irregularities covering at least 20 percent of the ground level area extending 1 mile (1 61 km) or more from die site EXPOSURE c has terrain that is flat and generally open, extending l/2 mile (0 81 km) or more from the site in any quadrant or having scattered obstructions extending one-half mde or more from the site in any full quadrant This category includes flat or gently rolling open country and grasslands Sites normally considered as Exposure B, but which are subject to topographic amplification or channelization, such as ndgetops or draws, shall be considered as Exposure C T EXPOSURE D represents the most severe exposure m ar- eas with basic wind speeds of 80 miles per hour (mph) (129 km/h) or greater and has terrain that is flat and unobstructed facing large bodies of water over 1 mile (1 61 km) or more in width relative to any quadrant of the building site Exposure D extends inland from the shoreline 1A mile (0 40 km) or 10 times the building height, whichever is greater 3. Determine Design Wind Pressure required for your installation Design Wind Pressure is the amount of wind pressure that a structure is designed to withstand, expressed here m pounds per square foot (psf) To determine the Design Wind Pressure required for your installation, apply the following factors using Table 1 • your Basic Wind Speed (determined in step 1), • your exposure category (determined m step 2) and • the height of your roof above the ground If your values fall significantly outside the range of the table, or if your Design Wind Pressure requirement exceeds 50 psf consult UniRac, a professional engineer or your local building authority Table I Design Wind Pressure (psf) by Wind Speed and Exposure Category Design force applies to surface pressure and/or uplift (withdrawal) Basic Wind Speed (mph) *2001 California Building Code, vol 2 chap 16, Structural Engineei ing Design Provisions, Div III Wind Design, p 3810 rEmphasis in the original, indicating material inserted by California into definitions adopted from the UBC Category B 1 5' roof height 20' roof height 25' roof height 30' roof height Category C 1 5' roof height 20' roof height 25' roof height 30' roof height Category D 15' roof height 20' roof height 25' roof height 30' roof height 70 10 1 1 12 12 17 19 19 20 23 24 25 25 80 13 14 15 16 23 24 25 26 30 31 32 33 90 17 18 19 21 29 31 32 33 38 39 41 42 100 21 22 24 25 35 38 40 41 46 48 50 51 110 25 27 29 31 43 46 48 50 56 58 60 62 120 30 32 35 36 51 54 57 59 67 70 72 74 130 35 38 41 43 60 64 67 69 78 82 84 87 Source These Design Wind Pressure (P) values are based on the formula P = Ce * C. * q. * lf (2001 California Building Code, voL 2, chap 16, Structural EngineermgDesign Provisions Dn- III WindDesign,p 3810) Assump- tions / = / and C = I 3 4a. Determine Minimum Design Dead and Live Loads for standard rafter spacing... Foot spacing refers to the space between L-feet (or standoffs, if applicable) along the same SolarMount rail (see Fig 2, p 8) If you are spacing feet to match a standard rafter spacing, con suit Table 2 to determine your Minimum Design Live and Dead Loads per footing (If you prefer to maximize foot spacing to minimize roof penetrations, skip to Step 4b on p 8 ) Locate the make and model of the PV module that you plan to install and the rafter spacing at your installation site Read the Minimum Design Dead Load and read or extrapolate the Mini- mum Design Live Load for the Maximum Foot Spacing and the Design Wind Pressure you determined in step 3 To meet code, you must verify that the roof rafter assembly at your installation site has the capacity to resist the sum of the Design Dead and Live Loads If they do not, try smaller footer spacing (In this case, you may elect to use the procedures outlined in Step 4b ) If the result is still not acceptable, relocate the array to a stronger area of the roof or strengthen the inadequate framing elements For assistance, consult a local professional engineer Go to step 5 on page 8 05/2007 Rev 15 •PM353030 41 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Table 2 SolarMount® Loads (Ibs) per Footing at Standard Rafter Spacings To meet code, your Design Loads must be at or above those indicated You the installer are solely responsible for verifying that the roof can withstand these design loads For specifications based on Design Wind Pressure values greater than 50 pounts per square foot, contact UniRac Minimum Design Dead Load Minimum Design Live Load as a Function of Design Wind Pressure 20psf 30psf 40psf SOpsf Minimum Design Dead Load Minimum Design Live Load as a Function of Design Wind Pressure 20psf 30psf 40psf SOpsf 433 578 650 Sanyo HIP-I80BA3 thru -200BA3 48' rafter (foot) spacing 29 173 260 347 64" rafter (foot) spacing 39 231 347 462 72' rafter (foot) spacing 44 260 390 520 Sharp ND-NOECU (MOW) 48' rafter (foot) spacing 26 153 230 306 383 64" rafter (foot) spacing 34 204 306 408 5IO 72 rafter (foot) spacing 39 230 344 459 574 SharpND-l67U3 48' rafter (foot) spacing 28 174 262 349 436 64' rafter (foot) spacing 37 232 349 465 58! 72 rafter (foot) spacing 41 262 392 523 654 Sharp NT-I75UI,NT-I85UI 48' rafter (foot) spacing 35 207 3IO 4I3 5I7 64' rafter (foot) spacing 47 276 4I3 55! 689 72' rafter (foot) spacing 53 3IO 465 620 775 Sharp ND-200UI, ND-208UI 48' rafter (foot) spacing 21 64' rafter (foot) spacing 43 72' rafter (foot) spacing 48 SunWize SW85, SW90, SW95 48' rafter (foot) spacing 35 64 rafter (foot) spacing 46 72' rafter (foot) spacing 52 SunWize SW155, SW165 48 rafter (foot) spacing 28 64' rafter (foot) spacing 38 72 rafter (foot) spacing 43 273 393 5I3 634 337 486 634 783 379 546 7I4 NA 190 253 285 234 3I2 35! 285 380 474 380 506 633 427 569 7I2 339 452 508 444 592 666 549 732 NA 05/2007 Rev 15 •PM353030 42 of 179 SolarMount® Code-Compliant Planning and Assembly (California) SiittWJZe> TECHNOLOOIE« Table 3 SolarMount® Loads per Footing at Maximum Foot Spacing To meet code, your Design Loads must be at or above the Design Wind Pressure indicated You the installer are solely responsible for verifying that the roof can withstand these design loads For specifications based on Design Wind Pressure values greater than 50 pounds per square foot contact UniRac, Design Wind Pressure 20psf JOpsf 40psf 50psf Design Wind Pressure 20psf JOpsf 40psf 50psf Sanyo HIP-I80BA3 thru -200BA3 Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) Sharp ND-NOECU (NOW) Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) Sharp ND-I67U3 Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) Sharp NT- 1 TSUI, NT- I85UI Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) 125 451 76 133 424 72 124 450 71 114 491 83 102 553 62 108 516 58 102 556 58 93 601 68 88 636 54 94 599 51 88 639 50 81 698 59 79 713 48 84 669 45 79 717 45 72 775 53 Sharp ND-200UI.ND-208UI Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) SunWize SW8S, SW90, SW95 Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) SunWizeSWI55,SWI65 Maximum Foot Spacing (inches) Minimum Foot Design Live Load (Ibs) Minimum Foot Design Dead Load (Ibs) 102 535 68 119 470 86 101 494 60 88 668 59 97 575 70 87 614 52 77 763 51 84 664 61 76 763 45 65 772 43 75 741 54 68 777 40 7 05/2007 Rev 15 *PM353030 43 of 179 liNillAC* SolarMount® Code-Compliant Planning and Assembly (California) SUIlWiZf£ 4b.... Or verify Maximum Foot Spacing and Determine Minimum Design Dead and Live Loads To minimize roof penetrations, consult Table 3 (p 7) to deter- mine Maximum Foot Spacing allowable for the Design Wind Pressure that you determined in Step 3 Find the make and model of the PV module vou plan to install, then read or extrapolate Foot Design Live Loads and Dead Loads at the maximum spacing To meet code, you must verify that foot spacing is at or below the dimension listed and that the roof rafter assembly at your installation site has the capacity to withstand the sum of the Design Dead Load and Design Live Load for the speci- fied spacing If they do not, try smaller footer spacing If the result is still not acceptable, relocate the array to a stronger area of the roof or strengthen the inadequate framing elements For assistance, consult a local professional engineer 5. Verify acceptable Rail End Overhang Rail End Overhang (Fig 2) must equal 50 percent or less of foot spacing Thus, if foot spacing is 72 inches, the Rail End Overhang can be up to 36 inches In this case, two feet can support a rail of as much as 144 inches (72 inches between the feet and 36 inches of overhang at each end) 6. Ensure that Live Loads do not ex- ceed Pull-Out Capacities Based on the characteristics of your roof rafter or truss lumber and the lag screws, consult Table 4 to determine the lag pull- out capacity per 1-inch thread depth Compare that value to the minimum design live load per footing determined in Step 4a or 4b Based on these values, determine the length of the lag-screw thread depth you require to resist the design live load To ensure code compliance, the lag pull-out capacity per footing must be greater than the footing design live load If your SolarMount requires standoffs, always use at least two lag screws to secure the standoff to the rafter Figure 2 SolarMount foot spacing refers to the distance between feet on the same rail Over- hang, the distance from end of the rail to the first foot, may be no more than half the fool spacing Table 4 Lag pull-out (withdrawal) capacities (Ibs) in typical roof truss lumber Douglas Fir, Larch Douglas Fir, South Engelmann Spruce Lodgepole Pine (MSR I650f & higher) Hem, Fir Hem, Fir (North) Southern Pine Spruce, Pine, Fir Spruce, Pine Fir (E of 2 million psi and higher grades of MSR and MEL) Specific gravity 050 046 046 043 046 055 042 050 f/,<. shaft,* 2/4" thread depth 665 588 588 530 588 768 513 665 Lag screw specifications •V,t shaft* per 1 thread depth 266 235 235 212 235 307 205 266 '/t shaft,* per / thread depth ||r|jj 304 269 269 243 269 352 235 304 t : Thread depth i i .¥ J! ii!==i 353Smss=3=!=; ==: ^ ^ 1 V Sources Uniform Building Code American Wood Council Notes (/) Thread must be embedded in a rafter or other structural roof member (2) Pull-oul values incorporate a I 6 safety factor recommended by the American Wood Council (3) See UBC for required edge distances *Use flat washers with lag screws to, 8 05/2007 Rev 15 *PM353030 44 of 179 SolarMount® Code-Compliant Planning and Assembly (California) TECH NOLDOIES Part III. Installing SolarMount with top mounting clamps This secaon covers SolarMount assembly where the installer has elected to use top mount- ing clamps to secure modules to the rails It details the procedure for flush mounting SolarMount to a pitched roof Contents Laying out the installation area Laying out L-feet Installing L-feet Laying out standoffs Installing standoffs Installing SolarMount rails Installing the modules Figure 3 Exploded view of a low-profile installation mounted flush to the roof with L-feet Table 5 Part quantities Table 6 Wrenches and torque SMR Series SolarMount Rail Sets (model no = rail length in inches) Vf. footing -/s~ flange bolts nuts Wrench size Recommended torque (ft-lbs) SMR48 thru 106 SMR 120 thru 180 SMR 192 thru 216 Roi/s 2 2 2 L-feet 4 6 8 'A hardware Vt" hardware 15 30 CT Series Clamp Sets (model no = modules accommodated) CT2 CT3 CT4 CT5 CT6 CT7 CT8 End Mid 'A module clamps clamps clamp bolts 6 'A x (A flange safety bolts nuts Caution Stainless steel hardware can seize up a process called galling To significantly reduce the likelihood of galling SAF-T-EZE anti-seize lubricant has been included with your hardware Apply a very small drop to the threads of all bolts before in- stallation If more anti-seize is needed, substitute any lubricant 2 4 6 8 10 12 14 10 12 14 16 18 10 12 14 16 18 20 05/2007 Rev 15 *PM353030 45 of 179 If NiRACe SolarMount® Code-Compliant Planning and Assembly (California) Laying out the installation area The installation can be laid out with rails parallel to the rafters (high-profile mode) or perpendicular to the rafters (low-pro- file mode) Note that SolarMount rails make excellent straight edges for doing layouts Center the installation area over the rafters as much as pos- sible Leave enough room to safely move around the array during installation The width of the installation area is equal to the length of one module The length of the installation area is equal to • the total width of the modules, • plus 1 inch for each space between modules (for mid- damp), • plus 3 inches (IVi inches for each set of end clamps) High profile mode Low profile mode Lower roof edge Figure 4 Rails may be placed parallel or perpendicular to rafters 10 05/2007 Rev 15 *PM353030 46 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Laying out L-feet L-feet (Fig 5) are used for installation through existing roofing material, such as asphalt shingles or sheet metal Use Figure 6 or Figure 7 below to locate and mark the L-feet lag bolt holes within the installation area To meet code, you must use the foot spacing deter- mined in procedural steps 4a or 4b (pp 5, 8) When determining the distance be- tween the rails in high-profile mode, keep in mind that the center of each rail will be offset from the L-foot lag bolt holes by 13A inches If multiple high-profile rows are to be installed adjacent to one another, it will not be possible for each row to be centered above the rafters Adjust as needed, following the guidelines in Figure 7 as closely as possible Figure 5 Ovprhang 1-3/4 typical eu:_n end SOTi, lypicai Figure 6 Low-profile layout 25% maximum typical each end 1 3/4" -*- 50% minimum typical 1 3/4" Rafters Figure 7 High-profile layout Installing L-feet Drill pilot holes through the roof into the center of the rafter at each L-footlag bolt hole locauon Consult procedural step 6 and Table 4 (p 8) to select the lag bolts that you must use to meet building code wind load requirements Lag bolts are not provided with SolarMount rail sets Squirt, sealant into the hole, and on the shafts of the lag bolts Seal the underside of the L-feet with a suitable weatherproof sealant Securely fasten the L-feet to the roof with the lag bolts Ensure that the L-feet face as shown in Figure 6 or Figure 7 The single-slotted square side of the L-foot must always he against the roof with the double-slotted side perpendicular to the roof 11 05/2007 Rev 15 *PM353030 47 of 179 SolarMount® Code-Compliant Planning and Assembly (California) SUttWiZfi Laying out standoffs Standoffs (Fig 8) are used for flashed installations, such as those with tile and shake shingles Use Figure 9 or Figure 10 to locate and mark the standoff lag bolt holes within the installation area To meet code, you must use the foot spacing determined in procedural steps 4a or 4b (pp 5, 8) Remove the tile or shake underneath each standoff location, exposing the roofing underlayment Ensure that the standoff base lies flat on the underlayment, but remove no more material than required for the flashings to be installed properly Use the standoff base as a template to mark lag bolt hole locations on underlayment above the center of the rafters (Fig 9 or Fig 10) Figures Raised flange standoff (left) and flat top standoff used in con- junction with an L-foot When determining the distance be- tween the rails in high-profile mode, keep in mind that the center of each rail will be offset from the standoff lag bolt holes by 7/it of an inch If multiple high-profile rows are to be installed adjacent to each other, it will not be possible for each row to be centered above the rafters Adjust as needed following the guidelines in Figure 30 as closely as possible Overhang •— ( 1 3/4" 50% minimum J typical Lower roof edge i . Rafters Figure 9 Low-profile layout 25% typical each end 7/16'*1 ( ^'\ Lower roof edge ''—'In • i N*' 50% minimum typical x^""Jf / i, / Foot -*-;— 7/16' spacing Overhang Figui eW High-profile layout Installing standoffs Drill Vi6-mch pilot holes through the underlayment into the center of the rafters at each standoff location Securely fasten each standoff to the rafters with the two Vis" x 3 V=' lag bolts provided with it Note You must verify that the lag boltsyou use are adequate for your installation by following proce- dural steps 4A or 4B (pp 5, 8) Ensure that the standoffs face as shown in Figure 9 or Figure 10 SolarMount standoffs are designed for easiest instal- lation with Oatey® 11A"-IV2~ No-Calk® flashings They can be obtained at most plumbing and roofing supply companies Install and seal flashings and standoffs using standard building practices 12 05/2007 Rev 15 "PM353030 48 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Figure 11 Splice bars slide into the footing bolt slots of SolarMount rail sections Clamping bolt slot Footing bolt slot Figure 12 Foot-to-rail splice attachment Installing SolarMount rails Keep rail slots free of roofing grit or other debris Foreign matter will cause bolts to bind as they slide in the slots Installing Splices If your installation uses SolarMount splice bars, attach the rails together (Fig 11) before mounting the rails to the foot- ings Use splice bars only with flush installations or those that use low-profile tilt legs If using more than one splice per rail, contact UniRac concerning thermal expansion issues Mounting Rails on Footings Rails may be attached to either of two mounting holes in the footings (Fig 12) Mount in the lower hole for a low profile, more aesthetically pleasing instal- lation Mount in the upper hole for a higher profile, which will maximize airflow under the modules This will cool them more and may enhance performance in hotter climates Slide the %-inch mounting bolts into the footing bolt slots Loosely attach the rails to the footings with the flange nuts Ensure that the rails are oriented to the footings as shown in Figure 6, 7, 9, or 10, whichever is appropriate Aligning the Rail Ends Align one pair of rail ends to the edge of the instal- lation area (Fig 13 or Fig 14) The opposite pair of rail ends will overhang the side of the installation area Do not trim them off until the installation is complete In low-profile mode (Fig 13), either end of the rails can be aligned, bui the first module must be installed at the aligned end For the safest high-profile installation (Fig 14), the aligned end of the rails must face the lower edge of the roof Securely tighten the flange nuts on the mounting bolts after alignment is complete (28-32 ft Ibs) Mount modules to the rails as soon as possible Temperature changes may bow the rails within a few hours if module placement is delayed Edge of installation area '« $ Edge of installation area Figure 13 Low-profile mode Figure 14 High-profile mode. 13 05/2007 Rev 15 *PM353030 49 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Installing the modules Prewiring Modules If modules are the Plug and Play type, no prewiring is required, and you can proceed directly to "Installing the First Module" below If modules have standard J-boxes, each module should be prewired with one end of the intermodule cable for ease of installation For safety reasons, module prewiring should not be performed on the roof Leave covers off J-boxes They will be installed when the modules are installed on the rails Installing the First Module In high-profile installations, the safety bolt and flange nut must be fastened to the module bolt slot at the aligned (lower) end of each rail It will prevent the lower end clamps and clamping bolts fiom sliding out of the rail slot dunng installation If there is a return cable to the inverter, connect it to the first module Close the J-box cover Secure the first module with T-bolts and end clamps at the aligned end of each rail Allow half an inch between the rail ends and the end damps (Fig 15) Finger tighten flange nuts, center and align the module as needed, and securely tighten the flange nuts (15 ft Ibs) Installing the Other Modules Lay the second module face down (glass to glass) on the first module Connect intermodule cable to the second module and close the J-box cover Turn the second module face up (Fig 16) With T-bolts, mid clamps, and flange nuts, secure the adjacent sides of the first and second modules Align the second module and securely tighten the flange nuts (Fig 17) For a neat installation, fasten cable clamps to rails with self-tapping screws Repeat the procedure until all modules are installed Attach the outside edge of the last module to the rail with end clamps Trim off any excess rail, being careful not to cut into the roof Allow half an inch between the end clamp and the end of the rail (Fig 15) Check that all flange nuts on T-bolts are securely fastened 1/2" minimum End clamp •'.TV; ,"•> '" bolt' jj^vancl'fjange nut Figure ]5 J-boxes Figure 16 Module frames ~T/4" module bolt pnge nut v '." , v~-".Rail Mid clamp "- ! • Figure 17 High-lipped module (cross section)Spacer £52 Low-lipped module (cross section)D SbtarMountirai! .id:/ £!_ Figure 18 Mid clamps and end damps for lipped-frame modules are identical A spacer for the end clamp is necessary only if lips are located high on the module frame 14 05/2007 Rev 15 •PM353030 50 of 179 r SolarMount® Code-Compliant Planning and Assembly (California) SutiWlZf? Part IV. Installing SolarMount with bottom mounting clips This section covers SolarMount assembly where the installer has elected to use bottom mounting clips to secure modules to the rails It de- tails the procedure for flush mount- ing SolarMount to a pitched roof Contents Planning the installation area 16 Laving out and installing L-feet 17 Attaching modules to the rails 18 Installing module-rail assembly 19 pv rhodutes {face down] V-->C Figure 79 SMR and CB components Table 7 Part quantities Table 8 Wrenches and torque SMR Series SolarMount Rail Sets CMR4R rhrn Roils r\i. -> SMR 120 thru 180 2 SMRI92 thru 216 2 CB Series Clip Sets (model no = CB2 CB3 CB4 CBS CB6 CB7 CBS % Clips 8 12 16 20 24 28 32 (model no = rail length in inches) L-feet A 6 8 modules ' module bolts 8 12 16 20 24 28 32 A footing % flange Wrench Recommended size torque (ft-lbs) bolts nuts '/•> hardware '/it IS • 4 4 6 6 8 8 - accommodated) '/>" flange nuts 8 12 16 20 24 28 32 /, hardware At 30 " Caution Stainless steel hardware can seize up, a process called galling To significantly reduce the likelihood of galling, SAF-T-EZE anti-seize lubricant has been included with your hardware Apply a very small drop ro the threads of all bolts before in- stallation If more anti-seize is needed, substitute any lubricant 15 05/2007 Rev 15 *PM353030 51 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Distance oetween - Iqa. boll centers - •T- •— Distance between —« module Tvounii.ng holes ^ELJij Ij-—Lag boll ->$- \/4 -*• Distance tjeiween • lag bolt centers -*~ ~* «— Distance Between —• module mourning holes j—1/4 o Figure 20 Clip Arrangements A and B Planning the installation area Decide on an arrangement for clips, rails, and L-feec (Fig 20) Use Arrangement A if the full width of the rails contact the module Otherwise use Arrangement B Caution If you choose Arrangement B, either (1) use the upper mounting holes of the L-feet or (2) be certain that the L-feet and clip positions don't conflict If rails must be parallel to the rafters, it is unlikely that they can be spaced to match rafters In that case, add structural supports—either sleepers over the roof or mounting blocks beneath it These additional members must meet code, if in doubt, consult: a pro- fessional engineer Never secure the footings to the roof decking alone Such an arrangement will not meet code and leaves the installation and the roof itself vulnerable to severe damage from wind Secure the footings in accordance with "Installing L-feet" (p 11) Leave enough room to safely move around the array during installation The width of a rail-module as- sembly equals the length of one module Note that L-feet may extend beyond the width of the assembly b> as much as 2 inches on each side The length of the assembly equals the total width of the modules 16 05/2007 Rev 15 *PM353030 52 of 179 llMlltflC* SolarMount® Code-Compliant Planning and Assembly (California) out and installing L-feet L-feet are used for installation through existing low profile roofing material such as asphalt shingles or sheet metal They are also used for most ground mount installations To ensure that the L-feet will be easily accessible during flush installation • Use the PV module mounting holes nearest the ends of the modules • Situate the rails so that foot- ing bolt slots face outward Use Figure 20 to determine spacing between feet on opposite rails Foot spacing (along the same rail) and rail overhang depend on design wind loads To meet code, you must use the foot spacing determined in procedural steps 4a or 4b (pp 5, 8) Install half the L-feet • If rails are perpendicular to rafters (Fig 21), install the feet closest to the lower edge of the roof • If rails are parallel to rafters (Fig 22) install the feet for one of the rails, but not both For the L-feet being installed now, drill pilot holes through the roof into the center of the rafter at each lag bolt hole location Consult Table 4 (p 8) to select lag bolts to meet, design wind loads Squirt sealant into the hole and onto the shafts of the lag bolts Seal the underside of the L-feet with a weath- erproof sealant Securely fasten the L-feet to the roof with the lag bolts Ensure that the L-feet face as shown in Figure 21 or Figure 22 Hold the rest of the L-feet and fasten- ers aside until the panels are com- plete and ready for installation Rafters Install later Figure 2.7 Raik laid out perpendicular to the rafters Rafter Install L-teet Figure 22 Rails laid out parallel to the i afters 17 05/2007 Rev 15 *PM353030 53 of 179 SolarMount® Code-Compliant Planning and Assembly (California) Attaching modules to the rails Lay the modules for a given panel face down on a surface that will not damage the module glass Align the edges of the modules and snug them together (Fig 19, p 15) Trim the rails to the total width of the modules to be mounted Place a rail adjacent to the outer mounting holes Orient the footing bolt slot outward Place a clip slot adiacent to the mounting holes, following the arrangement you selected earlier (Fig 20a or 20b, p 16) Assemble the clips, mounting bolts, and flange nuts Torque the flange nuts to 15 foot- pounds Wire the modules as needed For safety reasons, module wiring should not be performed on a roof For a neat installation, fasten cable clamps to rails with self-tapping screws 18 05/2007 Rev 15 *PM353030 54 of 179 If NlftAC* SolarMount® Code-Compliant Planning and Assembly (California) T £ C M NDLOOIES Installing the module-rail assembly Bring the module-rail assembly to the installation site Keep rail slots free of debris that might cause bolts to bind in the slots Consider the weight of a fully assembled panel UniRac recom- mends safety lines whenever lifting one to a roof Align the panel with the previously installed L-feet Slide Ve- inch L-foot mounting bolts onto the rail and align them with the L-feet mounting holes Attach the panel to the L-feet and finger tighten the flange nuts Rails may be attached to either of two mounting holes in the footings (Fig 23) • Mount in the lower hole for a low, more aesthetically pleasing installation • Or mount in the upper hole to maximize a cooling airflow under the modules This may enhance perfor- mance in hotter climates Adjust the position of the panel as needed to fit the instal- lation area Slide the remaining L-feet bolts onto the other rail, attach L-feet, and finger tighten with flange nuts Align L-feet with mounting holes previously drilled into roof Install lag bolts into remaining L-feet as described in "Laying out and installing L-feet" above Torque all footing flange nuts to 30 foot-pounds Verify that all lag bolts are securely fastened Footfna boll slot Figure 23 Leg-to-rail attachment 19 05/2007 Rev 15 *PM353030 55 of 179 SolarMount® Code-Compliant Planning and Assembly (California) SuriWlZ€* TECHNOLdOlES 10 year limited Product Warranty, 5 year limited Finish Warranty UniRac Inc warrants to the original purchaser ("Purchaser") of product(s) that it manufactures ( Product") at the original installation site that the Product shall be free from defects in material and workmanship for a period of ten (10) years except for the anodized finish which finish shall be free from visible peeling or cracking or chalking under normal atmospheric conditions for a period of five (5) years from the earlier of I) the date the installation of the Product is completed or 2) 30 days after the purchase of the Product by the original Purchaser ("Finish Warranty ) The Finish Warranty does not apply to any foreign residue deposited on the finish All installations in corrosive atmospheric conditions are excluded The Finish Warranty is VOID if the practices specified byAAMA 609 & 610-02 - Cleaning and Maintenance for Architecturally Finished Aluminum" (www aamanet.org) are not followed by Purchaser This Warranty does not cover damage to the Product that occurs during its shipment, storage or installation This Warranty shall be VOID if installation of the Product is not performed in accordance with UmRac's written installation instructions or if the Product has been modified repaired or reworked in a manner not previously authorized by UniRac IN WRITING or if the Product is installed in an environment for which it was not designed UniRac shall not be liable for consequential, contingent or incidental damages arising out of the use of the Product by Purchaser under any circumstances If within the specified Warranty periods the Product shall be reasonably proven to be defective then UniRac shall repair or replace the defective Product, or any part thereof in UniRac s sole discretion Such repair or replacement shall completely satisfy and discharge all of UmRac's liability with respect to this limited Warranty Under no circumstances shall UniRac be liable for special indirect or consequential damages arising out of or related to use by Purchaser of the Product. Manufacturers of related items such as PV modules and flashings may provide written warranties of their own UniRac s limited Warranty covers only its Product, and not any related items THE STANDARD IN PV MOUNTING STRUCTURES 20 UniRac, Inc wwvv unirac com 1411 Broadway Boulevard NE Albuquerque NM 87102-1545 USA 505.242.6411 505 242 6412 Fax 05/2007 Rev 15 *PM353030 56 of 179 THE*M«y!-"STANDARD IN PV MODULE RACKS Standoffs and Flashings Installation Manual 907 Thank you for purchasing a UniRac product Please review these instructions completely before proceeding Standoffs 3-, 4-, 6-, and 7-inch lengths in each type Shaft Pan nos 0 D Use Components Raised flange 310017 15/8 zinc-plated steel thru 24 Flat top / -piece 310009 |5/8" zinc-pfated steel thru 16 Flat top 2-piece afummum 310027 thru 42 I'/a Use only with SolarMount standard or HD rails Secure to rafter with 2 lag screws at opposite corners, orienting the flange parallel to the rails Use with SunFrame, SolarMount standard, or SolarMount HD rails Secure to rafter with 2 lag screws at opposite corners Secure L-foot or installer-supplied strut directly to standoff with standoff hardware Use with SunFrame, SolarMount standard, or SolarMount HD rails Secure to rafter with 2 lag screws Secure L-foot or installer-supplied strut directly to standoff with standoff hardware Especially convenient when installing over a tile roof because flashing can be precisely fitted over secured base prior to installation of shaft •Welded standoff •2lags,5/|6"x3i/2'* •Welded standoff • Bolt, 3/8 x 11/4 • Lock washer, 3/8 •2lags,5/l6 x3'/2* • Shaft • Base assembly • Bolt,3/8 x M/4 • Lock washer, 3/8 •2lags,5/,6 x3'/2* * A lag-bolt removal credit is available wherever an installer prefers to substitute a different log bo/tThe installer is solely responsible for determining wheth- er lags are adequate to handle live and dead loads under wind conditions at the installation site Wind loads and lag pullout capacities are addressed in Code-Compliant Planning and Assembly manuals for SolarMount (Installation Manual 214) and SunFrame (Installation Manual 801 I or 802) Flashings for flat top 2-piece standoffs (I '/e O D shaft) (see illustrations, p 2) Pan no *Dimensions Collared, galvanized 990109 875x125 All metal, aluminum 310044 9 x 12 All metal, solf aluminum 310045 18 x 18 *Packs of 12 flashings Flashings for flat top I -piece standoffs and raised-flange standoffs (15/s O D shaft) (see illustrations, p 3) Pan no *Dimensions Collared, galvanized 990101 8 75" x 12 5 Collared aluminum 990102 875 x 12 5 Collared, soft aluminum 990103 18 x 18 *Packs of 12 flashings Pub 040714-lii July 2004 I j*/,!,©20p4byUrliRac,fInc " ;.;V - f..''' j '^. All.nghts'refsenred^ . ';.;;;•• 05/2007 Rev 15 •PM353030 57 of 179 Installation Manual 907 Standoffs and Flashings The installer is solely responsible for • Complying with all applicable local or national build- ing codes, including any that may supercede this manual, • Ensuring that UmRac and other products are appro- priate for the particular installation and the installa- tion environment, • Ensuring that the roof, its rafters, connections, and other structural support members can support the ar- ray under building hve load conditions, • Using only UmRac parts and installer-supplied parts as specified by UmRac (substitution of parts may void the warranty), • Maintaining the waterproof integrity of the roof, and • Ensuring safe installation of all electrical aspects of the PV array Planning and installation There are many possible configurations of standoffs and flashing The three examples here illustrate major product varieties and installation settings Example 1 2-piece, aluminum, flat top standoff Soft aluminum flashing Tile roof SunFrame (shown) or SolarMount rail SunFrame •* rail tv, * ••- '.- L-foot Mold flashing to tile Remove a tile over a rafter Install the base of a two-piece standoff, ensuring that both lag bolts are screwed into the rafter Install soft aluminum flashing over the base, inserting it under the tile above and forming it to the shape of the tile Insert standoff shaft through the opening in the flashing, screwing it down firmly in place onto the base Seal with roofing cement or other appropriate compound Attach L-feet to standoffs Slide L-foot mounting bolts along slot on SunFrame (or SolarMount) rail. Insert footing bolts through L-feet and fasten with flange nuts 05/2007 Rev 15 *PM353030 58 of 179 Installation Manual 907 Standoffs and Flashings Example 2 1-piece, steel, flat top standoff No-Calk™ flashing Shingled roof SunFrame (shown) or SolarMount rail SunFrame rai1 Cut an opening in the roofing material over a rafter to accommodate the flashing riser Install the standoff, ensuring that both lag bolts are screwed into the rafter Insert the flashing under the shingle above and over the shaft of the standoff No-Calk collar does not require sealing of the flashing and standoff shaft Attach L-feet to standoffs Slide L-foot mounting bolts along slot on SunFrame (or SolarMount) rail Insert footing bolts through L-feet and fasten with flange nuts Example 3 l-piece, steel, raised-flange standoff No-Calk™ flashing Shingled roof SolarMount rail '••, SolarMount rail Shingle Cut an opening in the roofing material over a rafter to accommodate the flashing riser Install the standoff, ensuring that (1) both lag bolts are screwed into the rafter, and (2) the raised flange is oriented parallel to the rail, insert the flashing under the shingle above and over the shaft of the standoff No-Calk"" collar does not require sealing of the flashing and standoff shaft Slide mounting bolts along slot on SolarMount rail. Insert footing bolts through raised flange on standoff and fasten with flange nuts 05/2007 Rev 15 *PM353030 59 of 179 ® Installation Manual 907 Standoffs and Flashings 10 year limited Product Warranty, 5 year limited Finish Warranty UniRac Inc .warrants to the original purchaser ("Purchaser") of product(s) that it manufactures ("Product1) at the original installation site that the Product shall be free from defects in material and workmanship for a period of ten (10) years, except for the anodized finish, which finish shall be free from visible peeling or cracking or chalking under normal atmospheric conditions for a period of five (5) years from the earlier of I) the date the installation of the Product is completed or 2) 30 days after the purchase of the Product by the original Purchaser (' Finish Warranty') The Finish Warranty does not apply to any foreign residue deposited on the finish All installations in corrosive atmospheric conditions are excluded The Finish Warranty is VOID if the practices specified by AAMA 609 & 610-02 -"Cleaning and Maintenance for Architecturally Finished Aluminum' (www.aamanet.org) are not followed by Purchaser This Warranty does not cover damage to the Product that occurs during its shipment, storage, or installation This Warranty shall be VOID if installation of the Product is not performed in accordance with UniRacs written installation instructions, or if the Product has been modified, repaired or reworked in a manner not previously authorized by UniRac IN WRITING or if the Product is installed in an environment for which it was not designed UniRac shall not be liable for consequential, contingent or incidental damages arising out of the use of the Product by Purchaser under any circumstances If within the specified Warranty periods the Product shall be reasonably proven to be defective then UniRac shall repair or replace the defective Product, or any part thereof, in UniRac's sole discretion Such repair or replacement shall completely satisfy and discharge all of UniRac's liability with respect to this limited Warranty Under no circumstances shall UniRac be liable for special, indirect or consequential damages arising out of or related to use by Purchaser of the Product. Manufacturers of related items, such as PV modules and flashings may provide written warranties of their own UniRac's limited Warranty covers only its Product, and not any related items UniRac, Inc. www umrac com THE 4*§&STANDARD IN PV MODULE RACKS 3201 University Boulevard SE, Suite 110 Albuquerque NM 87106-5635 USA 505.242.6411 505 242 6412 Fax 05/2007 Rev 15 *PM353030 60 of 179 05/2007 Rev 15 *PM353030 61 of 179 Section 6 Electrical Installation 05/2007 Rev 15 'PM353030 62 of 179 05/2007 Rev 15 *PM353030 63 of 179 Solar Array Electrical Installation Recommended Tools and Materials • 7/16", 1/2" and 9/16" socket wrenches • screwdriver, small & medium slotted and Phillips • wire cutter & stripper • wire fish tape • channel lock pliers • y/ EMT or PVC conduit • THWN-2 white, black & green wire • "LB" style pull box • conduit straps and fasteners • tape measure The home-run wiring from the roof top junction box to the DC disconnect switch is to be supplied by the installer due to the unknown distance The installer should pre-measure the home run distance, supply %" conduit and calculate the appropriate wire size to get a power drop of no greater than 2% Refer to NEC table chapter 9 table 8 (wire resistance) and also Table 310 16 in section 310 for the ampacity of a conductor in conduit An extra pull box may be necessary to allow the penetration of the %" conduit into the building envelop of the dwelling This item is not supplied with the GTS package, however, a 'LB' type conduit body or two gang outdoor box could be installed to serve this purpose When the Inverter is mounted inside, it is recommended the GTS back panel be installed close to the penetration point of the dwelling If the penetration is deemed too far by the inspector, then an extra DC disconnect will be installed inside or outside close to the penetration point [NEC 690 14 (C1)l If your GTS power center is installed indoor or away from the utility service entrance, it is possible that your local jurisdiction will require that an additional AC disconnect switch be installed outdoor If that is the case, the switch would normally be located near utility meter, easily accessible by utility company All disconnect switches in the PV system will be required to be clearly/permanently labeled as a photovoltaic disconnect [NEC 690 14 (C 2)] The label on the AC disconnect will indicate the nominal AC voltage, frequency, current, power and also the maximum overcurrent protection rating [NEC 690 52] The label on the DC disconnect will indicate the DC operating voltage and current and also the maximum voltage and short circuit current of the photovoltaic source [NEC 690 53] 05/2007 Rev 15 *PM353030 64 of 179 One Way Distance Calculation for Wire Pair NOMINAL VOLTAGE VOLTAGE DROP TEMP (DEG C) 300 Vdc (MMP Average) 2% 90 C Amps 1 00 200 300 400 500 600 700 800 900 1000 1200 1400 1600 1800 2000 Wire Gauge #14 911 456 304 228 182 152 130 114 101 91 76 65 57 51 46 #12 1445 723 482 361 289 241 206 181 161 145 120 103 90 80 72 #10 2308 1154 769 577 462 385 330 288 256 231 192 165 144 128 115 #8 3678 1839 1226 919 736 613 525 460 409 368 306 263 230 204 184 #6 5828 2914 1943 1457 1166 971 833 728 648 583 486 416 364 324 291 #4 9290 4645 3097 2323 1858 1548 1327 1161 1032 929 774 664 581 516 465 Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft Ft *uncoated copper DC resistance [NEC Tables Section 9 Table 8] 05/2007 Rev 15 *PM353030 65 of 179 05/2007 Rev 15 *PM353030 66 of 179 OJ NJ O CO o I- pico i x 9 O I -M O O-n DD O X I I H m zmo co I I I CO DD"< O X —K -^ o oo R Ol01 I I 05/2007 Rev 15 *PM353030 67 of 179 05/2007 Rev 15 *PM353030 68 of 179 05/2007 Rev 15 *PM353030 69 of 179 05/2007 Rev 15 *PM353030 70 of 179 05/2007 Rev 15 *PM353030 71 of 179 Solar Array Grounding Recommend tools and materials • Cordless drill and #19 or 5/32 drill bit • Medium #2 Philips and flat head screw driver • Wire cutters • No-Ox coating Grounding the Solar Modules All solar modules in a string must be tied together using a single grounding conductor The NEC also requires that a solar module should be able to be removed without breaking the grounding conductor for that string Each solar module will attach to the continuous ground using a tin-plated copper lay-in lug that is UL listed for outdoor use One lug will be fastened to the frame of each solar module using a 10-32 1/2" stainless steel screw A self-drilling 'tek' screw is not acceptable for this application This ground connection can be done while installing each solar module onto the supporting rails It will save time to fasten the lay-In lug onto each solar module frame prior to placement onto roof structure See drawings in this section In addition to grounding the solar modules, it is also necessary to bond all SolarMount rails together by attaching a lay-in lug on the side of each rail Once the lugs are installed, the extra grounding wire supplied with the ground kits can be use to interconnect the rails It is recommended that any exposed connections, such as the ground connections, should be coated with durable anti-oxidant coating Sizing of Equipment Ground Conductor The size of the grounding conductor that is not protected by GFDI (i e DC side) should be sized to be at least 125% of the short circuit currents originating from the photovoltaic source [NEC 690 45] The size of a grounding conductor that is of a source protected by GFDI (le AC side) the grounding conductor should be sized as per NEC table 250 122 DC Grounding Electrodes and Grounding Electrode Conductors In most systems, both the AC and DC ground will be bonded together at the dwellings mam grounding rod [NEC 690 47 (C 2)] If that is the case than the grounding electrode conductor will be sized as per [NEC 250 66](ac) and [NEC 250 166 ](dc) This means that your direct ground rod connection from your DC disconnect (or inverter) to your ground rod will to be at least AWG#8 and/or not smaller than the largest conductor on the DC side If the array is mounted away from the dwelling (e g ground or pole mounted), then an additional grounding electrode (DC side ground rod) may be required The DC side ground rod would be installed as close as possible to the PV array and the grounding electrode conductor would be sized according to [NEC 250 166] If a second ground rod is necessary, the two grounding rods will need to be tied together in accordance to [NEC 690 47(C 1)] 05/2007 Rev 15 *PM353030 72 of 179 05/2007 Rev 15 *PM353030 73 of 179 05/2007 Rev 15 *PM353030 74 of 179 05/2007 Rev 15 *PM353030 75 of 179 Section 7 Power Center Installation 05/2007 Rev 15 *PM353030 76 of 179 05/2007 Rev 15 *PM353030 77 of 179 GTS Power Center (or Inverter) Installation Recommended Tools and Materials • Cordless drill w/ set of drill bits • Measuring Tape • (6x) lag bolts or wall anchors with machine screws • 7/16" socket wrench • channel lock pliers • wire cutters and stripper • hex key set • %" EMT or PVC conduit and straight fittings • conduit bender • AC/DC multi meter-true RMS-20A • Wire fish tape • AC Breaker • Medium Flat head and Philips screw driver The GTSPC includes the mam DC/AC Inverter panel and safety disconnects The Power Center is packaged on an aluminum plate pre-wired with AC & DC disconnects switches and will allow for up to three DC input circuits Wiring is pulled up to the inverter in non-metallic conduit The mounting plate includes captive bolts to simplify the placement of the inverter (inverter supplied separately) The Power Center and the inverter are designed to be installed outside but can also be mounted inside as well If mounted outdoors, Power Center (and/or inverter) should be mounted in the shade close to the mam service entrance, ideally on the north side of the building If the unit is installed inside, the unit should be installed in area where the temperature can be maintained at less than 45°C The unit should not be installed in a restrained space without proper air circulation (le closet) or where temperature can reach extreme cold For mounting the Power Center to the wall, use Vi" lag bolts into wood studs, if you are mounting the Power Center on masonry or block wall, use lead expansion shield type inserts for %" lag or machine screws The mounting holes of the Power Center are spaced at 16" on center Install the inverter onto the Power Center mounting plate by first mounting the inverter hanger panel onto the power center with the bolts supplied with the Power Center Once mounted, it is recommended to have two persons lift the inverter into position on the Power Center or on the wall as it can weight up to 140lbs Once the inverter has been secured, complete the wiring into the inverter's wiring compartment Connect the solar array by installing 3/4" conduit to the DC Disconnect switch hub or knock-out When completing the wiring, it is recommended to leave a few extra inches of wires so that they can be quickly maintained in case the connection would corrode 05/2007 Rev 15 *PM353030 78 of 179 Main Service Panel The Mam Service Panel will need to have the physical space to accept an additional AC breaker to accommodate the GTS system Please refer to the Electrical Diagram supplied with your system or with the system diagram in Section 4 for the appropriate breaker size The Mam Service Panel sum of source current will also need to be kept under the busbar rating of the manufacturer If the system is installed in a dwelling, the NEC does allow the sum of current sources to exceed the rating of the busbar by more than 120% of the rating [NEC 690 64] If the existing service entrance is a 100A service, the additional PV breaker cannot exceed 20A and in a 200A service entrance, the breaker cannot exceed 40A If the additional breaker for the GTS system exceeds the 120% current headroom or does not have the physical space to be inserted in the panel, a sub-panel will need to be installed on the line side of the Service Panel 05/2007 Rev 15 *PM353030 79 of 179 Installation Chapter 2, "Installation", provides information about planning for and installing the GT Inverter It contains information to help you plan wire routes, AC and DC connections, and find a suitable location for installation It also discusses requirements for grounding the GT Inverter and your PV array Procedures are provided for installing the Xantrex Grid Tie Solar Inverter The topics in this chapter are organized as follows • "Installation Options" on page 2-2 • "Planning the Installation" on page 2-2 • "Preparing for the Installation" on page 2-12 • "Mounting the Inverter" on page 2-15 05/2007 Rev 15 *PM353030 80 of 179 Installation Installation Options The GT Inverter may be installed as a single inverter for a single P V array of one or two PV strings, or in a multiple inverter configuration for multiple PV arrays (see Figure 2-1 for diagrams of both options) Single Inverter Installation In this configuration, a single inverter collects the harvested solar energy and routes the power to the mam utility service panel to be used by the loads Any surplus power not used by the loads will be directed to the utility grid Multiple Inverter Installations If multiple inverters are used, each inverter must be wired to an independent PV array In this configuration, each inverter collects the harvested solar energy from a separate PV array and routes the power to the mam utility service panel to be used by the loads Any surplus power not used by the loads will be directed to the utility grid Communications between inverters can be enabled by installing network cabling to the inverter RJ45 ports See "Connecting Network Cable Between Multiple Inverters" on page 3-16 Planning the Installation The following issues need to be considered when planning for an installation using the GT Inverter See the specified sections for more information "Inverter Location" on page 2-4 • "PV Array Requirements" on page 2-5 "Grounding Requirements'7 on page 2-8 "Routing the Wires" on page 2-11 Ensure that you have obtained all permits required by local authorities or utilities before commencing installation 2-2 975-0245-01-01 05/2007 Rev 15 *PM353030 81 of 179 Planning the Installation Utility Grid Single Inverter Installation Photovoltaic Panels - PV Array ,. PV String *1 Utility Grid Multiple Inverter Installation PhotovoltaicPanels Multiple PV Arrays GT Inverter#1 | ,, GTInverter#2 DC converted to AC PV Array #1 Figure 2-1 Installation Options Overview 975-0245-01-01 2-3 05/2007 Rev 15 *PM353030 82 of 179 Installation Inverter Location WARNING: Burn hazard Do not install in a location where people can accidentally come into contact with the front of the inverter High temperatures can be present on the face of the inverter, causing a potential burn hazard In extreme conditions, the GT Inverter chassis can reach temperatures over 70° C (158° F), which can cause skin burns if accidentally touched Ensure that the GT Inverter is located away from normal traffic areas Inverter failure due to improper installation will void the inverter warranty Consider the following when determining where to install the inverter Fire Safety Indoor/Outdoor Orientation Temperature Ground Clearance Distance Do not install anywhere near combustible or flammable materials The GT Inverter uses a Type 3R-rated enclosure (vertical mount only) that can be mounted indoors or outdoors (Type 3R enclosures are intended for outdoor use primarily to provide a degree of protection against falling rain, and to be undamaged by the formation of ice on the enclosure ) While the 3R-ratcd enclosure protects the GT Inverter from moisture, outdoor installations should be located away from lawn sprinklers and other sources of spray The GT Inverter must be mounted vertically on a wall or pole Do not mount the GT Inverter horizontally Ensure that the GT Inverter is mounted in a location where the ambient temperature range is -25° to +65° C (-13° to +149° F) At extreme hot or cold temperatures, the front panel LCD may not function normally At higher temperatures, the GT Inverter may derate power See"Output Power vs Ambient Temperature at Various DC Voltages" on page A-4 and "Environmental Specifications" on page A-6 Outdoors, the GT Inverter requires at least 100 cm (39 inches) of clearance between the bottom of the unit and the ground Indoors, it is recommended that the same clearance between the bottom of the unit and the floor be used To minimize copper losses, ensure that wire lengths between the PV array and the Gr Inverter and between the inverter and the Main Utility Service Panel are kept to a minimum Maximum distances will depend on wire gauges used and PV array output voltages 2-4 975-0245-01-01 05/2007 Rev 15 'PM353030 Debris free PV Array Requirements 83 of 179 Planning the Installation Excessive debris (such as dust, leaves, and cobwebs) can accumulate on the unit, interfering with wiring connections and ventilation Do not install in a location where debris can accumulate (under a tree, for example) WARNING: Shock hazard Whenever a PV array is exposed to sunlight, a shock hazard exists at the output wires or exposed terminals To reduce the risk of shock during installation, cover the array with an opaque (dark) material before making any connections General Recommendations It is important that the PV array is installed correctly to the manufacturer's specifications and to local code requirements Equipment and Installation Recommendations Important The PV array should be free of shade This requirement includes even small obstructions such as vent pipes, chimneys and power lines A small amount of shade can have a disproportionately high impact on system performance Equipment recommendations installation recommendations All electrical equipment should be listed for the voltage and current ratings necessary for the application. All wiring should be sized correctly to minimize voltage drop All exposed wires or conduits should be sunlight resistant All required overcurrenl protections should be included in the system and accessible for maintenance Depending on the installation, an external disconnect may be required if the inverter is installed in a location not easily accessible to utility or fire personnel Consult local authorities for additional information Integral roofing products should be properly rated All electrical terminations should be fully tightened, secured, and strain relieved as appropriate All mounting equipment should be installed according to the manufacturer's specifications All roof penetrations should be sealed with an acceptable sealing method that does not adversely impact the roof warranty All wires, conduit, exposed conductors and electrical boxes should be secured and supported according to code requirements 975-0245-01-01 2-5 05/2007 Rev 15 *PM353030 84 of 179 Installation Voltage and MPPT Requirements MPPT operational window The MPPT software maximizes the output energy of solar arrays as long as the operating voltage is within the MPPT operational window Ensure that the PV array used in the system operates within the MPPT operational window Effects of array voltages outside of the MPPT operational window are shown in Table 2-1 Table 2-1 MPPT Voltage < 195 Vdc 195to550Vdc 550 to 600 Vdc "> 600 Operational Window Effect of Array Voltage Operating voltage will be shifted to 195 Vdc, the array will not be at its maximum power point Maximum harvest of solar energy Will not allow maximum harvest of solar energy Will shut down and may cause damage to the inverter, stops selling surplus energy Inverter Mode Low power MPPT window Power derating Shutdown Voltage The maximum power point voltage of a string connected to the GT Inverter should requirements be a minimum of 195 Vdc If it is less than 195 Vdc, the inverter will continue to operate, but it will regulate the PV voltage to 195 V Because the array will not be operating at its maximum power point, this may result in lower than expected energy harvest Maximum PV The solar array should be sized such that its maximum power output docs not Power exceed the limits of the MPPT operational window (195 to 550 Vdc) See "Guidelines for Matching PV Array Size to Xantrex Grid Tie Solar Inverter Input" The array voltage should never exceed 600 VOc (open circuit voltage) under any thermal condition Likewise, ensure that the Isc (short circuit current) rating of the array at any temperature does not exceed the short circuit current rating of the inverter 2-6 975-0245-01-01 05/2007 Rev 15 •PM353030 85 of 179 Planning the Installation Guidelines for Matching PV Array Size to Xantrex Grid Tie Solar Inverter Input For determining the number of panels required in the PV string (panels connected in series), you must ensure that the following requirements are met 1 To avoid damage to the inverter, ensure that the PV array output will never exceed 600 Vdc under any conditions 2 Do not exceed the maximum array short circuit-current rating marked on the inverter 3 To achieve maximum energy harvest from your array, ensure that the VMP (voltage at maximum power) does not drop below 195 Vdc or increase above 550 Vdc under most conditions Guidelines to help you meet these requirements • Consider the expected VOc of the string under all possible conditions The panel manufacturer provides a VOc rating per panel, but it is usually rated at 25°C (77°F) Ensure that the VOc rating at the coldest ambient temperature does not exceed 600 Vdc Panel voltage increases in cold temperatures—the panel manufacturer should be able to provide a coefficient of voltage increase per degree The NEC also has required temperature/voltage deratings that must be used, these can be found in Table 690 7 of the 2002 NEC handbook You need to determine the coldest temperatures expected on the site, and size the array strings accordingly The array's maximum DC voltage in coldest expected temperature, with both manufacturer coefficient and NEC derating, must not exceed 600 Vdc to prevent inverter damage • Panel voltage decreases in high temperatures This will affect the panels' VMP. Again, the manufacturer's coefficient must be used with the highest expected temperature to determine the minimum VMPL Once you know the specifications of your panels, all these factors will help determine the maximum and minimum number of panels that can be used Note The GT PV array sizing tool is available at www xantrcx com 975-0245-01-01 2-7 05/2007 Rev 15 *PM353030 86 of 179 Installation Grounding Requirements AC Grounding North America Elsewhere PV Grounding WARNING: Shock hazard The GT Inverter must be grounded by connection to a grounded permanent wiring system The GT Inverter must be connected to a grounded, permanent wiring system via the GT Inverter ground bar See Figure 2-2 for the location of the GT Inverter ground bar The ground bar must also be connected to the main utility breaker panel ground bar and to the house grounding rod according to NEC requirements In other locations, AC grounding is governed by local codes Consult with the local utility for specific grounding requirements The GT Inverter is designed to have all PV positive, negative, and ground conductors connected inside its wiring box The PV equipment ground should be connected to the GT Inverter ground bar The size for the conductor is usually based on the size of the largest conductor in the DC system A DC grounding electrode conductor may be required by the Authority Having Jurisdiction (AHJ) Use the GT Inverter ground bar for this connection Important In most models, the negative PV conductor is internally bonded to the ground system within the inverter's ground fault detection circuit Inverter models marked with the "-POS" suffix are positive grounded and have the positive PV conductor internally bonded to the ground system through the inverter's ground fault protection circuit It is important that the negative (or positive) PV conductor is not bonded to the ground at any other point in the system Long Distance Grounding If the PV array is more than 30 meters (100 feet) from the inverter, then there must also be a direct connection from the array frame to an earth ground next to the array A connection between this ground and the primary earth ground connection via a buried wire between the two points is also necessary (see Figure 2-3) 2-8 975-0245-01-01 05/2007 Rev 15 *PM353030 87 of 179 Planning the Installation Lightning Protection Reduce the risk of lightning damage by using a single-point grounding system In this system, all ground lines terminate at the same point—the primary earth ground This point normally is the mam utility ground installed by the utility company to provide a ground for the house wiring (see Figure 2-4) This ground usually consists of a copper rod driven 1 5 to 2 5 meters (6 to 8 feet) into the earth PV Array Main Utility Service Panel L1 BD L2 (NEUTRAL :",-=:~ivr^'?- •:.v'.."v:.y.'?.'i...! GROUND B0eeeeeefe>eeel • ] ! - E I Neutral ^ -to- Ground Bond I AC Ground •] r3f!S SEK^ KSKJ BSKH SS&-S TO^i HS^: * BBSS «K3 BK^ «^I KK3 mst KtSS tlssa 1SSK I DC/AC Disconnect Switch Pnmary Earth Ground DC Ground if required by AHJ Figure 2-2 Basic Grounding Overview 975-0245-01-01 2-9 05/2007 Rev 15 *PM353030 88 of 179 Installation PV Array When the distance between the PV Array and the GT Inverter is greater than 30 m (100 ft), the array should have its own earth ground, which should be connected to the Primary Earth Ground by a buried wire Check your local codes for grounding requirements Mam utility Service Panel L2 Neutral -to- Ground Bond Primary Earth Ground Figure 2-3 Long Distance Grounding Overview 2-10 975-0245-01-01 05/2007 Rev 15 *PM353030 89 of 179 Planning the Installation PV Array Main Utility Service Panel PV String #1 PV String #2 B5M KRi;1 KB* iXantrex-'GTInyerter _-; Wiring Box ' • Neutral -to- Ground Bond Primary Earth Ground Figure 2-4 Grounding With Extra Lightning Protection Overview Routing the Wires Typical Determine all wire routes to and from the GT Inverter Typical routing configurations configurations include • AC wiring from the GT Inverter to the main utility service panel • DC input wiring from the PV array to the GT Inverter DC ground from the PV array to the Primary Earth Ground All wiring and installation methods should conform to applicable electrical and building codes For installations in the United States, the National Electrical Code (NEC) and local codes apply For installations in Canada, the Canadian Electrical Code (CEC) and local codes apply For all installations, local utilities may have additional requirements 975-0245-01-01 2-11 05/2007 Rev 15 *PM353030 90 of 179 Installation WARNING: Shock hazard Check for existing electrical or plumbing prior to drilling holes in the walls Conduit holes/knockouts Pre-plan the wire and conduit runs Dual knockouts for 35 mm (1 3/8 inch) or 27 mm (1 inch) conduit holes are located on the bottom and back of the wiring box—four dual knockouts in total Two threaded 27 mm (1 inch) conduit holes arc located on each side of the wiring box (Figure 2-5) For maximum safety, run AC, DC, and communication wires in separate conduits 35 mm (1 3/8") and 27 mm (1") dual knockouts 27 mm (1") threaded conduit holes Bottom \ DC/AC Disconnect Switch Figure 2-5 Conduit Hole and Knockout Locations Side Preparing for the Installation Ensure your local utility is consulted for any requirements for connecting to or returning power to the grid Obtain all permits necessary to complete the installation Consult your local and national electrical codes for more information This section includes the following topics "Wiring" on page 2-13 • "Circuit Breakers and Disconnect Switch" on page 2-13 "Other Materials Needed" on page 2-14 • "Equipment Needed" on page 2-14 Important In this manual "wiring" and "wires" are used m reference to both AC and DC wiring/cabling and wires/cables 2-12 975-0245-01-01 05/2007 Rev 15 *PM353030 91 of 179 Preparing for the Installation Wiring Wire size and length will be determined by the location of each component and their relative distance to each other Wire sizes may also be affected by whether or not conduit is used Recommended wire Strip all wires 9 mm (3/8 inch) stripping length Acceptable wire The AC and DC terminal blocks in the GT Inverter accept wire sizes from sizes #14AWGto#6AWG Important Wiring should not be undersized Undersized wiring can result m significant power losses and reduction in system efficiency Circuit Breakers and Disconnect Switch The following circuit breakers, disconnect switch and fuse are required for installing this equipment AC Circuit Breaker Requirements In North America, the mam utility service panel must dedicate a double pole breaker to operate each GT Inverter installed This breaker must be sized to handle the rated maximum output voltage and current of the GT Inverter (sec "Electrical Specifications", "Output" on page A-2) DC/AC Disconnect Switch The wiring box includes a PV/Utility disconnect switch that switches both AC and DC at the same time WARNING Shock hazard Do not remove the wiring/disconnect box The 600 volt DC/AC disconnect in the wiring box meets NEC Article 690 It is a non-serviceable component and shall remain in place Removal can expose energized conductors Use caution when working around sources of DC power Although the DC/AC disconnect switch disconnects the inverter from DC power, hazardous voltages from paralleled PV strings may still be present upstream of the switch Ground Fault Fuse The GT Inverter is equipped with a 600 volt 1-Amp ground fault protection fuse (replace with Littelfuse KLKD 1 or equivalent) 975-0245-01-01 2-13 05/2007 Rev 15 *PM353030 92 of 179 Installation WARNING: Shock hazard Do not attempt to service the ground fault protection fuse yourself This should only be done by qualified service personnel, such as certified electricians or technicians Other Materials Needed Equipment Needed Mounting support material, such as plywood or poles Conduit for wire runs and appropriate fittings/bushings Wood screws and anchors for screws, depending on mounting surface Wire cutters/wire cnmpcrs/wire stoppers Assorted screwdrivers, drill, etc Level Digital Voltmeter Frequency counter (optional, for troubleshooting) 2-14 975-0245-01-01 05/2007 Rev 15 'PM353030 93 of 179 Mounting the Inverter Mounting the Inverter Overview A WARNING: Fire, Shock and Energy Hazards ' * Before installing the GT Inverter, read all instructions and cautionary markings located in this manual, on the PV array, and on the main service panel General installation steps There are four mam steps in the installation of the GT Inverter 1 Mounting the GT Inverter (this chapter) 2 Grounding the PV array (see your PV equipment documentation) 3 Making the DC connections from the PV array to the GT Inverter ("Connecting the DC Wiring" on page 3-4) 4 Making the AC connections from the GT Inverter to the main utility service panel ("Connecting the AC Wiring" on page 3-7) Figure 2-6 summarizes these four steps Mam Utility Service Panel Xantrex GT Inverter Figure 2-6 Installation Overview 975-0245-01-01 2-15 05/2007 Rev 15 •PM353030 94 of 179 Installation In this chapter only the first step, mounting the inverter and installing accessories, is described Mounting steps Instructions for mounting the GT Inverter are described in the following sections • "Preparing to Mount the Unit" on page 2-16 "Installing the Mounting Bracket" on page 2-17 "Mounting the Inverter on the Bracket" on page 2-22 Multiple inverter Mounting instructions for multiple inverters are described in "Mounting Multiple instructions Inverters" on page 2-23 Special wiring instructions for multiple inverter installations are described in "Connecting Multiple Inverters" on page 3-9 Preparing to Mount the Unit Dimensions and Knockout Locations The dimensions of the inverter and the mounting bracket and some of the knockout locations on the wmng/disconnect box are shown m Figure 2-7 Four 27 or 35 mm (1 or 1 3/8 inch) dual knockouts are provided on the back and bottom of the unit to accommodate wiring two on the bottom, on either side of the DC/AC Disconnect Switch • two on the back of the wiring/disconnect box Four 27 mm (1 inch) conduit holes on the sides of the wiring/disconnect box (two on each side) are filled with plastic plugs, which can be removed to insert conduit nipples as required for multiple inverter installations One or two of these side conduit holes may be used to accommodate Xanbus network cables connected between multiple inverters CAUTION Equipment damage If your installation location requires that you drill additional conduit holes into the wiring/disconnect box, ensure that there arc no metal shavings left inside the unit These could cause a short circuit when the unit is operating Knockout Preparation Remove your choice of knockouts from the wiring box to facilitate conduit installation for wire runs This is much easier to do prior to mounting the inverter Important Ensure there are no metal shavings left inside the unit after removing the knockouts These could cause a short circuit when the unit is operating Be sure to install bushings or conduits in the knockout holes to protect the wires from damage Important If installed outdoors, conduit must be sealed where it enters the wiring box 2-16 975-0245-01-01 05/2007 Rev 15 'PM353030 95 of 179 Mounting the Inverter Side view 27cm (1") conduit holes with threaded caps, on both sides Dual 3 5 cm or 2 7 cm (1 3/8" or 1") knockouts (on back panel) Front view 55 (21 5/8) 69 (27 1/2) 726 (21 5/8) Dual 3 5 cm or 2 7 cm (1 3/8" or 1") knockouts _403 (157/8)" 62 (27/16)-279(11) All measurements in cm (inches) 52(2) Figure 2-7 Dimensions of GT Inverter and Knockout Locations Installing the Mounting Bracket The mounting bracket for the GT Inverter allows the unit to be easily mounted and dismounted for servicing It has two hooks that match corresponding hooks on the back side of the inverter and wiring box The inverter can be separated from the wiring/disconnect box and removed from the bracket, leaving the wiring/disconnect box in place 975-0245-01-01 2-17 05/2007 Rev 15 *PM353030 96 of 179 Installation Rectangular slots x 25 08 x 3 (5/16 x 1 3/16) ~ Mounting bracket |«- 253(10) H Back side of the inverter Mounting flanges Mounting slots for securing the inverter> Figure 2-8 Mounting Bracket and GT Inverter Mounting flanges All measurements in cm (inches) Clearance Requirements For optimal and safe operation, ensure there is adequate clearance around the inverter The minimum clearance recommendations in Table 2-2 assume a vertical mounting If clearances are reduced below these mimmums, rated power may not be achieved Table 2-2 Inverter Clearance Requirements Location Minimum Clearance Above Below Inverter Bracket In front On sides 30cm (12 inches) Outdoors • 100 cm (39 inches) 110 cm (43 inches) Indoors the same clearances are recommended but not required The inverter extends below the bracket by approximately 10 cm (4 inches) Sufficient room to allow for easy access to read the display and to prevent accidental contact with hot surface Units can be mounted side by side with no clearance between them, but 15 cm (6 inches) of clearance around the outermost two units is recommended In hot climates, some clearance between units may be needed to prevent thermal derating 2-18 975-0245-01-01 05/2007 Rev 15 *PM353030 97 of 179 Mounting the Inverter A WARNING- Shock hazard Before drilling holes to mount the GTT Inverter, ensure there are no electrical wires or plumbing in this area A WARNING: Personal injury t—l—• The GT Inverter weighs approximately 20 kg (45 Ibs ) Always use proper lifting techniques during installation to prevent personal injury f WARNING: Explosion hazard Do not store combustible or flammable materials anvwhere near the inverter Surfaces for Mounting Mounting on poles or rails Mounting to wallboard with support Mounting to siding using wall studs Mounting to concrete surface The GT Inverter weighs approximately 20 kg (45 Ibs ) The supporting surface must be strong enough to handle 75 kg (160 Ib ) If the supporting surface is not strong enough to handle that weight, then supporting material such as a sheet of plywood can be used to enhance the strength of the mounting surface The GT Inverter can be mounted to a vertical surface such as wallboard, wood siding, concrete wall or pole assembly • See "Mounting on Poles or Rails" on page 2-20 Ensure the bottom of the unit is a minimum of 100 cm (39 inches) from the ground if mounted outdoors Installation onto wallboard requires either the use of a supporting material such as plywood or securing the mounting screws to supporting wall studs Use at least two screws and anchors to secure the unit to the supporting material If mounting to exterior siding using a wall stud for support, the plywood backing will not be needed Use at least two lag screws to secure the unit to the supporting material Ensure the screws entei the stud at least 4 cm (1 5 inches) to adequately support the weight of the unit See "Mounting on Wallboard, Siding or Concrete" on page 2-21 • If mounting the unit on a concrete surface using anchors with no supporting material, use four screws and anchors, instead of two, to adequately secure the unit and distribute the weight Important Local codes may impose additional mounting requirements in earthquake or other high-nsk areas Important Other than the mounting bracket, no mounting hardware is supplied with the GT Inverter It is recommended to use 6 mm (% inch) diameter fasteners However, because mounting surfaces can vary, installers must select appropriate hardware for each installation 975-0245-01-01 2-19 05/2007 Rev 15 *PM353030 98 of 179 Installation Mounting on Poles or Rails To mount the unit using poles 1 Ensure that poles or rails are securely assembled in place If using horizontal rails, three rails are required two for the mounting bracket and a third for securing the bottom edge of the inverter wiring box (see Figure 2-9) 2 Connect the mounting bracket vertically to the poles or rails (Figure 2-9) Be sure to use at least two bolts to secure the mounting bracket to the support Position the lower edge of the bracket a minimum of 110 cm (43 inches) above the floor or ground 3 If using a single vertical pole, ensure that the inverter is secure and unable to rotate around the pole ©Mounting Bracket 1 H X \ 34 Sj •9' / \ 03 ^ ^ 1 '"' - .SSE» ^™^p^to». ;• "i^x^•^^w. f. .*"W . . •''. ' "^ •: . i '» I ' 110(4 Ground/ Floor i) 1 "* i itm :® f |i€>s«;-:®«« \. jf At least 2 bolts to secure bracket to poles/rails ^ ^ |i©:::®;f@'<i j j^^ cars tessa < / SE^J ^ • ; ' -Ctss o..^.. • - - • -* "4 g>|jj|. (18 5) •<•&•:. 9) 15 (59) ::@ ® ;®:® «€)«•©©; For securing -^ the bottom of the wiring box 100 All measurements in cm (inches) Ground / Floor i€?M€K (39) Figure 2-9 Examples of Mounting on a Pole or Rails 2-20 975-0245-01-01 05/2007 Rev 15 •PM353030 99 of 179 Mounting the Inverter Mounting on Wallboard, Siding or Concrete To mount the GT Inverter to wallboard, siding, or concrete- Locate the area where the GT Inverter is to be installed Install backing support material if required See Figure 2-10 i 406(16)h—oc —H 1 2 ;&v.:*± TSfe..;!7--"' | • L • *' ? ^lAf least 2 screw's i *--;i^:=» with washers to ' "'" '?* secure bracket plywood J •"!>£?„- 15 (6)^t - >'T - S i — •> < - * 110(43) Ground / Floor All measurements in cm (inches) Single GT Inverter Multiple GT Inverters Figure 2-10 Installing the Mounting Bracket using Plywood Support 3 Using a level, place the mounting bracket against the wall surface at least 110 cm (43 inches) from the ground Sec Table 2-2 on page 2-18 to ensure minimum clearance requirements are met 4 Mark the location for mounting screws if using a wall stud for support At least four mounting screws and anchors are needed for concrete installations or wallboard installations where no wall studs are available for support For multiple inverter installations, the brackets should be mounted at least 15 cm (6 inches) apart, or at least 40 6 cm (16 inches) on-center 5 Remove the bracket and drill the holes using an appropriately sized drill bit Drill appropriately sized holes for screws or anchors 6 Secure the bracket to the supporting surface using at least two screws and washers 975-0245-01-01 2-21 05/2007 Rev 15 *PM353030 100 of 179 Installation Mounting the Inverter on the Bracket Mounting a Single Inverter To mount the inverter on the mounting bracket- 1 Place the GT Inverter's mounting hooks, located on the back of the enclosure, over the bracket and ensure the inverter is seated properly, as shown in Figure 2-11 2 After the unit is correctly seated on the bracket hooks, locate the mounting slots in the flange below the wiring box and mark the location on the wall for securing screws 3 Remove the inverter and drill pilot holes in the wallboard or siding for the securing screws 4 Reinstall the GT Inverter on the bracket and secure the bottom of the unit with appropriate screws or anchors, and tighten Slide the mounting hooks on the inverter over the hooks on the mounting bracket flange with mounting slots Bracket hooks 100 cm (39") Ensure the inverter is seated properly on the mounting bracket Ground/floor Figure 2-11 Proper Placement of the Inverter on the Mounting Bracket 2-22 975-0245-01-01 05/2007 Rev 15 •PM353030 101 of 179 Mounting the Inverter Mounting Multiple Inverters As shown in Figure 2-10, inverters can be mounted side by side on wallboard or a plywood support Conduit nipples should be installed on one side of the first inverter before mounting on the bracket Ensure that the sealing ring is located on the conduit nipple between inverters, i e , on the outside of the wiring box The lock nut is attached after the nipple is inserted into the conduit hole of the second inverter 975-0245-01-01 2-23 05/2007 Rev 15 *PM353030 102 of 179 2-24 05/2007 Rev 15 *PM353030 103 of 179 Wiring the Inverter Chapter 3, "Wiring the Inverter", provides procedures for making DC and AC wiring connections, and grounding the GT Inverter and the PV array Instructions for wiring multiple inverters are also provided The topics in this chapter are organized as follows "Accessing the Wiring Terminals" on page 3-2 "Connecting the DC Wiring" on page 3-4 "Connecting the AC Wiring" on page 3-7 "Connecting Multiple Inverters" on page 3-9 05/2007 Rev 15 *PM353030 104 of 179 Wiring the Inverter Accessing the Wiring Terminals You must remove the GT Inverter wiring box cover to access the terminal blocks, ground bar and communications ports (for connecting multiple inverters) To remove the wiring box cover. 1 Using a Phillips screwdriver, remove the two screws on the bottom side of the wiring box and set in a safe place (see Figure 3-1 for location of screws) 2 Lift the cover off the wiring box When replacing the wiring box cover, be careful not to pinch any wires in the wiring box Insulating barrier Wiring box cover screws Figure 3-1 Removing the Wiring Box Cover AC and DC connections are made at the wiring terminals shown in Figure 3-2 The clear plastic insulating barrier inside the wiring box is a permanent component It is intended to separate the high-voltage AC and DC wiring from any communications cabling and to prevent wiring from coming into contact with the wmng box cover When wiring the unit, it is necessary to pull the cover back to access the wiring terminals After completing the wmng, replace the insulating barrier to its original position 3-2 975-0245-01-01 05/2007 Rev 15 *PM353030 105 of 179 Accessing the Wiring Terminals DC Terminals for connecting PV strings PV + AC Terminals for connecting to mam utility service panel DC/AC Disconnect Switch Figure 3-2 AC and DC Terminal Block Location in the Wiring Box 975-0245-01-01 3-3 05/2007 Rev 15 'PM353030 106 of 179 Wiring the Inverter Connecting the DC Wiring WARNING Shock hazard Whenever a PV array is exposed to sunlight, a shock hazard exists at the output wires or exposed terminals To reduce the risk of shock during installation, cover the array with an opaque (dark) material and ensure that the DC/AC Disconnect Switch is set to OFF before commencing any wiring See Figure 3-3 WARNING: Shock hazard The 600 volt DC/AC disconnect in the wmng box meets NEC Article 690 It is a non-serviceable component and shall remain in place Removal can expose energized conductors A. WARNING: Shock hazard ^—-— Use caution when working around sources of DC power Although the DC/AC disconnect switch disconnects the inverter from DC power, hazardous voltages from paralleled PV strings may still be present upstream of the switch Before servicing a PV string, isolate each string by completely removing PV wiring from the inverter terminal block OFF ON Figure 3-3 DC/AC Disconnect Switch Positions 3-4 975-0245-01-01 05/2007 Rev 15 *PM353030 107 of 179 Connecting the DC Wiring The following procedure is illustrated in Figure 3-4 If there is more than one PV string, label the positive and negative wire pairs appropriately (for example PVl-Stnng #1 POS, PVl-Srnng #1 NEC, PVl-Strmg #1 GND, PVl-Strmg#2POS, etc) To wire the PV array to GT Inverter. 1 Remove the wiring/disconnect box cover (see page 3-2) 2 Install DC conduit from the PV stnng(s) to the GT Inverter wiring box, through one of the knockout holes 3 Route the wires from the PV stnng(s) through the conduit and into the wiring box 4 Connect the DC Ground from each PV string to the GROUND bar in the wiring box 5 Connect the POSITIVE (+) wire from the PV1 string #1 to one of the PV+ terminals in the wiring box Double check that the wire is in the proper location and tighten the screw 6 Connect the NEGATIVE (-) wire from the PV1 string # 1 to one of the PV- terminals Double check that the wire is in the proper location and tighten the screw 7 Repeat for the PV 1 string #2, if there is one a) Connect the POSITIVE (+) wire from the PV1 string #2 to the unused PV+ terminal b) Connect the NEGATIVE (-) wire from the PV1 string #2 to the unused PV- terminal Double check that the wires are in the proper locations and tighten the screws 8 If required, connect the DC ground electrode conductor tot he DC or AC ground electrode as per NEC 690 47 9 Ensure all connections are correctly wired and properly torqued according to values shown in Table 3-1 Table 3-1 Torque Values for Wires* AWG 14tolO 8 6 Wire Size ! mm2 I 2 5 to 60 | 100 1 160 m-lb 35 40 45 Torque Nm 40 45 5 1 *Use copper conductors only 975-0245-01-01 3-5 05/2007 Rev 15 *PM353030 108 of 179 Wiring the Inverter PV1 String #2 PV Array 1 DC/AC Disconnect Switch i mm msu mr. mrt m^ KS> iss.3 sss " *! B= iara sas Bra mn an SBK B ~ ESS OK sea i DC Ground if required by AHJ H Figure 3-4 DC Connections for Multiple PV Strings Important Depending upon installation and local codes, fusing and/or a combiner box may be required This fusing and combiner box are to be provided by the installer Important A DC grounding electrode conductor may be required by the AHJ Check local codes before installation 3-6 975-0245-01-01 05/2007 Rev 15 *PM353030 109 of 179 Connecting the AC Wiring Connecting the AC Wiring WARNING- Shock hazard!\AC utility wiring to the GTT Inverter unit is performed directly at the main breaker panel This should be done only by a qualified installer or electrician ,f\ WARNING: Shock hazard Before wiring the GT Inverter, ensure the main breaker in the primary utility breaker box is switched OFF Switch this breaker ON only after all wiring is completed as instructed in the procedures Important Jn the United States, the National Electrical Code (NEC) requires the inverter to be connected to a dedicated circuit and no other outlets or devices may be connected to this circuit The NEC also imposes limitations on the size of the inverter and the manner in which it is connected to the utility grid The circuit breakers that are used in the mam panel that feed the inverter circuit must be for back-fed operation and labeled as such The GT Inverter can be connected to a single bi-directional meter, or to dual meters, where one meter indicates power used and the second meter indicates power sold (power supplied back to the utility) Consult with the local utility to determine the proper components to install, and obtain any permits required prior to installation The following procedure is illustrated in Figure 3-5 Important Neutral conductor wiring is not required in this installation 975-0245-01-01 3-7 05/2007 Rev 15 *PM353030 110 of 179 Wiring the Inverter To wire the mam utility service panel to the GT Inverter: 1 Install conduit from the mam utility service panel to the wiring/disconnect box of the GT Inverter Run the two HOT wires (LI and L2) and ground wire from the service panel through the conduit and into the inverter wiring box 2 Install or use an existing double-pole 20-Amp circuit breaker (or two single-pole breakers, ganged) in the mam utility service panel, and ensure that the breakers are set to OFF 3 Connect the ground wire (green or bare copper) from the ground bar in the main utility service panel to the GND bar in the wiring box 4 Connect the LI HOT wire (black) from the double-pole breaker installed in the mam utility service panel, to the LI GRID terminal in the wiring box 5 Connect the L2 HOT wire (red) from the double-pole breaker installed in the main utility service panel, to the L2 GRID terminal in the wiring box 6 Ensure all connections are correctly wired and properly torqued according to values shown in Table 3-1 on page 3-5 Utility Grid L2 Neutral Utility Meter Xantrex GT Inverter Wiring'.Box : • ' 'SHE :®~ •©:";_- ;.'• i: ,-..: ' / jprri IS 'f © L1 L2 L1 [@1 fTPWTn ' " -" Neutral Mam Utility Service Panel AC/DC Disconnect Switch s E= E^; ms «m mx ^a J^D KS;S sr?" Primary Earth J. Ground •===• Figure 3-5 AC Connections from GT Inverter to Utility Service Panel 3-8 975-0245-01-01 05/2007 Rev 15 •PM353030 111 of 179 Connecting Multiple Inverters Connecting Multiple Inverters For installations with multiple GT Inverters, separate solar arrays are required for each unit The output of each GT Inverter feeds a separate dual-pole 20-Amp circuit breaker (LI and L2) in the mam utility service panel For such installations, complete the wiring and perform the commissioning procedure for each inverter one at a time For wiring instructions, see "Connecting the DC Wiring" on page 3^4 and "Connecting the AC Wiring" on page 3-7 For the commissioning procedure, see "Commissioning Multiple Inverters" on page 4-4 WARNING Shock hazard and equipment failure If inverters "share" more than one PV array, an input current difference of over 1 A between arrays can cause each inverter to fail—the ground fault protection fuse will blow, followed by short circuit failure This failure will also generate hazardous voltages at the DC/AC disconnect switch on each unit It is very important to ensure each inverter is correctly connected to its own PV array(s) and that no wires are crossed For example, connect PV1 positive (+) and PV1 negative (-) to inverter 1 and PV2 positive (+) and PV2 negative (-) to inverter 2 Do not connect PV1 positive (+) and PV2 negative (-) to inverter 1 and PV2 positive (+) and PV1 negative (-) to inverter 2 See Figure 3-6 Figure 3-6 Improper Multiple Inverter Connections 975-0245-01-01 3-9 05/2007 Rev 15 *PM353030 112 of 179 Wiring the Inverter DC and AC Wiring for Multiple Inverters The following procedures are illustrated in Figure 3-7 The illustration and instructions assume only two inverters, but in fact up to ten inverters can be installed and networked together If there will be more than one PV array, label the positive and negative wire pairs appropriately (for example PV1 POS, PV1 NEC, PV1 GND, PV2 POS, etc ) Connecting DC To wire the PV array to multiple GT Inverters wmn§ 1 Remove the wiring box cover from each unit (see page 3-2) 2 Install the DC conduit from the PV arrays to the GT Inverter wiring boxes, through appropriate knockout holes Metal conduit is highly recommended 3 Route the wires from each PV array through the conduit and into the wiring box of the unit intended for that PV array 4 Connect the DC Ground from each P V array to the GND bar in the wiring box of the unit intended for that PV array Do not combine array ground wires 5 Follow the instructions on page 3-4 for connecting POSITIVE (+) and NEGATIVE (-) wires from each PV array to each GT Inverter 6 If required by the AHJ, a DC grounding conductor may be connected to each inverter's ground bar One inverter will connect to a common grounding conductor The other inverters will use tap connectors Connection is then made to the DC or AC grounding electrode as per NEC 690 47 7 Ensure all connections are correctly wired and properly torqued according to values shown in Table 3-1 on page 3-5 To wire the main utility service panel with multiple GT Inverters.Connecting AC wmng 1 Run conduit from the mam utility service panel to the wiring boxes of the GT Inverters 2 Follow the instructions on page 3-7 for connecting LI and L2 HOT wires and ground wire from the mam utility service panel to each GT Inverter 3 Ensure all connections are correctly wired and properly torqued according to values shown m Table 3-1 on page 3—5 3-10 975-0245-01-01 05/2007 Rev 15 'PM353030 113 of 179 Connecting Multiple Inverters PV Array #2 (PV2) Utility Grid Neutral © "':.-.- •" ' ;,"' S ^ ' '©' Xantrex GTInverfer #1 '• Xantrex GT Inverter #2 Primary EarthX. 5Ground ~ :• BCT2 SE-r K™; K"1- (M™ CT™ " ' ' n K t - !G J5|r 7 W&"'*'"'" ™" li f DC/AC Disconnect Switch Listed tap connector or exothermic welding * K!EZ ffis-'' (i S^ Sas^ E^ KSK aex'JS ^^s fl»^ @i!» GTC3 K:T Figure 3-7 DC and AC Wiring With Multiple GT Inverters 975-0245-01-01 3-11 05/2007 Rev 15 *PM353030 114 of 179 •PM353030 ReV MULTI-PURPOSE MODULE rRAME Ti HIGH POWER. HIGH EFFICIENCY. MONO-CRYSTALLINE SILICON PHOTOVOLTAIC MODULE WITH 175W MAXIMUM POWER This mono-crystalline 175 watt module features 13.45% module efficiency for an outstanding balance of size and weight to power and performance. Reengineered frame includes a contoured edge to improve water management, reducing surface moisture and debris. The new back support bar allows better performance under mechanical load. Using breakthrough technology perfected by Sharp's nearly 50 years of research and development, these modules use a textured cell surface to increase light absorption and improve efficiency. Common applications include office buildings, cabins and solar power stations. Ideal for both residential and commercial grid-connected systems and designed to withstand rigorous operating conditions, Sharp's NT-175U1 modules offer the maximum usable power per square foot of solar array. MULTI-PURPOSE MODULE Cell No. of Cells and Connections Open Circuit Voltage (Voc) Mono-crystalline silicon 72 In series 44.4V 35.4V 5.4A 4.95A Maximum Power Voltage (Vpm) Short Circuit Current (Isc) Maximum Power Current (Ipm) Maximum Power (Pmax)* 175W (+10% /-5%) Module Efficiency Maximum Power (nm) 13.45% Maximum System Voltage &OOVDC Series Fuse Rating IOA Type Of Output Terminal Lead Wire with MC Connector * (STC) Standard Test Conditions: 25'C, 1 kW/m', AM 1.5 Dimensions (A x B x C below) Weight Size of Carton Packing Configuration Pallet Quantity 32.5'x 62.0" x 1.8' (826mm X 1575mm X 46mm) 35.3lbs/16kg 62.60" x 33.27" x 4.251 (1590mm X 845mm X 108mm) 2 PCS per carton 30 DCS per pallet Operating Temperature (mln to max/F/'C) -40 to +194'F / -40 to +90'C Storage Temperature (mln to max/F/Tj) -40 to +194T / -40 to +90'C Cell Temperature: 25'C Voltage [W Current vs. Voltage — Power vs. Voltage Current, Power vs. Voltage Characteristics 1 D J_ JL E T r G \ \ I T T 1 H ABC 32.5'/S26mm 62.0'A575mm 1.8V46mm E F G 3.9"AOOmm 3UV790nim 43.3'/1100mm D 13.4'/340mm Design and specifications are subject to change without notice. Sharp Is a registered trademark of Sharp Corporation. All other trademarks are property of their respective owners. Sharp takes no responsibility for any defects that may occur In equipment using any Sharp devices. Contact Sharp to obtain the latest product manuals before using any Sharp device. /US SHARP ELECTRONICS CORPORATION • 5901 Bolsa Avenue, Huntington Beach, CA 92647 Tel: 1-800-SOLAR-06 • E-mail: sharpsolar@sharpusa.com • www.sharpusa.com/solar Cover photo: Solar Installation by Pacific Power Management, Auburn CA ©2008 Sharp Electronics Corporation. All rights reserved.SESG-175U1 Printed In the USA APPj >0VED *_[ -t- 1 -^ + -4-_c 4 / : D P ] ] 1 ] . uffeiL ^(Louut/ x-1-' W .-QU.62. (E PTC Check A License Contractor's License Detail Page 1 of 2 Skip to CSLB Home | Content | Footer | Accessibility I Search Department of Consumer Affairs ~! iGOV Contractors State Liqeir§e Board 01 CONSUMERS 02 03 CONTRACTORS APPLICANTS 04 JOURNEYMEN 05 PUBLIC WORKS 06 BUILDING OFFICIALS 07 GENERAL INFO AboutCSLB CSLB Newsroom Board and Committee Meetings Disaster information Center CSLB Library Frequently Asked Questions Online Services o Check A License o-' HIS Regi^ranon a I- iicg a Construction C'.';ir.f)i,5ini o Pnxessinq 7iir;es •» Check Application » -it'ijich tor a Workers •-.''.'••"^.'jOMsa'ion Company How to Participate £li DISCLAIMER A license status check provides information taken from the CSLB license database Before relying on this information, you should be awai the following limitations • CSLB complaint disclosure is restricted by law (8&P_7124 6) If this entity is subject to pu complaint disclosure, a link for complaint disclosure will appear below Click on the link 01 obtain complaint and/or legal action information • Per B&.PJ7Q71.1.7, only construction related civil judgments reported to the CSLB are disc • Arbitrations are not listed unless the contractor fails to comply with the terms of the arbitn • Due to workload, there may be relevant information that has not yet been entered onto th license database License Number Business Information Entity Issue Date Reissue Date Expire Date License Status Classifications Bonding Workers- Compensation 346161 Extract Date 08/04/21 SEARS CONSTRUCTION CO 1387 CYNTHIA LANE CARLSBAD, CA 92008 Business Phone Number (760) 720-9548 Sole Ownership 10/26/1977 05/27/1988 03/31/2009 This license is current and active All information below should b> reviewed CLASS I DESCRIPTION GENERAL BUILDING CONTRACTOR CONTRACTOR'S BOND This license filed Contractor's Bond number 6307950 in the amoui $12,500 with the bonding company SURETY COMPANY OF THE PACIFIC Effective Date 01/01/2007 Contractor's Bonding History This license is exempt from having workers compensation msurano they certified that they have no employees at this time Effective Date 03/19/1997 Expire Date None Wo rke.rs.' 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