Loading...
HomeMy WebLinkAbout2510 N Hathaway St - PlanBldg #1011106232 Elect #20176232 Issued on 5/25/22 2510 N. Hathaway St 05/26/22 Expedited Permit Process for PV Systems1 Expedited Permit Process for PV Systems Standard String System The Solar America Board for Codes and Standards (Solar ABCs) Expedited Permit Pro- cess provides a means to differentiate systems that can be permitted quickly and easily due to their similarity with the majority of small-scale PV systems. Those systems with unique characteristics may be handled with small additions to this Expedited Permit Process or may require much more information, depending on the uniqueness of the installation. The following pages contain forms for the Standard String System to use with the Expe- dited Permit Process. The Micro-Inverter, AC Module, and Supply-Side Connection forms are also available as interactive PDF files at www.solarabcs.org/permitting. In jurisdic- tions that have adopted the Expedited Permit Process for PV Systems, these forms can be filled out electronically and submitted in either printed form and via email. An elec- tronic format is used so that the supplied information is standardized and legible for the local jurisdiction. 2510 N. Hathaway St05/26/22 Expedited Permit Process for PV Systems2 Expedited Permit Process for Small-Scale PV Systems Standard String System The information in this guideline is intended to help local jurisdictions and contractors identify when PV system installations are simple, needing only a basic review, and when an installation is more complex. It is likely that 50%-75% of all residential systems will comply with these simple criteria. For projects that fail to meet the simple criteria, resolution steps have been suggested to provide as a path to permit approval. Required Information for Permit: 1. Site plan showing location of major components on the property. This drawing need not be exactly to scale, but it should represent relative location of components at site (see supplied example site plan). PV arrays on dwellings with a 3’ perimeter space at ridge and sides may not need separate fire service review. 2. Electrical diagram showing PV array configuration, wiring system, overcurrent protection, inverter, disconnects, required signs, and ac connection to building (see supplied standard electrical diagram). 3. Specification sheets and installation manuals (if available) for all manufactured components including, but not limited to, PV modules, inverter(s), combiner box, disconnects, and mounting system. Step 1: Structural Review of PV Array Mounting System Is the array to be mounted on a defined, permitted roof structure? l Yes l No If No due to non-compliant roof or a ground mount, submit completed worksheet for the structure WKS1. Roof Information: 1. Is the roofing type lightweight (Yes = composition, lightweight masonry, metal, etc…)__________________________ ____________________________________________________________________________________________________ If No, submit completed worksheet for roof structure WKS1 (No = heavy masonry, slate, etc…). 2. Does the roof have a single roof covering? l Yes l No If No, submit completed worksheet for roof structure WKS1. 3. Provide method and type of weatherproofing roof penetrations (e.g. flashing, caulk).____________________________ Mounting System Information: 1. Is the mounting structure an engineered product designed to mount PV modules with no more than an 18” gap beneath the module frames? l Yes l No If No, provide details of structural attachment certified by a design professional. 2. For manufactured mounting systems, fill out information on the mounting system below: a. Mounting System Manufacturer ___________Product Name and Model#________________________________ b. Total Weight of PV Modules and Rails ___________lbs c. Total Number of Attachment Points____________ d. Weight per Attachment Point (b÷c)_________________lbs (if greater than 45 lbs, see WKS1) e. Maximum Spacing Between Attachment Points on a Rail ______________inches (see product manual for maximum spacing allowed based on maximum design wind speed) f. Total Surface Area of PV Modules (square feet)_________________ ft 2 g. Distributed Weight of PV Module on Roof (b÷f)_______________ lbs/ft2 If distributed weight of the PV system is greater than 5 lbs/ft2, see WKS1. Step 2: Electrical Review of PV System (Calculations for Electrical Diagram) In order for a PV system to be considered for an expedited permit process, the following must apply: 1. PV modules, utility-interactive inverters, and combiner boxes are identified for use in PV systems. 2. The PV array is composed of 4 series strings or less per inverter. 3. The total inverter capacity has a continuous ac power output 13,440 Watts or less 4. The ac interconnection point is on the load side of service disconnecting means (690.64(B)). 5. One of the standard electrical diagrams (E1.1, E1.1a, E1.1b, or E1.1c) can be used to accurately represent the PV system. Interactive PDF diagrams are available at www.solarabcs.org/permitting. Fill out the standard electrical diagram completely. A guide to the electrical diagram is provided to help the applicant understand each blank to fill in. If the electrical system is more complex than the standard electrical diagram can effectively communicate, provide an alternative diagram with appropriate detail. 2510 N. Hathaway St05/26/22 Ex p e d i t e d P e r m i t P r o c e s s f o r P V S y s t e m s 3 Standard String System Site Plan                                                          Revco Solar Engineering 26631 CABOT RD Ste. B KEVIN&JOAN McCARTHY LAGUNA HILLS, CA 92653 2510 N HATHAWAY ST. PH. (949) 367-0740 DC:10.0kW AC: 9.011kW 2510 N. Hathaway St05/26/22 Ex p e d i t e d P e r m i t P r o c e s s f o r P V S y s t e m s 4 Standard String System Electrical Diagram                                                                                                                                                                                                                                                   Revco Solar Engineering 26631 CABOT RD Ste. B KEVIN&JOAN McCARTHY LAGUNA HILLS, CA 92653 2510 N HATHAWAY ST. PH. (949) 367-0740 DC:10.0kW AC: 9.011kW 2510 N. Hathaway St05/26/22 Ex p e d i t e d P e r m i t P r o c e s s f o r P V S y s t e m s 5 Notes for Standard String System Electrical Diagram Contractor Name, Address and Phone: _________________ _________________ _________________ _________________ Notes for One-Line Standard Electrical Diagram for Single-Phase PV Systems Site Name: __________________________ Site Address: ________________________ System AC Size: ______________________ SIZE FSCM NO DWG NO REV SCALE NTS Date: SHEET Drawn By: Checked By: MAX POWER-POINT CURRENT (IMP) MAX POWER-POINT VOLTAGE (VMP) OPEN-CIRCUIT VOLTAGE (VOC) SHORT-CIRCUIT CURRENT (ISC) MAX SERIES FUSE (OCPD) MAXIMUM POWER (PMAX) MAX VOLTAGE (TYP 600VDC) VOC TEMP COEFF (mV/oC or %/oC ) IF COEFF SUPPLIED, CIRCLE UNITS A V V A A W V MODULE MAKE MODULE MODEL PV MODULE RATINGS @ STC (Guide Section 5) MAX DC VOLT RATING MAX POWER @ 40oC NOMINAL AC VOLTAGE MAX AC CURRENT MAX OCPD RATING V W V A A INVERTER MAKE INVERTER MODEL INVERTER RATINGS (Guide Section 4) 1) IF UTILITY REQUIRES A VISIBLE-BREAK SWITCH, DOES THIS SWITCH MEET THE REQUIREMENT? YES NO N/A 2) IF GENERATION METER REQUIRED, DOES THIS METER SOCKET MEET THE REQUIREMENT? YES NO N/A 3) SIZE PHOTOVOLTAIC POWER SOURCE (DC) CONDUCTORS BASED ON MAX CURRENT ON NEC 690.53 SIGN OR OCPD RATING AT DISCONNECT 4) SIZE INVERTER OUTPUT CIRCUIT (AC) CONDUCTORS ACCORDING TO INVERTER OCPD AMPERE RATING. (See Guide Section 9) 5) TOTAL OF ______ INVERTER OCPD(s), ONE FOR EACH INVERTER. DOES TOTAL SUPPLY BREAKERS COMPLY WITH 120% BUSBAR EXCEPTION IN 690.64(B)(2)(a)? YES NO NOTES FOR INVERTER CIRCUITS (Guide Section 8 and 9): 1.) LOWEST EXPECT AMBIENT TEMPERATURE BASED ON ASHRAE MINIMUM MEAN EXTREME DRY BULB TEMPERATURE FOR ASHRAE LOCATION MOST SIMILAR TO INSTALLATION LOCATION. LOWEST EXPECTED AMBIENT TEMP ______oC 2.) HIGHEST CONTINUOUS AMBIENT TEMPERATURE BASED ON ASHRAE HIGHEST MONTH 2% DRY BULB TEMPERATURE FOR ASHRAE LOCATION MOST SIMILAR TO INSTALLATION LOCATION. HIGHEST CONTINUOUS TEMPERATURE _____oC 2.) 2005 ASHRAE FUNDEMENTALS 2% DESIGN TEMPERATURES DO NOT EXCEED 47oC IN THE UNITED STATES (PALM SPRINGS, CA IS 44.1 oC). FOR LESS THAN 9 CURRENT-CARRYING CONDUCTORS IN ROOF-MOUNTED SUNLIT CONDUIT AT LEAST 0.5" ABOVE ROOF AND USING THE OUTDOOR DESIGN TEMPERATURE OF 47oC OR LESS (ALL OF UNITED STATES), a) 12 AWG, 90oC CONDUCTORS ARE GENERALLY ACCEPTABLE FOR MODULES WITH Isc OF 7.68 AMPS OR LESS WHEN PROTECTED BY A 12-AMP OR SMALLER FUSE. b) 10 AWG, 90oC CONDUCTORS ARE GENERALLY ACCEPTABLE FOR MODULES WITH Isc OF 9.6 AMPS OR LESS WHEN PROTECTED BY A 15-AMP OR SMALLER FUSE. NOTES FOR ARRAY CIRCUIT WIRING (Guide Section 6 and 8 and Appendix D): OCPD = OVERCURRENT PROTECTION DEVICE NATIONAL ELECTRICAL CODE ® REFERENCES SHOWN AS (NEC XXX.XX) NOTES FOR ALL DRAWINGS: SIGNS–SEE GUIDE SECTION 7 SIGN FOR DC DISCONNECT SIGN FOR INVERTER OCPD AND AC DISCONNECT (IF USED) RATED MPP CURRENT RATED MPP VOLTAGE MAX SYSTEM VOLTAGE MAX CIRCUIT CURRENT A V V A PHOTOVOLTAIC POWER SOURCE WARNING: ELECTRICAL SHOCK HAZARD–LINE AND LOAD MAY BE ENERGIZED IN OPEN POSITION AC OUTPUT CURRENT NOMINAL AC VOLTAGE A V SOLAR PV SYSTEM AC POINT OF CONNECTION THIS PANEL FED BY MULTIPLE SOURCES (UTILITY AND SOLAR) Revco Solar Engineering 26631 CABOT RD Ste. B KEVIN&JOAN McCARTHY LAGUNA HILLS, CA 92653 2510 N HATHAWAY ST. PH. (949) 367-0740 DC:10.0kW AC: 9.011kW 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 Rev: 7/15/2021 RESIDENTIAL PHOTOVOLTAIC CHECKLIST SOL-01 CBC 2019 Solar Photovoltaic (PV) Checklist for Detached SINGLE FAMILY RESIDENCES Only Instructions: The licensed contractor of record shall complete all sections, answer the ten questions and sign the certification section below. A copy of this form shall be attached to each of TWO sets of plans, of minimum 11” x 17” size. If answering NO to any of the questions, plan check shall be required. Project Address: Contractor Company Name: Contractor License Number: YES NO Are the following applicable to the proposed project? 1.   Will the PV system layout provide the required three-foot wide clear access pathways per Section 605.11 of the California Fire Code, and is this shown on the roof plan? 2.   Will the PV system be installed on a roof having only one roofing layer with no overlays? 3.   Will the PV array be flush mounted to the existing roof so that the plane of the modules (panels) are parallel to the plane of the roof? 4.   Will the PV system weigh maximum 4 pounds per square feet or less? 5.   Will the PV system be installed where the modules do not overhang any roof edges (such as eaves, gabled ends, ridges and hips)? 6.   Will the PV system be installed with a space of 2” minimum to 10” maximum between the underside of modules and the surface of the roof? 7.   Will the PV system be installed without using any ballast system or counter-weight system? 8.   Will the anchors be installed with a maximum horizontal anchor spacing of 6 feet and is this maximum horizontal spacing shown on the plans? 9.   Will the minimum 5/16” lag screws be installed with a minimum of 2-1/2 inch embedment into roof rafters (with pre-drilled holes) and is this minimum embedment shown on the plans? 10.   Are ALL the structural pages of the plans stamped and signed by a California licensed professional engineer? (including project specific site plan, PV layout, anchorage spacing, anchorage details and manufacturer’s PV support information.) I certify under penalty of perjury under the laws of the State of California that the above is true: Print Name: Signature: Phone Number: Date: Email Address: Planning & Building Agency Building Safety Division 20 Civic Center Plaza P.O. Box 1988 (M-19) Santa Ana, CA 92702 (714) 647-5800 www.santa-ana.org 2510 N. Hathaway St05/26/22 About Solaria Established in 2000, The Solaria Corporation has created one of the industry’s most respected IP portfolios, with over 100 patents encompassing materials, processes, applications, products, manufacturing automation and equipment. Headquartered in Fremont, California, Solaria has developed a technology platform that unlocks the potential of solar energy allowing it to be ubiquitous and universally accessed. Achieving over 20% effi ciency, Solaria PowerXT solar panels are one of the highest power panels in the residential and commercial solar market. Compared to conventional panels, Solaria PowerXT panels have fewer gaps between the solar cells; this leads to higher power and superior aesthetics. Solaria PowerXT Pure BlackTM panels are manufactured with black backsheet and frames, enhancing a home or building’s architectural beauty. Higher Effi ciency, Higher Power Solaria PowerXT panels achieve over 20% effi ciency; conventional panels achieve 15% – 17% effi ciency. Solaria PowerXT panels are one of the highest power panels available. Lower System Costs Solaria PowerXT panels produce more power per square meter area. This reduces installation costs due to fewer balance of system components. Improved Shading Tolerance Sub-strings are interconnected in parallel, within each of the four panel quadrants, which dramatically lowers the shading losses and boosts energy yield. Improved Aesthetics Compared to conventional panels, Solaria PowerXT panels have a more uniform appearance and superior aesthetics. Durability and Reliability Solder-less cell interconnections are highly reliable and designed to far exceed the industry leading 25 year warranty. Solaria PowerXT ®-400R-PM Solaria PowerXT ® | DC Panel About Solaria Established in 2000, The Solaria Corporation has created one of the industry’s most respected IP portfolios, with over 250 issued and pending patents in PV solar cell and module technology. Headquartered in Oakland, California, Solaria has developed a technology platform that unlocks the potential of solar energy. The Solaria Corporation 1700 Broadway, Oakland, CA 94612 P: (510) 270-2507 www.solaria.com Copyright © 2020 The Solaria Corporation Product specifi cations are subject to change without notice.SOL-DAT-0005 Rev 01 4-2020 2510 N. Hathaway St05/26/22 1.0in 25mm 5.8in 148mm 64.7in 1644mm 5.8in 148mm 1.0in 25mm 47.4in 1204mm 14.4in 367mm 35.9in 911mm POSITIVE (+) 1000mm[39.4in] NEGATIVE (-) 1000mm[39.4in] 7mm[0.276in] X 10mm[0.394in] 4X MOUNTING SLOTS 'B' 4.5mm[0.18in] 4X GROUNDING HOLES 'A' 1.7mm A BB B B A A A The Solaria Corporation 1700 Broadway, Oakland, CA 94612 P: (510) 270-2507 www.solaria.com Copyright © 2020 The Solaria Corporation Product specifi cations are subject to change without notice.SOL-DAT-0005 Rev 01 4-2020 Solaria PowerXT®-400R-PM Performance at STC (1000W/m2, 25° C, AM 1.5) Solaria PowerXT-400R-PM Max Power (Pmax) [W]400 Effi ciency [%]20.2 Open Circuit Voltage (Voc) [V]51.1 Short Circuit Current (Isc) [A]9.82 Max Power Voltage (Vmp) [V]42.4 Max Power Current (Imp) [A]9.41 Power Tolerance [%]-0/+3 Performance at NOCT (800W/m2, 20°C Amb, Wind 1 m/s, AM 1.5) Max Power (Pmax) [W] 295 Open Circuit Voltage (Voc) [V] 48.1 Short Circuit Current (Isc) [A] 7.92 Max Power Voltage (Vmp) [V] 40.0 Max Power Current (Imp) [A] 7.59 Temperature Characteristics NOCT [ºC]45 +/-2 Temp. Coeff. of Pmax [% / ºC]-0.39 Temp. Coeff. of Voc [% / ºC]-0.29 Temp. Coeff. of Isc [% / ºC]0.04 Design Parameters Operating temperature [ºC]-40 to +85 Max System Voltage [V]1000 Max Fuse Rating [A]20 Bypass Diodes [#]4 Mechanical Characteristics Cell Type Monocrystalline Silicon Dimensions (L x W x H) 64.72" x 47.4" x 1.57" 1644mm x 1204mm x 40mm Weight 21 kg / 46 lbs Glass Type / Thickness AR Coated, Tempered / 2.84mm Frame Type Black Anodized Aluminum Cable Type / Length 12 AWG PV Wire (UL) / 1000mm Connector Type MC4 Junction Box IP67 / 4 diodes Front Load 5400 Pa / 113 psf* Rear Load 2400 Pa / 50 psf* * Refer to Solaria Installation Manual for details Certifi cations / Warranty Certifi cations UL 61730/UL1741/CEC CAN/CSA-C22.2 Fire Type (UL 1703)1 Warranty 25 years* * Warranty details at www.solaria.com Packaging Stacking Method Horizontal / Palletized Panels/ Pallet 25 Pallet Dims (L x W x H)66.57" x 48.7" x 48.4" 1691mm x 1238mm x 1230 mm Pallet Weight 590 kg / 1300 lbs Pallets / 40-ft Container 18 Panels / 40-ft Container 450 IV Curves vs. Irradiance (400W Panel) 1.57in 40mm 1.38in 35mm .07in 1.70mm .43in 11mm Comprehensive 25-Year Warranty 0 1 2 3 4 5 6 7 8 9 10 0 5 10 15 20 25 30 35 40 45 50 55 CU R R E N T ( A ) VOLTAGE (V) Years 25-year Power, Parts and Labor from Solaria Typical Tier 1 industry warranty 100% 90% 80% 98% 5 10 2515 20 86% 81% Wo r k m a n s h i p L i m i t FRAME PROFILE 2510 N. Hathaway St05/26/22 PO W E R O P T I M I Z E R solaredge.com PV power optimization at the module-level Specifically designed to work with SolarEdge inverters Up to 25% more energy Flexible system design for maximum space utilization Fast installation with a single bolt Next generation maintenance with module- level monitoring Meets NEC requirements for arc fault protection (AFCI) and Photovoltaic Rapid Shutdown System (PVRSS) Module-level voltage shutdown for installer and firefighter safety Superior efficiency (99.5%) Mitigates all types of module mismatch losses, from manufacturing tolerance to partial shading Power Optimizer For North America P320 / P340 / P370 / P400 / P401 / P405 / P485 / P505 25 YEAR WARRANTY 2510 N. Hathaway St05/26/22 © SolarEdge Technologies Ltd. All rights reserved. SOLAREDGE, the SolarEdge logo, OPTIMIZED BY SOLAREDGE are trademarks or registered trademarks of SolarEdge Technologies, Inc. All other trademarks mentioned herein are trademarks of their respective owners. Date: 07/2020/V02/ENG NAM. Subject to change without notice. (6) For detailed string sizing information refer to: http://www.solaredge.com/sites/default/files/string_sizing_na.pdf (7) It is not allowed to mix P405/P485/P505 with P320/P340/P370/P400/P401 in one string (8) A string with more than 30 optimizers does not meet NEC rapid shutdown requirements; safety voltage will be above the 30V requirement (9) For 208V grid: it is allowed to install up to 7,200W per string when the maximum power difference between each string is 1,000W (10) For 277/480V grid: it is allowed to install up to 15,000W per string when the maximum power difference between each string is 2,000W Power Optimizer For North America P320 / P340 / P370 / P400 / P401 / P405 / P485 / P505 Optimizer model (typical module compatibility) P320 (for 60-cell modules) P340 (for high- power 60-cell modules) P370 (for higher- power 60 and 72- cell modules) P400 (for 72 & 96-cell modules) P401 (for high power 60 and 72 cell modules) P405 (for high- voltage modules) P485 (for high- voltage modules) P505 (for higher current modules) INPUT Rated Input DC Power(1)320 340 370 400 405 485 505 W Absolute Maximum Input Voltage (Voc at lowest temperature)48 60 80 60 125(2)83(2)Vdc MPPT Operating Range 8 - 48 8 - 60 8 - 80 8-60 12.5 - 105 12.5 - 83 Vdc Maximum Short Circuit Current (Isc)11 10.1 11.75 11 14 Adc Maximum Efficiency 99.5 % Weighted Efficiency 98.8 98.6 % Overvoltage Category II OUTPUT DURING OPERATION (POWER OPTIMIZER CONNECTED TO OPERATING SOLAREDGE INVERTER) Maximum Output Current 15 Adc Maximum Output Voltage 60 85 Vdc OUTPUT DURING STANDBY (POWER OPTIMIZER DISCONNECTED FROM SOLAREDGE INVERTER OR SOLAREDGE INVERTER OFF) Safety Output Voltage per Power Optimizer 1 ± 0.1 Vdc STANDARD COMPLIANCE EMC FCC Part15 Class B, IEC61000-6-2, IEC61000-6-3 Safety IEC62109-1 (class II safety), UL1741 Material UL94 V-0 , UV Resistant RoHS Yes INSTALLATION SPECIFICATIONS Maximum Allowed System Voltage 1000 Vdc Compatible inverters All SolarEdge Single Phase and Three Phase inverters Dimensions (W x L x H)129 x 153 x 27.5 / 5.1 x 6 x 1.1 129 x 153 x 33.5 / 5.1 x 6 x 1.3 129 x 153 x 29.5 /5.1 x 6 x 1.16 129 x 159 x 49.5 / 5.1 x 6.3 x 1.9 129 x 162 x 59 / 5.1 x 6.4 x 2.3 mm / in Weight (including cables)630 / 1.4 750 / 1.7 655 / 1.5 845 / 1.9 1064 / 2.3 gr / lb Input Connector MC4(3)Single or dual MC4(3)(4)MC4(3) Input Wire Length 0.16 / 0.52 m / ft Output Wire Type / Connector Double Insulated / MC4 Output Wire Length 0.9 / 2.95 1.2 / 3.9 m / ft Operating Temperature Range(5)-40 - +85 / -40 - +185 ˚C / ˚F Protection Rating IP68 / NEMA6P Relative Humidity 0 - 100 % (1) Rated power of the module at STC will not exceed the optimizer “Rated Input DC Power”. Modules with up to +5% power tolerance are allowed (2) NEC 2017 requires max input voltage be not more than 80V (3) For other connector types please contact SolarEdge (4) For dual version for parallel connection of two modules use P485-4NMDMRM. In the case of an odd number of PV modules in one string, installing one P485 dual version power optimizer connected to one PV module. When connecting a single module seal the unused input connectors with the supplied pair of seals. (5) For ambient temperature above +85°C / +185°F power de-rating is applied. Refer to Power Optimizers Temperature De-Rating Technical Note for more details. PV System Design Using a SolarEdge Inverter(6)(7) Single Phase HD-Wave Single phase Three Phase for 208V grid Three Phase for 277/480V grid Minimum String Length (Power Optimizers) P320, P340, P370, P400, P401 8 10 18 P405, P485, P505 6 8 14 Maximum String Length (Power Optimizers)25 25 50(8) Maximum Power per String 5700 (6000 with SE7600-US - SE11400- US) 5250 6000(9)12750(10) W Parallel Strings of Different Lengths or Orientations Yes 2510 N. Hathaway St05/26/22 IN V E R T E R S solaredge.com Optimized installation with HD-Wave technology Specifically designed to work with power optimizers Built-in module-level monitoring Outdoor and indoor installation Optional: Revenue grade data, ANSI C12.20 Class 0.5 (0.5% accuracy) Record-breaking efficiency Quick and easy inverter commissioning directly from a smartphone using the SolarEdge SetApp Fixed voltage inverter for longer strings UL1741 SA certified, for CPUC Rule 21 grid compliance Integrated arc fault protection and rapid shutdown for NEC 2014 and 2017, per article 690.11 and 690.12 Extremely small Single Phase Inverter with HD-Wave Technology for North America SE3000H-US / SE3800H-US / SE5000H-US / SE6000H-US / SE7600H-US / SE10000H-US / SE11400H-US 12-25 YEAR WARRANTY 2510 N. Hathaway St05/26/22 Model Number SE3000H-US SE3800H-US SE5000H-US SE6000H-US SE7600H-US SE10000H-US SE11400H-US APPLICABLE TO INVERTERS WITH PART NUMBER SEXXXXH-XXXXXBXX4 OUTPUT Rated AC Power Output 3000 3800 @ 240V 3300 @ 208V 5000 6000 @ 240V 5000 @ 208V 7600 10000 11400 @ 240V 10000 @ 208V VA Maximum AC Power Output 3000 3800 @ 240V 3300 @ 208V 5000 6000 @ 240V 5000 @ 208V 7600 10000 11400 @ 240V 10000 @ 208V VA AC Output Voltage Min.-Nom.-Max. (211 - 240 - 264)Vac AC Output Voltage Min.-Nom.-Max. (183 - 208 - 229)----Vac AC Frequency (Nominal)59.3 - 60 - 60.5(1)Hz Maximum Continuous Output Current @240V 12.5 16 21 25 32 42 47.5 A Maximum Continuous Output Current @208V -16 -24 --48.5 A Power Factor 1, adjustable -0.85 to 0.85 GFDI Threshold 1 A Utility Monitoring, Islanding Protection, Country Configurable Thresholds Yes INPUT Maximum DC Power @240V 4650 5900 7750 9300 11800 15500 17650 W Maximum DC Power @208V -5100 -7750 --15500 W Transformer-less, Ungrounded Yes Maximum Input Voltage 480 Vdc Nominal DC Input Voltage 380 400 Vdc Maximum Input Current @240V(2)8.5 10.5 13.5 16.5 20 27 30.5 Adc Maximum Input Current @208V(2)-9 -13.5 --27 Adc Max. Input Short Circuit Current 45 Adc Reverse-Polarity Protection Yes Ground-Fault Isolation Detection 600k Sensitivity Maximum Inverter Efficiency 99 99.2 % CEC Weighted Efficiency 99 99 @ 240V 98.5 @ 208V % Nighttime Power Consumption < 2.5 W (1) For other regional settings please contact SolarEdge support (2) A higher current source may be used; the inverter will limit its input current to the values stated Single Phase Inverter with HD-Wave Technology for North America SE3000H-US / SE3800H-US / SE5000H-US / SE6000H-US/ SE7600H-US / SE10000H-US / SE11400H-US 2510 N. Hathaway St05/26/22 Model Number SE3000H-US SE3800H-US SE5000H-US SE6000H-US SE7600H-US SE10000H-US SE11400H-US ADDITIONAL FEATURES Supported Communication Interfaces RS485, Ethernet, ZigBee (optional), Cellular (optional) Revenue Grade Data, ANSI C12.20 Optional(3) Inverter Commissioning with the SetApp mobile application using built-in Wi-Fi Access Point for local connection Rapid Shutdown - NEC 2014 and 2017 690.12 Automatic Rapid Shutdown upon AC Grid Disconnect STANDARD COMPLIANCE Safety UL1741, UL1741 SA, UL1699B, CSA C22.2, Canadian AFCI according to T.I.L. M-07 Grid Connection Standards IEEE1547, Rule 21, Rule 14 (HI) Emissions FCC Part 15 Class B INSTALLATION SPECIFICATIONS AC Output Conduit Size / AWG Range 1'' Maximum / 14-6 AWG 1'' Maximum /14-4 AWG DC Input Conduit Size / # of Strings / AWG Range 1'' Maximum / 1-2 strings / 14-6 AWG 1'' Maximum / 1-3 strings / 14-6 AWG Dimensions with Safety Switch (HxWxD)17.7 x 14.6 x 6.8 / 450 x 370 x 174 21.3 x 14.6 x 7.3 / 540 x 370 x 185 in / mm Weight with Safety Switch 22 / 10 25.1 / 11.4 26.2 / 11.9 38.8 / 17.6 lb / kg Noise < 25 <50 dBA Cooling Natural Convection Operating Temperature Range -40 to +140 / -40 to +60(4)˚F / ˚C Protection Rating NEMA 4X (Inverter with Safety Switch) (3) Revenue grade inverter P/N: SExxxxH-US000BNC4 (4) Full power up to at least 50˚C / 122˚F; for power de-rating information refer to: https://www.solaredge.com/sites/default/files/se-temperature-derating-note-na.pdf Single Phase Inverter with HD-Wave Technology for North America SE3000H-US / SE3800H-US / SE5000H-US / SE6000H-US/ SE7600H-US / SE10000H-US / SE11400H-US © SolarEdge Technologies, Inc. All rights reserved. SOLAREDGE, the SolarEdge logo, OPTIMIZED BY SOLAREDGE are trademarks or registered trademarks of SolarEdge Technologies, Inc. All other trademarks mentioned herein are trademarks of their respective owners. Date: 5/2019/V01/ENG NAM. Subject to change without notice. 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 www.solaredge.comUSA  -   GermAny -   ItAly -   FrAnce -   JApAn -    chInA -    AUStrAlIA -    ISrAel SolarEdge Wireless Communication ZigBee Kit SE1000-ZBGW-K / SE1000-ZB03-SLV / SE1000-ZBRPT C o m m u n i C a T i o n Simple Wireless Connectivity Connects SolarEdge inverters wirelessly to an Internet router ZigBee unit installed within the inverter enclosure for outdoor resilience Antenna external to inverter for wider range Communication to Internet via Ethernet The home gateway supports up to 15 SolarEdge devices (e.g. inverters) on the wireless network Inverter Internet Router ETH www SolarEdge Portal Home Gateway 2510 N. Hathaway St05/26/22 © SolarEdge Technologies, Inc. All rights reserved. SOLAREDGE, the SolarEdge logo, OPTIMIZED BY SOLAREDGE are trademarks or registered trademarks of SolarEdge Technologies, Inc. All other trademarks mentioned herein are trademarks of their respective owners. Date: 10/2013. V.01. Subject to change without notice. SolarEdge Wireless Communication ZigBee Kit SE1000-ZBGW-K / SE1000-ZB03-SLV / SE1000-ZBRPT FUNCTIONAL UNIT Number of devices that can be monitored 1-15 RF pERFORMANCE Transmit power 10 dBm Receiver Sensitivity -102 dBm Antenna gain 2.1 dBi Outdoor (LOS) range 400 / 1300 m / ſt Indoor range1 50 / 160 m / ſt HOME GATEWAY / RE pEATER Antenna Included Power supply Included, 100-240VAC Operating temperature -20 to +60 / -4 to +140 ˚C / ˚F Dimensions (H x W x D)115 x 70 x 50 / 4.5 x 2.8 x 2.0 mm / in Relative humidity (non condensing)0 - 80 % Ingress protection IP20 (Indoor) ZIGBEE SLAvE kIT Antenna, mounting bracket and RF cable Included Dimensions (H x W x D)22.0 x 32.9 x 4.1 / 0.9 x 1.3 x 0.2 mm / in Ingress protection IP65 (IP20 / indoor rated when installed inside Control and Communication Gateway or Firefighter Gateway) CERTIFICATION Safety IEC60950, UL60950 EMC Approvals ETSI(Europe), C-Tick(Australia), Telec(Japan) Scenario A: Basic Kit Part Number: SE1000-ZBGW-K - 1 x SolarEdge home gateway - 1 x ZigBee slave kit for single SolarEdge device Scenario C: Extending range using a repeater Part Number: SE1000-ZBRPT - 1 x SolarEdge ZigBee Repeater for extending the ZigBee range Scenario B: Adding additional slave units Part Number: SE1000-ZB03-SLV - 1x ZigBee slave kit for connecting multiple devices to the same home gateway 1 Approximate values, may differ depending on specific installation conditions Home Gateway Internet Router Master Ethernet ETH www SolarEdge Portal Slave Slave Slave Home Gateway (Master) www SolarEdge Portal ZigBee Repeater (Slave) Inverter Internet Router Ethernet ETH Slave Inverters Inverter Home Gateway Internet Router Master Ethernet ETH www SolarEdge Portal 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 SOLARMOUNT defined the standard in solar racking. New enhancements are designed to get installers off the roof faster than ever before. Components are pre-assembled and optimized to reduce installation steps and save labor time. Our new grounding & bonding process eliminates copper wire and grounding straps to reduce costs. Utilize the microinverter mount with a wire management clip for an easier installation. SM SOLARMOUNT GET OFF THE ROOF FASTER THAN EVER BEFORE OPTIMIZED COMPONENTS • VERSATILITY • DESIGN TOOLS • QUALITY PROVIDER LOSE ALL OF THE COPPER & LUGS System grounding through Enphase microinverters and trunk cables SMALL IS THE NEXT NEW BIG THING Light Rail is Fully Compatibility with all SM Components ENHANCED DESIGN & LAYOUT TOOLS Now Featuring Google Map Capabilities within U-Builder 2510 N. Hathaway St05/26/22 UNIRAC CUSTOMER SERVICE MEANS THE HIGHEST LEVEL OF PRODUCT SUPPORT ENGINEERING EXCELLENCE UNMATCHED EXPERIENCE PERMIT DOCUMENTATION DESIGN TOOLS CERTIFIED QUALITY BANKABLE WARRANTY PROTECT YOUR REPUTATION WITH QUALITY RACKING SOLUTIONS BACKED BY ENGINEERING EXCELLENCE AND A SUPERIOR SUPPLY CHAIN OPTIMIZED COMPONENTS INTEGRATED BONDING & PRE-ASSEMBLED PARTS Components are pre-assembled and optimized to reduce installation steps and save labor time. Our new grounding & bonding process eliminates copper wire and grounding straps or bonding jumpers to reduce costs. Utilize the microinverter mount with a wire management clip for an easier installation. VERSATILITY ONE PRODUCT - MANY APPLICATIONS Quickly set modules flush to the roof or at a desired tilt angle. Change module orientation to portrait or landscape while securing a large variety of framed modules on flat, low sloped or steep pitched roofs. Available in mill, clear and dark anodized finishes to outperform your projects financial and aesthetic aspirations. AUTOMATED DESIGN TOOL DESIGN PLATFORM AT YOUR SERVICE Creating a bill of materials is just a few clicks away with U-Builder, a powerful online tool that streamlines the process of designing a code compliant solar mounting system. Save time by creating a user profile, and recall preferences and projects automatically when you log in. You will enjoy the ability to share projects with customers; there’s no need to print results and send to a distributor, just click and share. INTEGRATED BONDING MIDCLAMP INTEGRATED BONDING SPLICE BAR INTEGRATED BONDING MICROINVERTER MOUNT w/ WIRE MANAGEMENT INTEGRATED BONDING L-FOOT w/ T-BOLT SM SOLARMOUNT BANKABLE WARRANTY As a Hilti Group Company, Unirac has the financial strength to back our products and reduce your risk. Have peace of mind knowing you are receiving products of exceptional quality. SOLARMOUNT is covered by a 10 year limited product warranty and a 5 year limited finish warranty. TECHNICAL SUPPORT Unirac’s technical support team is dedicated to answering questions & addressing issues in real time. An online library of documents including engineering reports, stamped letters and technical data sheets greatly simplifies your permitting and project planning process. CERTIFIED QUALITY PROVIDER Unirac is the only PV mounting vendor with ISO certifications for 9001:2008, 14001:2004 and OHSAS 18001:2007, which means we deliver the highest standards for fit, form, and function. These certifications demonstrate our excellence and commitment to first class business practices. UL2703BONDING & GROUNDING MECHANICAL LOADING SYSTEM FIRE CLASSIFICATIONLI S T E D PUB 16JAN04 - DIGITAL UPDATES 2510 N. Hathaway St05/26/22 • Made of corrosion-resistant, tin-plate copper • No surface preperation on rail or module required • Reliability throughout the lifetime of the PV system • Multiple equipment ground conductor allowance: One 14 AWG to 6 AWG or two 10 AWG, two 12 AWG • UL2703 Listed • Listed to ANSI/UL 467 by Intertek ETL • CSA Certified to C22.2 No. 41 Grounding Lugs Constructed of corrosion resistant, tin-plated copper, the Wiley line of grounding lugs are high quality solutions for your solar PV system. The tin-plated lug assures minimum contact resistance and protection against corrosion. The low profile of the grounding lug allows it to be installed in a variety of positions with one solid or stranded copper wire (14 AWG to 6 AWG), or two copper wires (12 AWG to 10 AWG). Copper wire is secured by a 1/4-28 stainless steel screw, which is horizontal to the tang. This allows for easy access when mounted under a PV module. The result is a continuous ground on all solar applications. WEEB ® Grounding Lug The WEEB ® Grounding Lug is installed using stainless steel mounting hardware. When the hardware is tightened, the WEEB® washer’s specialized teeth embed into anodized aluminum or any electrically conductive metal to establish a gas tight electrical connection. 4004188 © 2014 BURNDY LLC Customer Service 1-800-346-4175 | International 603-647-5299 | Canada 1-800-387-6487 | www.burndy.com © 2014 BURNDY LLC Connecting Power to Your World® ITEM # CATALOG # LENGTH In. [mm] WIDTH In. [mm] HEIGHT In. [mm] HOLE SIZE In. [mm] MOUNTING HARDWARE ASSEMBLED TORQUE 30020109 WEEB-LUG-6.7 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.266 [6.76] 1/4 inch hardware included N 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50045236 WEEB-LUG-6.7HS 30020110 WEEB-LUG-6.7AS 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.266 [6.76] 1/4 inch hardware included Y 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046747 WEEB-LUG-6.7ASHS 30020111 WEEB-LUG-8.0 1.575 [40.00] 0.866 [22.00] 0.472 [12.00] 0.323 [8.20] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046750 WEEB-LUG-8.0HS 50010335 WEEB-LUG-8.0AS 1.575 [40.00] 0.866 [22.00] 0.472 [12.00] 0.323 [8.20] 5/16 inch hardware included Y 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046753 WEEB-LUG-8.0UNHS 50023920 WEEB-LUG-8.0UN 1.575 [40.00] 0.866 [22.00] 0.472 [12.00] 0.323 [8.20] 5/16 inch hardware included N 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046756 WEEB-LUG-8.0ASHS 30020112 WEEB-LUG-15.8 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.323 [8.20] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046759 WEEB-LUG-15.8HS 50021995 WEEB-LUG-8.2 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.323 [8.20] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw, 10ft lbs for mounting hardware w/ Penetrox-A on threads50046762 WEEB-LUG-8.2HS *HS = HEX SOCKET CAP TERMINAL SCREW LUG HS 2510 N. Hathaway St05/26/22 • Material: tin-plated copper • Outdoor rated • Low profile design • Perfect for galvanized steel applications or anywhere a • WEEB® washer is not required • Multiple equipment ground conductor allowance: One 14 AWG to 6 AWG or two 10 AWG, two 12 AWG • Listed to ANSI/UL 467 by Intertek ETL WILEY Grounding Lug The Wiley Grounding Lug is available unassembled, without installation hardware, and with standard hole sizes of 1/4” and 5/16” (M8). Perfect for galvanized steel applications or anywhere a WEEB® washer is not required. 4004188 Grounding Lugs Customer Service 1-800-346-4175 | International 603-647-5299 | Canada 1-800-387-6487 | www.burndy.com © 2014 BURNDY LLC Connecting Power to Your World® ITEM # CATALOG #LENGTH In. [mm] WIDTH In. [mm] HEIGHT In. [mm] HOLE SIZE In. [mm]HARDWARE ASSEM- BLED TORQUE 50028861 WILEYLUG6.7 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.266 [6.76] 1/4 inch hardware not included N 7 ft lbs for terminal screw 50046765 WILEYLUG6.7HS 50028866 WILEYLUG8.0 1.575 [40.00] 0.866 [22.00] 0.472 [12.00] 0.323 [8.20] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw 50046768 WILEYLUG8.0HS 50028869 WILEYLUG8.2 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.472 [12.00] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw 50046771 WILEYLUG8.2HS 50028872 WILEYLUG15.8 1.575 [40.00] 0.709 [18.00] 0.472 [12.00] 0.323 [8.20] M8 or 5/16 inch hardware not included N 7 ft lbs for terminal screw 50046774 WILEYLUG15.8HS *HS = HEX SOCKET CAP TERMINAL SCREW LUG HS 2510 N. Hathaway St05/26/22 SM SOLAR MOUNT INSTALLATION GUIDE PAGE GROUNDING LUG MOUNTING DETAILS: Details are provided for both the WEEB and Ilsco products. The WEEBLug has a grounding symbol located on the lug assembly. The Ilsco lug has a green colored set screw for grounding indication purposes. Installation must be in accordance with NFPA NEC 70, however the electrical designer of record should refer to the latest revision of NEC for actual grounding conductor cable size WEEBLUG CONDUCTOR - UNIRAC P/N 008002S: Apply Anti Seize and insert a bolt in the aluminum rail and through the clearance hole in the stainless steel flat washer. Place the stainless steel flat washer on the bolt, oriented so the dimples will contact the aluminum rail. Place the lug portion on the bolt and stainless steel flat washer. Install stainless steel flat washer, lock washer and nut. Tighten the nut until the dimples are completely embedded into the rail and lug. See product data sheet for more details, Model No. WEEB-LUG-6.7. ILSCO LAY-IN LUG CONDUCTOR - UNIRAC P/N 008009P: Alternate Grounding Lug - Drill and bolt thru both rail walls per table. See product data sheet for more details, Model No. GBL-4DBT. GROUNDING LUG - BOLT SIZE & DRILL SIZE GROUND LIG BOLT SIZE DRILL SIZE WEEBLug 7/16”N/A - Place in Top SM Rail Slot IlSCO Lug #10-32 7/32" • Torque value depends on conductor size. • See product data sheet for torque value. SYSTEM GROUNDING 18 2510 N. Hathaway St05/26/22 Business Stream Products Renewable and Solar Technology TÜV Rheinland PTL Photovoltaic Testing Laboratory 2210 South Roosevelt Street Tempe, Arizona 85282 Main Phone: 480-966-1700 Main Fax; 775-314-6458 Email: info@tuvptl.com TÜV Rheinland North America Holding, Inc. 1 Federal Street Boston, MA 02110 Main Phone: 617-426-4888 Main Fax: 617-426-6888 Member of TÜV Rheinland Group Attn: John Nagyvary Unirac Inc. 1411 Broadway Blvd Albuquerque, NM 87102 Phone: +505 242 6411 Email: john.nagyvary@unirac.com Email: jcastagna@us.tuv .com 480-966-1700, x153 October 14, 2014 UL SU 2703 Qualification Testing Completed Type of Equipment: PV Mounting System Model Designation: Unirac Solar Mount Test Requirement: UL Subject 2703, Issue 2 TÜV Rheinland File Number: L1-URC140710B TÜV Rheinland Project Number: URC140710B Dear Mr. Nagyvary, This letter is confirmation that the Unirac Solar Mount (SM) PV Mounting System has successfully completed electrical bonding tests and mechanical loading tests according to the UL Subject 2703 standard. Congratulations on this achievement. The four PV modules used for mechanical load testing were: TSMC – TS-150C2, CIGS_Series_C2 (also known as CS_Vision)  Trina – TSM-255PA05.08 Centro E Series – E 250B, 60 cell module Centro T Series – TP6 250 SW, 60 cell module Attached are the test results of the Bonding Conductor tests according to Section 22 of UL Subject 2703. Complete test results will be provided to you separately when the full report is completed. You may use this correspondence as a an interim Letter of Compliance (LOC) indicating the Unirac Solar Mount (SM) PV Mounting System has met the relevant bonding and mechanical load requirements of UL Subject 2703 (Issue 2) pending publication of the final certificate on the TÜV Rheinland Certipedia website. Sincerely, Jack Castagna Solar Components Program Manager TÜV Rheinland PTL, LLC 2510 N. Hathaway St05/26/22 2 Attachment 1: Bonding Conductor Test Data Sample Number Sample Type 0013A L-Foot Sample – Foot to Rail 0013B L-Foot Sample – Bonding Clip to Rail 0014A L-Foot Sample – Foot to Rail 0014B L-Foot Sample – Bonding Clip to Rail 0029A End Clamp – Frame to Rail 0029B End Clamp – Clip to Rail 0030A End Clamp – Frame to Rail 0030B End Clamp – Clip to Rail 2510 N. Hathaway St05/26/22 3 Sample Number Sample Type 0005A Mid Clamp – Frame A to Rail 0005B Mid Clamp – Frame B to Rail 0006A Mid Clamp – Frame A to Rail 0006B Mid Clamp – Frame B to Rail 0021 Rail Splice 0022 Rail Splice 0043A Anodized Mounting Plate to Rail 0043B Anodized Mounting Plate to Rail 2510 N. Hathaway St05/26/22 4 Sample Number Sample Type 0039 Enphase Micro Inverter to Rail 0040 Enphase Micro Inverter to Rail 0048 End Clamp Sample with Keps Nut 0049 End Clamp Sample with Keps Nut 2510 N. Hathaway St05/26/22 1411 BROADWAY BLVD NE ALBUQUERQUE, NM 87102 USA WWW.UNIRAC.COM PRODUCT LINE: DRAWING TYPE: DESCRIPTION: REVISION DATE: SOLARMOUNT PART & ASSEMBLY L-FOOT JANUARY 2016 LEGAL NOTICE PRODUCT PROTECTED BY ONE OR MORE US PATENTS SHEET SM - A 0 2 DRAWING NOT TO SCALE ALL DIMENSIONS ARE NOMINAL 3" 2" 2" L FOOT Ø3 8" SOLARMOUNT STANDARD ON L-FOOT SOLARMOUNT HD ON L-FOOT MINIMUM HEIGHT MAXIMUM HEIGHT MINIMUM HEIGHT MAXIMUM HEIGHT 3 8-16 x 3 4 T BOLT 3 8 -16 FLANGE NUT 3 5 16" 41 2" 311 16" 47 8" SOLARMOUNT LIGHT ON L-FOOT 2 7 16 311 16 MINIMUM HEIGHT MAXIMUM HEIGHT NOTE: L-FOOT CAN BE INSTALLED IN TWO ORIENTATIONS. PLEASE REFER TO INSTRUCTIONS IN THE QUICK START GUIDE. 2510 N. Hathaway St05/26/22 1411 BROADWAY BLVD NE ALBUQUERQUE, NM 87102 USA WWW.UNIRAC.COM PRODUCT LINE: DRAWING TYPE: DESCRIPTION: REVISION DATE: SOLARMOUNT PART & ASSEMBLY BONDING TOP CLAMPS SEPT 2014 LEGAL NOTICE PRODUCT PROTECTED BY ONE OR MORE US PATENTS SHEET SM - A 0 7 DRAWING NOT TO SCALE ALL DIMENSIONS ARE NOMINAL BONDING SM END CLAMPBONDING SM MID CLAMP MID CLAMP END CLAMP 1 4" 15 16" 17 8" Ø1 4" Ø1 4" 1 3 16" 11 2" 1 8" VARIES - REFER TO SHEET SM-P04 2510 N. Hathaway St05/26/22 SFSUN FRAME RM ROOF MOUNT UL2703SYSTEM FIRE CLASSIFICATION CLASS A - TYPE 1, 2, 3 & 10 MODULES *TYPE 10 MODULES - SOLARMOUNT SYSTEM ONLY NO ADDITIONAL PARTS REQUIRED. BUSINESS AS USUAL. Unirac product lines do not require any additional parts or modifications to their existing system components to achieve a UL1703 and UL2703 Class A Rating / Fire Certification. Enjoy the same great labor savings with no additional component costs. Refer to each product’s Installation Guide and Design & Engineering Guide for specific details. BUILDING CODE REQUIREMENTS. TESTING / CERTIFICATION PROCESS. BUILDING CODE The International Building Code (IBC) 2012 has been adopted in serval states and includes new requirements for the fire classification of solar systems. These requirements are included in Chapter 15 – Roofing. The IBC applies to commercial buildings and in some instances residential buildings. IBC 2012 has been adopted by the State of California and the new requirements for the fire classification of solar systems will be effective January 2015. CERTIFIED STANDARDS UL 1703 and 2703 have been updated to reflect the new requirements in the IBC 2012. The testing requirements include: • Module Typing (Types 1 and 2 are the most common; Type 3 and 10 refer to Glass – Glass modules or ThinFilm modules) • Spread of Flame Testing (System = Module + Mounting) • Burning Brand Testing (System = Module + Mounting) WHAT YOU NEED TO KNOW 1. Check with your local AHJ to determine the required roof classification of your building. The fire classification of the solar system will need to match or be greater than the roof classification. 2. Check to see what “Type of Module” you are purchasing. 3. Check to see if your mounting system has been tested with this “Type of Module”, what fire classification was achieved, and if any additional components or installation requirements are needed. This information should be included in the mounting manufacturer’s installation instructions and certification documentation. 4. Provide the mounting manufacturer’s installation instructions and certification documentation to your AHJ for approval. QUESTIONS Info@unirac.com SM SOLAR MOUNT CLASS A - TYPE 1, 2, 3 & 10 MODULES CLASS A - TYPE 1, 2 & 3 MODULES CLASS A - TYPE 1, 2 & 3 MODULES ROOF COVERING FIRE CLASS RATING MOUNTING SYSTEM MODULE TYPE CLASSICATION COMPONENTS BURNING BRAND TEST (Pitched Roof Only) A burning wood block is placed on module as a fan blows at 12 MPH. The flame can’t be seen on the underside of the roof within 90 minutes Flame at southern edge of roof is aimed up the roof as a fan blows at 12 MPH. The flame can’t spread 6 feet or more in 10 mins. SPREAD OF FLAME TEST TESTING PROCEDURES © DIGITAL PUB 150101 2510 N. Hathaway St05/26/22 20 plf 30 plf 40 plf 50 plf 60 plf 70 plf 80 plf 100 plf 120 plf 150 plf 180 plf 0 plf 12.5 ft 11.0 ft 10.0 ft 9.0 ft 8.5 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.0 ft 4.5 ft 5 plf 12.5 ft 11.0 ft 10.0 ft 9.0 ft 8.0 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.0 ft 4.5 ft 10 plf 11.0 ft 10.0 ft 9.0 ft 8.5 ft 8.0 ft 7.5 ft 7.0 ft 6.5 ft 5.5 ft 5.0 ft 4.5 ft 15 plf 7.5 ft 7.5 ft 7.5 ft 7.5 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.5 ft 5.0 ft 4.5 ft 20 plf 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.0 ft 4.5 ft 25 plf 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 30 plf 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 35 plf 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 40 plf 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 50 plf 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 60 plf 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 70 plf 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 20 plf 30 plf 40 plf 50 plf 60 plf 70 plf 80 plf 100 plf 120 plf 150 plf 180 plf 0 plf 12.5 ft 11.0 ft 10.0 ft 9.0 ft 8.5 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.0 ft 4.0 ft 5 plf 12.5 ft 11.0 ft 10.0 ft 9.0 ft 8.0 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.0 ft 4.0 ft 10 plf 11.0 ft 10.0 ft 9.0 ft 8.5 ft 8.0 ft 7.5 ft 7.0 ft 6.5 ft 5.5 ft 5.0 ft 4.0 ft 15 plf 7.5 ft 7.5 ft 7.5 ft 7.5 ft 7.5 ft 7.0 ft 6.5 ft 6.0 ft 5.5 ft 5.0 ft 4.0 ft 20 plf 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.5 ft 5.0 ft 4.0 ft 25 plf 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.5 ft 4.0 ft 30 plf 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 3.5 ft 35 plf 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 3.0 ft 40 plf 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 50 plf 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 2.0 ft 60 plf 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 70 plf 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft 1.5 ft Example: 60 plf Downward Load (strong axis)8.0 ft Max Span for Downforce 50 plf Upward Load (strong axis)8.5 ft Max Span for Uplift 10 plf Horizontal Load (weak axis)8.0 ft Max Span = min (downforce, uplift) with SOLARMOUNT Standard Rail Horizontal Load SOLARMOUNT Standard Rail Downforce Span Length Horizontal Load SOLARMOUNT Standard Rail Uplift Span Length Note: No Interpolation Permitted. APPENDIX C Downward & Upward Span Length Tables PAGE C1 2510 N. Hathaway St05/26/22 (805) 486-4700 (805) 486-4799–fax 1551 S. Rose Ave. Oxnard, CA 93033 View more info on our website at: www.prosolar.com Tile Roof Structural Attachment Without TileTrac® With TileTrac® Patent #5,746,029 The TileTrac® Design Structurally attaches to roof rafter and allows the rail attachment stud to be located at the strongest point of the tile (the crown) where water does not flow. Part # TT-18-T6 TileTrac® for s-curve concrete tile (6” Tall Threaded Stud) TileTrac® for flat concrete tile (4” Tall Threaded Stud) Part # TT-18-T4 The patented TileTrac ® attachment allows for a structural roof rafter connection with optimal attachment stud location adjustability. Design results in the best looking systems in the industry. • Aluminum and Stainless Steel components for corrosion resistance and strength • 1,740 lbs of 3rd party lab tested pullout strength • Water-tight seal lab tested for 7 days under 34 inches of water, zero leakage • 10 sq. inches of base area evenly distributes roof load and provides sufficient sealant bonding area • Industry’s most cost effective tile attachment product • Minimal install labor and time • Over 12 years of industry preferred design • Requires only one Stainless Steel lag bolt (included) Benefits of the TileTrac® TileTrac ® assembly structurally attached to the rafter Support Rail Water Flows in the Valley of the Tile High Point/ Crown of the Tile (optimum) RafterRafter Not structurally attached to the rafter Third Party Lab Tested 1,740 lbs. Pullout Va l u e 2510 N. Hathaway St05/26/22 Installation steps for both s-curve and flat concrete tile* STEP 1: Select a tile in the area of the roof rafter. STEP 2: Remove the tile by pushing and pulling. It is usually held in place by a small nail. STEP 3: Using an electronic stud finder (recommended), or other means, locate the rafter center. Mark a reference point on the tile above. Step 4: Seal the initial tile nail hole. Using a 3/16” drill bit and drill guide (FJ-Drill), drill pilot hole along the rafter center Step 5: Insert the lag bolt and washer through the TileTrac ® and apply fresh room temperature sealant to the base. Step 6: Using a 1/2" socket, install the lag bolt until seated. Do not overtighten. The sealant should flow outward sealing any holes. Step 7: After bolting the base to the roof, slide the upper carriage into the correct position under the crown of the tile. For Flat tile, slide the upper carriage near the middle of the tile. Step 8: Replace the tile by lining up the snap lines and mark the drill location accordingly. Step 9: Using a 3/8” carbide drill bit and ROTARY HAMMER DRILL in hammer mode, drill through the tile. See online video at www.prosolar.com for details. Step 10: Insert the threaded stud through the tile and tighten with 9/16" wrenches to engage stud with base. Bind two 3/8” nuts (included) using 9/16” wrenches and tighten. Step 11: Unbind nuts and remove from stud. Apply UV rated sealant between stud base and tile and compress with a 3/8" washer. Apply UV rated sealant around top of washer. *Not recommended for clay or slate tiles. Step 12: Fasten rail with lower and upper 3/8" nuts/washers as shown. Use a Rotary Hammer drill for a 5 second drill time. Tip: Use a cordless impact wrench Tip: Bind (2) 3/8" nuts and washers to top of stud prior to roof work Drill 3/16" pilot hole. ©Professional Solar Products, Inc. June 2008. TileTrac®is a registered trademark and covered under Pat. #5,746,029 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 2510 N. Hathaway St05/26/22 Page 1 of 8 TileTrac Installation Manual Date Modified: 09/12/07 APPLICATION: The TileTrac ® attachment can be used on both composition (comp) and concrete tile roof surfaces. The TileTrac ® TT-18S is in- tended for use on comp roofs and the Tile- Trac ® TT-18T is intended for use on tile roofs. Note: The TileTrac ® is not recommended for clay tile roofs. Symbol Legend Explanation or Install Tip Important Product Performance Information Critical for Safety WARNING All Professional Solar Products (ProSolar) are engi- neered and tested to withstand stated specifica- tions (as stated on published specification sheets) when installed properly. Failure to install properly may decrease the performance of the installation. SAFETY All regional safety requirements should be followed when installing ProSolar Products. All tools and equipment located on the roof should be secured to avoid falling object haz- ards. All equipment/tools should be properly maintained and inspected prior to use. Any exposed studs should be protectively capped to help avoid injury. This installation manual is intended for use by professional installers with a working knowledge of construction principles. Tool List •Chalk line •Cordless rotary hammer drill with 3/8” carbide masonry bit (for concrete roof tile drilling). •Cordless standard drill with 3/16” long drill bit (for lag bolt pilot hole) •Cordless standard drill with 1/4” carbide masonry bit (for breaking through composition roof shingle surface only; NOT FOR PILOT HOLE) •Cordless impact wrench with 1/2” socket •Mastic or roof sealant recommended: Tripolymer based, such as Geocel 2300 •Lumber Crayon •3/16” T-handle hex key (for composition shingle roof) •Precision electronic stud sensor •Dead-blow hammer (approx. 20 oz) ® Use of a Rotary Hammer drill is highly recom- mended. A Rotary Hammer drill (est. retail: $500-$700) reduces concrete roof tile drill time to approx. 2 seconds. A hammer drill (est. retail: $250) will dramatically in- crease drill time to over one minute. Use of a standard drill will increase time to approx. 10 minutes. 2510 N. Hathaway St05/26/22 Page 2 of 8 Date Modified: 09/12/07 Installation steps overview 1) System layout & chalk line marking 2) Locating roof rafters along chalk lines 3a) Sealing/attaching TileTrac® (S-Tile Roof) 3b) Sealing/attaching TileTrac ® (Composition Shingle Roof) 4) Clean up/Quality Inspection Step 1: System layout & chalk line marking Prior to beginning attachment work, the system roof layout should be defined. A drawing or sketch, prior to roof work, is recommended. Upon finalizing layout, use chalk lines to mark support rail locations. The chalk lines will be used to align TileTrac ® attachment points. Note: All support rails should be placed 48” apart along the module length. The rail dis- tance from the end of the module will vary based on module size. The 48” grid design is based on 12”, 16” or 24” on center (o/c) rafter spacing. (12” x 4 = 48”, 16” x 3 = 48”, 24” x 2 = 48”) All product specifications are based on 48” paired support rail spacing. Proper module/rail orientation—single array sample Rafter Directio n Supp o r t Rai l Direc t ion Clamps must secure the module on the long end of the frame. The span of the two support rails should be 48”. EXAMPLE: (Using a 64” long module) 48” 64” 8” 8” TileTrac Installation Manual ® Note: When configuring layout account for a 0.6” inter- module clamp space between modules and 2” for each end of the module array for end clamp spacing. Chalk line — to reference support rail placement 48” typical 0.6” Intermodule clamp spacing 2.0” End Clamp spacing 2510 N. Hathaway St05/26/22 Page 3 of 8 Date Modified: 09/12/07 Step 2: Locating roof rafters along chalk lines 1) Since rafters are normally located every 48” on center (o/c), finding one reference rafter should be sufficient for approximating the lo- cation of additional rafters by measuring 48” from the center of the first. 2) If the roof eve (bottom edge of roof) is ex- posed, reference the bottom edge of the roof rafter location and use to approximate the lo- cation of the roof rafter/intersection chalk line on the upper section of roof. (EASIEST FOR TILE ROOF) If the roof has a closed or blind soffet (enclosed rafters not visible at roof edge), the nailing pattern along the fascia board (board attached to ends of rafters) may indi- cate the rafter location at the bottom edge of the roof. TileTrac Installation Manual ® For installations requiring more than one row, with no spacing between rows, the distance between adjacent rail pairs will measure approximately the length of the module less 48”. The measurements and formulas listed above are the recommended and engi- neered values for the RoofTrac ® mount- ing system—non-tilt up. 48” Snap chalk lines along the location of where the support rails will be placed once spacing is calculated and measured. Actual spacing will be deter- mined on pattern of the roofing material to ensure a proper seal. 2510 N. Hathaway St05/26/22 Page 4 of 8 Mark (with lumber crayon) or account for ALL holes, including small nail holes to ensure roof is properly sealed. Approximate attaching/sealing time: 5 min. per attachment. STEP 1: Select a tile in the area of the roof rafter referenced by your chalk lines. STEP 2: Remove the tile by push- ing and pulling the tile, usually held in place by a small nail. STEP 3: Using an electronic stud finder locate the rafter center. Mark a reference point on the tile above. STEP 4: Drill several holes (if nec- essary) to locate the exact rafter center. A 3/16” pilot hole drill bit is recommended. STEP 5: Insert the lag bolt and washer through the TileTrac ® and apply fresh sealant to the base. Step 3a: Attaching / Sealing TileTrac® (Concrete Curve Tile Roof) Alternate methods of finding rafter center (STEP 3): 1) Using a dead-blow hammer, lightly tap perpendicular to the rafter until a solid sound is heard. Mark this location. 2) If attic is accessible, driving a nail upward beside the rafter may provide an adequate reference point. Roofing mastic/sealant must be applied per manufacturer’s specifica- tions. Mastic/sealant should be fresh and applied at room tempera- ture, as necessary. Date Modified: 09/12/07 TileTrac Installation Manual ® STEP 1 STEP 2 STEP 3 STEP 4 STEP 5 2510 N. Hathaway St05/26/22 Page 5 of 8 STEP 6: Install the lag bolt into the roof (cordless impact wrench rec- ommended) using a ½” socket drive until the lag bolt is seated. DO NOT OVERTIGHTEN. The sealant should flow outward sealing any holes made to locate the rafter. STEP 7: After bolting TileTrac ® to the roof, slide the upper carriage into the correct position under the crown of the tile. STEP 8: Replace the tile by lining up the snap lines, the tile is now ready to be marked and drilled. STEP 9: Using a 3/8” carbide bit and a rotary hammer, drill through the crown of the tile at the intersection of the chalk line and the reference marks. STEP 10: Insert the threaded shaft through the tile into the upper carriage. Bind two 3/8” nuts (provided) using two opposing 9/16” wrenches and tighten to 14 ft. lbs. Before replacing tiles, be sure ALL holes have been properly sealed, including the original hole used to hold the tile in place. Water flows through the valley (lowest point) of the tile, not the crown (highest point), which virtually eliminates any chance of water leakage through the tile attachment. The crown of the tile is the strongest point and will not break when properly drilled. Avoid attaching/drilling in the valley of the tile to prevent water/debris build-up which may lead to leakage. Date Modified: 09/12/07 TileTrac Installation Manual ® A Rotary Hammer Drill re- duces concrete roof tile drill time to approx. 2 seconds. A hammer drill will dramati- cally increase drill time to over one minute. Use of a standard drill will increase time to approx. 10 min- utes. See www.prosolar.com/ tiledrill.htm for demonstration. CROWN OF THE TILE (Highest/ strongest point) STEP 6 STEP 7 STEP 8 STEP 9 STEP 10 2510 N. Hathaway St05/26/22 Page 6 of 8 STEP 11: Apply UV rated sealant around the threaded shaft and com- press with a 3/8” washer included in the kit. The 3/8” box-end wrench can be used for this. STEP 12: Apply UV rated sealant around the top of the washer to com- plete the waterproof tile seal. Now the tile is completely waterproof. Step 3b: Attaching / Sealing TileTrac® (Composition Roof) STEP 2: Drill a 3/16” pilot hole to depth of the lag bolt. STEP 3: Apply a generous amount of fresh sealant (polyurethane based, such as Sikaflex 1-a recom- mended) to the base. Roofing mastic/sealant must be ap- plied per manufacturer’s specifica- tions. Mastic/sealant should be fresh and applied at room temperature, as necessary. Date Modified: 09/12/07 TileTrac Installation Manual ® Use of a 1/4” carbide tipped drill bit for breaking through the rough composition shingle surface only (not for pilot hole) will avoid premature pilot hole drill bit wear. The use of two drills—one for breaking through surface, one for pilot hole drill- ing—to decrease drill time is recommended. STEP 11 STEP 12 STEP 1 STEP 2 STEP 3 STEP 1: Using a precision stud finder, locate the absolute center of the rafter. Mark with a crayon/chalk. See section 3a Install Tip for additional methods for locating rafters. 2510 N. Hathaway St05/26/22 Page 7 of 8 STEP 4: Install the lag bolt and washer into the roof (cordless im- pact wrench recommended) using a ½” socket drive until the lag bolt is seated. DO NOT OVERTIGHTEN. The sealant should flow outward sealing any holes that were made to locate the rafter. STEP 5: After bolting TileTrac ® to the roof, slide the upper carriage into the desired position. STEP 6: Thread the short cup head stud into the upper carriage with a hex key and tighten to 14 ft/lbs. The nut/washer combination will be installed after the support rail is in place. Repeat steps 1-6 until all TileTrac® attachments are installed, then refer to the RoofTrac ® installation guide for the support rail and mod- ule clamping installation steps. Step 5: Clean up / Quality Inspection Clean-Up: Account for all tools and clean area as necessary. Quality Inspection: Contractors are advised to perform a final attachment quality inspection prior to installing the RoofTrac® mounting system to ensure all attachments are properly fastened. Make sure all installation crew members on the roof are mind- ful of protruding roof attach- ments to prevent tripping. All installation crew members should utilize proper safety equipment when installing a solar system. Date Modified: 09/12/07 TileTrac Installation Manual ® STEP 4 STEP 5 STEP 6 2510 N. Hathaway St05/26/22 26372 SANTA ROSA AVE. LAGUNA HILLS, CA 92653 HILLARD, JOHN Prepared For: REVCO SOLAR ENGINEERING, INC. 26631 CABOT RD., STE. B LAGUNA HILLS, CA 92653 (949) 367-0740 Design Criteria 1- Code: CALIFORNIA BLDG CODE 2019 / ASCE 7-16 2 - Wind: 95 MPH, Exposure: C 3 - Wood Species: DF-L No. 2 (SG = 0.5 ) Notice: Use restrictions of these calculations. The attached Calculations are valid only when bearing original signature hereon. Contractor/Client to verify existing dimensions/conditions prior to construction & solar racking is installed per manufacturer span requirements. The use of these calculations is solely intended for the above mentioned project. 5/12/2022 Structural Calculations for SOLAR POWER SYSTEM CONNECTION CHECK AT: Job: 1-844-PV ELITE | info@yoursolarplans.com 3000 E. Birch Street Suite 201 | Brea CA 92821 2510 N. Hathaway St05/26/22 01231334267689 9  711 !1"1#$ %&&''6''68( !%)22 '*0&8+*+(,%3026-#./3 .9/3  983'60/3 0.9 213  123456789:4;3<=:8 >??42@@A 3026-#.4.94 983'604 0.9 B::4?=83<2@A &&''6''684)22 '*0&8+*+ CD2E3<=:8A 2 '8F G=;2@<3;HA 3633)60)23 2 '76873I003J K3L34?GMH2A N >1BCOPQ R ST26)U,++V ST30)U,'2 V ST06)U,''V ST266)U,*2 V SW ,!T *8V SW ,!TT 80 V SW ,!TTT 263 V SW ,!TX 26+V >1BCOPQ Y ST26)U,'3 V ST30)U,'8V ST06)U,*0 V ST266)U,82 V SW ,!T 266 V SW ,!TT 226 V SW ,!TTT)TX 220 V >1BCOPYZ 9. [')60N.,,*0 V \]^_^`abc`defdghc^f]^_^ijkj\_^lb^gchem`chc^n_bnghbho^efo^ec`cnc]^phba^`n_hemf^bde^hcdnebde^`ohf^fa_deqc]^radbfdeq gnf^hfnscdnes_ng^``tu`^_``]nabfgneld_ohemnacsacnrchde^fl_noc]d`cnnbvdc]c]^bnghbwac]n_dcmxhpdeqya_d`fdgcdner^ln_^ s_ng^^fdeqvdc]f^`dqet z=@5D3=;24  ,, ,FV{,9. [',,,,# ,,!,|,9. ['4  ,,,  ,, #,,F, ,}V,,4#,,# ,~ , , #,,,,F,4{,#,, ! !,- [7€,,,#),,,! ,4,, !,,V,{,!#VFF,#,,,,,##), ,,! ,4!!,4,V,4, #,! ,,~V,F # N ,,FV,,,#,,, ,{,,,49 V,,    F ,V, ,,,,, ,,, ,F,F # V,,,~V{,FF4   ,!,,, ,,F, 9 , ,,,FFV, ,,‚!V,FV,,F, 4{!,~,,,W# ,!, ,F, F,4,F,F,,,FF, ,,! !,, F, ,{,#,,0,F,FVFV#,,V,   !FV,0,F,F #,,,V { ,!{,! !,,, ,F !,{ ,,F, ƒ„…†‡ ˆ‰Š‹ŒŽŽŠ‰ŒŒ‹ŒŽŠ‘ŽŽ’“”““•‹‹–—‰˜™š›•™ 2510 N. Hathaway St05/26/22 ASCE 29.4.4 Rooftop Solar Panels Parallel to the Roof Surface on Buildings of All Heights and Roof Slopes. Roof Slope  = 18.43 ° Roof Shape Gable Tributary Width s = 6.00 ft Tributary Length l = 2.70 ft Effective Area A e = 11.85 ft2 Height of Structure h = 15 ft Wind Speed V = 95 mph Exposure Category C Building Width B = 40 ft Building Length L = 50 ft Zone Width a = 4 ft Elevation Height zg = 179 ft Wind Directionality Kd = 0.85 Topography Factor Kt = 1.00 Ground Elevation Factor Ke = 0.99 Velocity Pressure Exposure Coefficient Kz = 0.85 Velocity Pressure q z = 0.00256KzKztKdKeV2 = 16.56 psf Solar Array Pressure Equalization a = 0.79 Array Edge Factor E = 1.50 Zone GCp p = qz(GCp)(E)(a) 3 - - 3r 3.56 -70.09 3e 2.98 -58.71 2 - - 2r 2.98 -58.71 2e - - 2n 2.98 -58.71 1 - - 1' - - 2510 N. Hathaway St05/26/22 LAG SCREW ANALYSIS Loads Wind Pressures qz = -58.71 psf Solar Panel Load QD = 3 psf Panel Length l = 5.393 ft Panel Width b 3.95 ft Attachment Spacing s = 6 ft Portrait Tributary Area At = 16.18 ft2 Wind Load P W = qz * At = -950 lbs Dead Load P D = Q D * At = 48.54 lbs Uplift Pa = 0.6 P D + 0.6 Pw = -541 lbs Landscape Tributary Area At = b * s = 11.85 ft2 Wind Load P W = qz * At = -696 lbs Dead Load P D = Q D * At = 35.55 lbs Uplift Pa = 0.6 P D + 0.6 Pw = -396 lbs Lag Screw 5/16" x 5" Specific Gravity of Lumber SG = 0.50 (Douglas Fir-Larch) Diameter of Lag Screw D = 5/16 in Withdraw Design /in 1800*SG 3/2 *D 3/4 = 266 lbs/in Depth of Embedment lp = 2.50 in Total Nominal Withdrawal Value W = W * l p = 665 lbs Load Duration Factor CD = 1.6 Withdrawal Design Value W' = W * C D = 1064 lbs Demand Capacity Ratio DCR = Pa / W' = 0.51 < 1 OK 2510 N. Hathaway St05/26/22 ASCE 30.3.2 Design Wind Pressure Beam/ Top Chord Check Roof Slope  = 18.43 ° Roof Shape Gable Tributary Width s = 2.00 ft Tributary Length L = 21.34 ft Effective Area A = L ( MAX [ s , L/3] ) = 100 ft2 Height of Structure h = 15 ft Wind Speed V = 95 mph Exposure Category C Building Width B = 40 ft Building Length L = 50 ft Zone Width a = 4 ft Elevation Height zg = 179 ft Wind Directionality Kd = 0.85 Topography Factor Kt = 1.00 Ground Elevation Factor Ke = 0.99 Velocity Pressure Exposure Coefficient Kz = 0.85 Velocity Pressure q z = 0.00256KzKztKdKeV 2 = 16.56 psf Internal Pressure Coefficient (GCpi) = -0.18 Zone GCp p = q z [(GCp) - (Gcpi)] 3 - - 3r 1.80 -32.79 3e 2.25 -40.25 2 - - 2r 2.25 -40.25 2e - - 2n 2.25 -40.25 1 - - 1' - - 2510 N. Hathaway St05/26/22 Beam/ Top Chord Check Lumber: Moment Demand # of Attachment per Rafter N A = Span : Orientation Lenght (ft) : Dead Load Roof Material: Q D = psf Live Load QLr = psf Wind Load p = psf Snow Load QS = psf Rafter Spacing s = in Wind Load, Portrait Portrait UL = Wind Load, Landscape Landscape U W = Linear Dead Load wd = plf Live Load wLr = plf Start ft Start ft End ft End ft Snow Load ws = plf Start ft Start ft End ft End ft Ma, Moment D lb-ft D+Lr lb-ft D+S lb-ft 0.6D+0.6W lb-ft D+0.45W+0.75Lr lb-ft D+0.45W+0.75S lb-ft Moment Capacity Framing Member Size Lumber Grade : DF-L No. 2 C M = 1 Ct = 1 Cr= CF = fb = psi C fu =C i = Breadth b = in Depth d = in Section Modulus Sx = bd 2 / 6 = in3 Bending Stress Capacity Fb = CM * C t * Cr * C F * fb = psi Table 4.3.1 NDS 2015 Deflection Limit E = ksi I = in4 Transient Deflection in Transient Deflection Allowed > [OKAY] Total Deflection in Total Deflection Allowed > [OKAY] 1.0 1 20 0.00 24 Tile 0.295 414 180 1.6 2153 psi D+0.45W+0.75S 566 psi 0.26 OKAY 1.6 2153 psi D+0.45W+0.75Lr 566 psi 0.26 OKAY 1.6 2153 psi 0.328 372 120 1600 20.80 0.6D+0.6W 1325 psi 0.62 OKAY 1.15 1547 psi D+S 915 psi 0.59 OKAY OKAY 1.25 1682 psi D+Lr 1046 psi 0.62 OKAY DCR 0.9 1211 psi D 915 psi 0.76 7.56 1346 CD Fb' = C D * F b ASD Load Ma * S x 2X6 1.15 1.3 21.34 14.85 21.34 900 1.50 5.50 577 659 577 835 357 357 0 0.0 0 3 0 0 0.0 Portrait 3 0.0 Portrait 0 0.0 0.0 AT (ft2) 16.18 11.85 pd (lbs) 48.54 -651 p w (lbs) ps (lbs) 0 14.85 40 0.0 0.0 0.0 0.0 0 0.0 Portrait 0 0.0 35.55 -477 0 -477 0.0 Landscape 5 11.7 35.6 -477 0.0 34 1 2 3 4 Eave 2 0.0 0.0 0.0 0.0 0.0 0 0.0 0.0 0.0 0.0 0 0.0 0.0 0.0 0.0 6 14.1 35.6 0.0 10.17 10.17 0.00 0.00 1.00 Landscape 3 7.7 35.6 17.00 -40.25 DF-L No. 2 6 j lj (ft) pd,j  (lbs) pw,j  (lbs) ps,j  (lbs) Landscape 1 3.8 35.6 -477 0.0 6.2 35.6 -477 -477 0.0 4 10.1 35.6 -477 0.0 ൌ ሺ െ ሻ െ െ െ ‐1000.0 ‐500.0 0.0 500.0 1000.0 0.000 5.000 10.000 15.000 20.000 25.000 2510 N. Hathaway St05/26/22 EISMIC WEIGHT COMPARISON / ANALYSIS - (PER CEBC 2019 Part 10 Chapter 5 Section 502.5) PV System Weight Module Model Solaria Panel Weight Wpanel = 46 lbs Number of Panels NPV = 25 Total PV System Weight W PV = Wpanel * NPV = 1150 lbs Existing Roof Weight Roof Weight QD =17.0 psf Building Length Lbuild =50 ft Building Width W build =40 ft Roof Area Abuild =2000 ft2 Building Perimeter Pbuild = 180 ft Wall Height ht = 8 ft Wall weight Qwall = 15 psf Interior wall weight Qint = 10 psf Roof Load Wfloor = Abuild * QD = 34000 lbs Wall LoadWwall = ht /2 * Qwall * Pbuild + Abuild * Qint /2 = 20800 lbs Total Story Weight Wbuild = Wfloor + Wwall = 54800 lbs Percentage Weight Increase WPV / Wbuild = 2.10%< 10% OKAY 2510 N. Hathaway St05/26/22