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BUTTE COUNTY AREA y DEPARTMENT OF DEVELOPMENT SERVICES INSPECTION CARD MUST BE ON JOB SITE 1{ 0 24 Hour Inspection Line (IVR) : 530.538.4365 (Cut off time for inspections is 3pm) - Development Services cannot guarantee inspections on the date requested " oeve�ov�,rr+r sEQvrcEs •- � — ---- - --- Office: 530.538.7601 Fax: 530 r a r f 'ALL PLAN REVISIONS MUST BE APPROVED BY -THE COUNTY BEFORE PROCEEDING - Inspection a IVR INSP DATE Setbacks 131 Foundations / Footings 1 I 1 Pier/Column Footings 122 Eufer Ground 216 ` Masonry Grout 120 Setbacks 131 Do Not Pour Concrete Until Above are Sign d Pre -Slab 124 Gas Test Underground/floor 404 Gas Piping Underground/floor 403 Underfloor Framing 149 Underfloor Ducts 319 Shear Transfer 136 Under Floor Plumbing 412 Under Slab Plumbing 411 Blockin nder inin 612 Tiedown/Soft Set System 611 Do Not Install Floor Sheathing or Slab Until Above Signed ShearwallB.W.P.-Interior 134 'ShearwalUB.W.P.-Exterior 135 Roof Nail/Drag Trusses 129 Manometer Test 605 Do Not Install Sidin Stucco or Roofing Until Above Signed Rough Framing 153 Rough Plumbing 406 Rough Mechanical 316 Rough Electrical 208 4 -Way Rough Framing 128 . Gas Piping House _ 403 Gas Test House 404 Shower Pan/Tub Test 408 Do Not Insulate Until Above Signed Inspection Type IVR INSP DATE T -Bar Ceiling 145 Stucco Lath 142 Plumbing Final 813 Fire Sprinkler Test or Final , 702 Swimming Pools Setbacks 131 Pool Plumbing Test 504 Gas Test 404 Pre-Gunite 506 Pre -Deck 505 Pool Fencing/Al arms/Barriers 503 Pre -Plaster 507 anuf ctu ed Homes Setbacks 131 Blockin nder inin 612 Tiedown/Soft Set System 611 Permanent Foundation System 613 Underground Electric 218 Sewer 407 Underground Water 417 Manometer Test 605 Continuity Test 602 Ski rtin Ste s/Landin gs 610 Coach Info Manufactures Name: Date of Manufacture: Model Name/Number: Serial Numbers: Length x Width: Insignia: t , a F . i�. .. Permit Final 802 Electrical Final 803 Mechanical Final t 809 Plumbing Final 813 Fire Sprinkler Test or Final , 702 Public Works Final 538.7681 Fire De artment/CDF 538.6226 Env. Health Final 538.7281 Sewer District Final r"TROJECT FINAL FEW I II/Me ' - *Project Final is a Certificate of Occupancy for (Residential Only) ' PERMITS BECOME NULL AND VOID I.YEAR FROM THE DATE OF ISSUANCE. IF WORK HAS COMMENCED, YOU MAY PAY FOR A LYEAR. :RENEWAL 30 DAYS PRIOR TO EXPIRATION y V Carbon monoxide alarms required by Sections R315.1 and R315.2 shall be installed in the following locations: 1. Outside of each separate dwelling unit sleeping area in the immediate vicinity of the bedroom(s). 2. On every level of a dwelling unit including basements. R315.1.5 Multiple -purpose alarms: Carbon monoxide alarms combined with smoke alarms shall comply with Section R315, all applicable standards, and requirements for listing and approval by -the Office of the State Fire Marshal, for smoke alarms. Butte County's Interpretation of 2016 CRC, Sections 314 &+315 for Smoke Alarms & Carbon Monoxide Alarms: Where alterations, repairs or additions exceeding $1,000 in valuation, existing dwellings shall be retrofitted with smoke alarms and those that have attached garages or fuel -burning appliances shall have carbon monoxide alarms installed. Existing smoke alarms can be replaced with dual function alarms for Smoke and Carbon Monoxide and in most cases will comply with the aforementioned code requirements for Carbon Monoxide Alarms. DECLARATION OF INSTALLATION UNDER THE PENALTY OF PERJURY As, Owner/Contractor, I/we affirm and declare under the penalty of perjury, under the laws of the State of California, by our signatures below as Owner/Contractor, that I/we will comply prior to final inspection with Items A & B as specified herein: A. Both Owner/Contractor have read and clearly understand the aforementioned 2016 California Residential Code (CRC) Carbon Monoxide Alarm requirements. B. Both Owner/Contractor are responsible for installing Carbon Monoxide Alarms prior to final inspection as per the aforementioned building code and maintaining such installation. Smoke Alarms will also be installed prior to final inspection as per the 2016 CRC. Smoke and Carbon Monoxide alarms are now installed in the following locations. PA /I W6" C0 -46h �7 %PPS n Srncke- Owner's name (print)- VTt&L e (2 KJt Owner's signature Date: /-P7 —I K - Contractor's nam print): _ 13ir-W A Mary e 1i CSLB License: Contractor's signature: Date: r ,, T11 y 7% —202 Project Address: e: Permit #:@-7 w Page 2 of 2 Revised 12.19.2016 Butte County Department of Development Services FORM NO PERMIT CENTER - 7 County Center Drive, Oroville, CA 95965 DBI -01 axe»,��a1 Main Phone (530) 538-7601 Fax (530) 538-7785 www.bunecountv.net/dds Declaration of Installation for Smoke Alarms and Carbon Monoxide Alarms The newly adopted 2016 California Residential Code requires the installation of Carbon Monoxide Detectors in dwelling units and in sleeping units within which fuel -burning appliances are installed and in dwelling units that have attached garages. The policy for Carbon Monoxide Alarms in Butte County states: "Any permit obtained in which the value of work exceeds $1000 associated with a Residential Group R Dwelling Unit or Sleeping Unit shall conform to the, following 2016 California Residential Code requirements for Smoke and Carbon Monoxide Alarms (Section R314 & R315)." 2016 California Residential Code requirements for Carbon Monoxide Alarms: R315.1 New construction: An approved carbon monoxide alarm shall be installed in dwelling units and in sleeping units within which fuel -burning appliances are installed and in dwelling units that have attached garages. R315.1.2 Power supply: For new construction required carbon monoxide alarms shall receive their primary power from the building wiring where such wiring is served from a commercial source and shall be equipped with a battery back-up. Alarm wiring shall be directly connected to the permanent building wiring without a disconnecting switch other than as required for over - current protection. Exceptions: 1. In dwelling units where there is no commercial power supply the carbon monoxide alarm may be solely battery operated. 2. In existing dwelling units a carbon monoxide alarm is permitted to be solely battery operated where repairs or alterations do not result in the removal of wall and ceiling finishes or there is no access by means of attic, basement or crawl space. R315.1.3 Interconnection. Where more than one carbon monoxide alarm is required to be installed within the dwelling unit or within a sleeping unit the alarm shall be interconnected in a manner that activation of one alarm shall activate all of the alarms in the individual unit. Exception: 1. Interconnection is not required in existing dwelling units where repairs do not result in the removal of wall and ceiling finishes, there is no access by means of attic, basement or crawl space, and no previous method for interconnection existed. R315.2 Where required in existing dwellings: Where a permit is required for alterations, repairs or additions exceeding one thousand dollars ($1,000), existing dwellings or sleeping units that have attached garages or fuel -burning appliances shall be provided with a carbon monoxide alarm in accordance with Section R315.1. Carbon monoxide alarms shall only be required in the specific dwelling unit or sleeping unit for which the permit was obtained. R315.2.6 Alarm requirements: No person shall install, market, distribute, offer for sale or sell any carbon monoxide device in the State of California unless the device and instructions have been approved and listed by the State Fire Marshal. Page] of 2 Revised 12.19.2016 x. ,SCOPE OF WORK: THE SYSTEM CONSISTSOF_A 5.88 KW DC (5.00 KW AC) _ = - ROOF-MOUNRTED PHOTOVOLTAIC- POWER SYSTEM OPERATING. -IN ;PARALLEL WITH THE UTILITY GRID. THERE ARE (2 1) TRINA TSM-280DD05A.08(II) -MODULES AND. (1) SOLAR EDGE SE5000H-US _ STRING INVERTER(S), CONNECTING TO THE UTILITY GRID THROUGH THE UPGRADED MAIN LOAD CENTER. ELECTRICAL MODIFICATIONS_ WILL BE MADETO THE MAIN LOAD CENTER. • INTERCONNECTION METHOD: LOAD SIDE BREAKER _ ROOF MATERIAL: COMP. SHINGLE PROJECT WILL COMPLY WITH THE 2016 CRC, 2016 CEC; . 20.1'6 • - CBC, AND 2016 CFC, 2015--l-RC, 2014 NEC, 2015 IBC, 20.15 IFC. ' • . 4801 N UNIVERSITY AVE, #900 PROVO, UT 84604 (888) 781-7074 c7 a a¢ pU M LICENSED ELECTRICAL CONTRACTOR • - - - z - - COMPANY: ION DEVELOPER LLC . ..F CLASSIFICATION: • _ - - - - C 10 AVI'IIORVED CON7RAROR: LICENSE NUMBER: ` 1027027 5131/2 + v EXPIRATION: Ill/C/[]/, _ , • - r: 5/312011 9 SYSTEM SIZE: 5.88 kW DC • 5.00 kW AC 21 MODULES • - - DATE: 11/24/2017 f_ DRAWN BY: JPL ADDITIONAL NOTES: SHEET: COVER - a AC DISCONNECT LOCATED NEXT TO OR WITHIN 10 FEET OF MAIN SERVICE PANEL(LINE OF SIGHT MAINTAINED), PV 1.0 r - r ` ION, 4801 N UNIVERSITY AVE, 4900 PROVO, UT 84604 (888) 781.7074 H-4 a Obi W aU A co u � U M ITY METER LOCATION J SERVICE LOCATION/ T OF INTERCONNECTION ...,,......,QCT SWITCH LICENSED ELECTRICAL CONTRACTOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: C 10 AUTUORMCDCOWMACTOR: LICENSE NUMBER: 1027027 TION I �/ • EXPIRATION:-�,,- 5/31/2019 SYSTEM SIZE: 5.88 kW DC 5.00 kW AC 21 MODULES DATE: 11/24/2017 DRAWN BY: TPL ADDITIONAL NOTES: ®- STRING I SCALE: SITE PLAN PV 2.0 ION Ai 4801 N UNIVERSITY AVE, #900 - • PROVO, UT 84604 ` (888)781-7074 (I, 1Y1J1 AL1 llll 1\l11LJ ROOF SECTION DATA ROOF SECTION A B C D E F G H MODULES 21 TILT 19 AZIMUTH 270 V SOLAR ACCESS AVG. 96.00% e a . • � L7.1 M 3' a pU OU w U m `- x 3 z M h - ......... �...-... r . n....��..-.... i. moi•.. r�r.r..�rr. _ : ION Ai 4801 N UNIVERSITY AVE, #900 - • PROVO, UT 84604 ` (888)781-7074 (I, 1Y1J1 AL1 llll 1\l11LJ ROOF SECTION DATA ROOF SECTION A B C D E F G H MODULES 21 TILT 19 AZIMUTH 270 V SOLAR ACCESS AVG. 96.00% e a . • � L7.1 M 3' a pU OU w U m `- x 3 z M h LICENSED ELECTRICAL CONTRACTOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: C10 LICENSE NUMBER: ALM1OLCDCONCT OR/tom 102702 EXPIRATION: 5/31/2011 9 SYSTEM SIZE: S.HH kW DC 5.00 kW AC 21 MODULES DATE: 11/24/2017 DRAWN BY: JPL ADDITIONAL NOTES: FIRE CODE OFFSET 2" X 4" TRUSS SYSTEM 24" ON CENTER SCALE. CANTILEVERS WILL BE NO MORE THAN 24" ATTACHMENT POINTS WILL BE NO MORE THAN 6' APART, STAGGERED SHEET: ROOF PLAN PV 3.0 WEATHER DATA HIGH TEMP, 2% AVG. 40 OC MIN DESIGN TEMP -4 OC GROUND SNOW LOAD' - 0 psf WIND SPEED 110 mph 2. MINIMUM DESIGN TEMPERATURE BASED ON ASHRAEMIAIIMUM FROM 2009 ASHRAE HANDBOOK`- FUNDAMENTALS - 1. HIGH TEMPERATURE 2% AVERAGE BASED ON ASHRAE HIGHEST MONTH 2% DRY BULB TEMPERATURE FOR ASHRAE LOCATION ` MOST SIMILAR TO INSTALLATION LOCATION 2. MINIMUM DESIGN TEMPERATURE BASED ON ASHRAEMIAIIMUM ~ MEAN EXTREME DRY BULB TEMPERATURE FOR ASHRAE LOCATION MOST SIMILAR TO INSTALLATION LOCATION 3. ALTERNATE POWER SOURCE PLACARD SHALL BE PERMANENTLY ATTACHED TO A/C DISCONNECT. 4. ELECTRICAL INSTALL SHALL COMPLY WITH 2016 CALIFORNIA ELECTRICAL CODE (INCLUDING AN "ALTERNATE POWER SOURCE PLACARD") 5. ALL SOLAR MODULES, EQUIPMENT, AND METALLIC COMPONENTS SHALL BE BONDED 6. IF THE EXISTING MAIN SERVICE DOES NOT HAVE VERIFIABLE GROUNDING ELECTRODE, IT IS THE PV CONTRACTOR'S RESPONSIBILITY TO INSTALL A SUPPLEMENTAL GROUNDING - ELECTRODE 7. EACH MODULE SHALL BE GROUNDED PER MANUFACTURER INSTRUCTIONS AND APPROVED METHODS . ION'' 4801 N UNIVERSITY AVE, #900 PROVO, UT 84604 (888)781-7074 8. PV INSTALLATION SHALL NOT OBSTRUCT ANY. PLUMBING VENTS, MECHANICAL EQUIPMENT; MECHANICAL VENTS, OR BUILDING ROOF Q VENTS IN ACCORDANCE WITH CPC 901.1, CPCca u_ 906, AND CMC 304. � U W) U . � M 9.' CONNECTORS THAT ARE NOT READILY ACCESSIBLE AND THAT ARE USED IN THE ~' CIRCUITS OPERATING AT OR OVER 30V AC OR DC SHALL REQUIRE A TOOL FOR OPERATING AND ARE REQUIRED TO BE MARKED "DO NOT LICENSED ELECTRICAL CONTRACTOR DISCONNECT UNDER LOAD" OR "NOT FOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: CURRENT INTERRUPTING" CIO AV17100.12PD CONIRAC(OR: LICEN 027027 ER: I , 10. THIS SYSTEM IS IN FULL COMPLIANCE WITH EXPIRATION: 5/31/2019 I(�" THE CALIFORNIA FIRE CODE FOR SYSTEM SIZE: 5.88 kW DC PHOTOVOLTAIC INSTALLATION AND ARTICLE 5.00 kW AC - 690 OF THE NATIONAL ELECTRIC CODE (NEC DATE: 21 MODULES 11/24/2017 NFPA 70) . DRAWN BY: JPL 11. BUILDING CONSTRUCTION TYPE: TYPE V ADDITIONAL NOTES: 12. BUILDING OCCUPANCY TYPE: R3 ION 4801 N UNIVERSITY AVE, #900 PROVO, UT 84604 (888)781-7074 .. 4 _ MODULE CLAMP . PHOTOVOLTAIC MSI ALPHA+ RAIL kn MODULE a a¢ U L -FOOT _ m _ ECOFASTEN COMP SHINGLE MOUNT ' • . ~' FLASHING611 / / t r; • LICENSED ELECTRICAL CONTRACTOR r^ COMPANY: / ;f;;,y••`' y ION DEVELOPER LLC .(1)5/16 X 4 /•.:`} y✓ CLASSIFICATION: 11 It ..; yy C 10 nunwaizeomNrxncjrJ/o/n�r ��,,•�•" ' LICEN02 02NUMBER: '//Y;,'^v'-c'.,✓'_ / . " EXPIRATION: 18-8 SS LAG SCREW. 5,31/2019 V 2 1/2" MIN. EMBEDMENT : SYSTEM SIZE: 5.88 kW DC 5.00 kW AC 21 MODULES PLYWOOD DATE: 11/24/2017 �:... COMP DRAWN BY: JPL + SHINGLE ADDITIONAL NOTES: ROOF TILT(S): 19° TRUSS SHEET: MOUNTING PV 5.0 a -THIS PV SYSTEM WILL HAVE THE FOLLOWING MARKINGS: _ 1 —= MATERIALS USED FOR MARKINGS WILL BE WEATHER RESISTANT. THE UNDERWRITERS LABORATORIES MARKING -AND-LABELING SYSTEM 969 (UL969) WILL BE USED AS STANDARD TO DETERMINE WEATHER RATING. 2-- MARKING STATING "CAUTION: SOLAR ELECTRIC SYSTEM CONNECTED" WILL BE PLACED AT THE MAIN SERVICE DISCONNECT. 3 — MARKING STATING "WARNING: PHOTOVOLTAIC POWER SOURCE" WILL BE PLACED ALONG DIRECT CURRENT CONDUIT, RACEWAYS, ENCLOSURES, CABLE ASSEMBLIES, AND JUNCTION BOXES. 4 -- THE MARKING WILL•BE MADE TO THE FOLLOWING SPECIFICATIONS: • RED BACKGROUND - • WHITE LETTERING • MINIMUM 3/8" LETTER HEIGHT • ALL CAPITAL LETTERS • ARIAL OR SIMILAR FONT, NON—BOLD REFLECTIVE, WEATHER RESISTANT MATERIAL SUITABLE FOR THE ENVIRONMENT (DURABLE ADHESIVE MATERIALS MAY MEET THIS REQUIREMENT) 5 MARKING WILL BE PLACED ON ALL INTERIOR AND EXTERIOR CONDUIT, RACEWAYS, ENCLOSURES, CABLE r. ASSEMBLIES, AND JUNCTION BOXES -TO ALERT THE FIRE SERVICE TO AVOID CUTTING THEM. MARKINGS WILL BE , - '=. PLACED ON ALL EXTERIOR DC CONDUIT, RACEWAYS, ENCLOSURES, AND CABLE ASSEMBLIES EVERY 10 FEET, AT I TURNS AND ABOVE AND/OR BELOW PENETRATIONS AND ALL DC COMBINER AND JUNCTION BOXES. ION 4801 N UNIVERSITY AVE, #900. PROVO, UT 84604 - (888)781-7074 O, aU pU w m O U H U LICENSED ELECTRICAL CONTRACTOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: C 10 LICENSE NUMBERAMORIZEDCOWRACTO : I GLJ 1027027 EXPIRATION: 5/31/2019 SYSTEM SIZE: 5.88 kW DC 5.00 kW AC 21 MODULES DATE: 11/24/2017 DRAWN BY: JPL STEM MARKINGS PV 6.0 THIS PV SYS TEM. WILL'HAVE- THE FOLLOWING r PHOTOVOLTAIC DC DISCONNECT CEC 690.14 (C)(2) LOCATED ON THE DC DISCONNECT PORTION OF THE INVERTER (FOR STRING INVERTERS, NOT APPLICABLE TO MICRO -INVERTERS) PHOTOVOLTAIC AC DISCONNECT RAPID SHUTDOWN SWITCH CEC 690.14 (C)(2) LOCATED ON THE AC DISCONNECT PHOTOVOLTAIC SYSTEM EQUIPPED WITH RAPID SHUTDOWN MICRO -INVERTERS SERVE AS RAPID SHUTDOWN DEVICES AT MODULE LEVEL CEC 690.56 (B) & (C) LOCATED ON THE. AC DISCONNECT AND ALL JUNCTION BOXES AT ARRAY LEVEL - t ' PHOTOVOLTAIC SYSTEMS AC SYSTEM SPECIFICATIONS ` SYSTEM SIZE: KW COMBINED OPERATING RATING: AMPS RATED OUTPUT VOLTAGE: VAC CEC 690.17 & CEC 690.54 LOCATED ON MAIN SERVICE PANEL WARNING: DUAL POWER SOURCES THIS EQUIPMENT FED BY MULTIPLE SOURCES SECOND SOURCE IS PHOTOVOLTAIC SYSTEM RATED AC OUTPUT CURRENT AMPS AC NORMAL OPERATING VOLTAGE VOLTS CEC 690.54 & CEC 705.12(D)(7) M PLACE ON AIN SERVICE PANEL AND ON SOLAR PV COMBINER PANELBOARD PV SYSTEM AC DISCONNECT SECOND SOURCE IS PHOTOVOLTAIC SYSTEM RATED AC OUTPUT CURRENT AMPS AC NORMAL OPERATING VOLTAGE VOLTS CEC 690.54 PLACED NEXT TO THE SOLAR PV BREAKER AND ON AC DISCONNECT WARNING: PHOTOVOLTAIC POWER SOURCE CRC R331.2 PLACED ALONG DIRECT CURRENT CONDUIT, RACEWAYS, ENCLOSURES, CABLE ASSEMBLIES, AND JUNCTION BOXES MARKINGS: +ION 4801 N UNIVERSITY AVE, #900 PROVO, UT 84604 (888) 781-7074 CEC 690.17 & CEC 690.54 PLACED ON OR ADJACENT TO THE AC DISCONNECT AND nTQ!`nATATE7rTTAT(_ WAFANIQ (Qnl AR P\( RRAATCFR) WARNING: ELECTRIC SHOCK HAZARD GROUNDED CONDUCTORS MAY BECOME UNGROUNDED AND ENERGIZED IF A GROUND FAULT IS INDICATED CEC 690.5 (C) PLACED ON ALL INVERTERS AND JUNCTION BOXES, OR PLACED NEAR THE GROUND -FAULT INDICATOR AT A VISIBLE LOCATION WARNING: ELECTRIC SHOCK HAZARD MICRO -INVERTER PHOTOVOLTAIC SYSTEM DC CONDUCTORS OF PHOTOVOLTAIC SYSTEM ARE UNGROUNDED AND MAY BE ENERGIZED CEC 690.35 (F) - PLACED ON ALL INVERTERS, JUNCTION ` BOXES AND SOLAR PV COMBINER ' PANELBOARD ' WARNING: INVERTER OUTPUT CONNECTION DO NOT RELOCATE THIS OVERCURRENT, DEVICE CEC 705.12 (D)(7) PLACED NEXT TO THE SOLAR PV BREAKER ON THE MAIN SERVICE PANEL, AND ON THE SOLAR PV COMBINER PANELBOARD Q zW enrn aa4 aU pU W �o U �x I--1 in U z m ti LICENSED ELECTRICAL CONTRACTOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: C 10 ALMIO .EDCONTRAMn: LICENSE NUMBER: 1,,, /lL, 1027027 041 I f�, J'^/�� ExPIRAT1oN: 5/31R019 SYSTEM SIZE: 5.88 kW DC 5.00 kW AC 21 MODULES DATE: 11/24/2017 DRAWN BY: JPL _ - JRGL 1 SYSTEM MARKINGS PV 7.0 PV MODULE SPECIFICATIONS MODULE MAKE AND MODEL TRINA TSM-280DDOSA.08(II) MAXIMUM POWER (DC) 280 WATTS MAX POWER -POINT VOLTAGE (VMPP) 31.7 VOLTS MAX POWER -POINT CURRENT (IMPP) 8.84 AMPS OPEN CIRCUIT VOLTAGE (VOC) , 39 VOLTS • SHORT CIRCUIT CURRENT (ISC) 9.35 AMPS TEMPERATURE COEFFICIENT VOC -0.29 %/°C MAXIMUM SYSTEM VOLTAGE IOOOV DC (UL) THWN-2 OR MC CABLE (EGC) ;PV CIRCUIT 1: 21 MODULES/SERIES PV MODULE STRING -INVERTER SPECIFICATIONS INVERTER MAKE AND MODEL SOLAR EDGE SE5000H-US RATED OUTPUT POWER (AC) 5000 WATTS NOMINAL OUTPUT VOLTAGE (AC) . 240 VOLTS MAX OUTPUT CURRENT (AC) 21 AMPS MAX INPUT VOLTAGE (DC) .480. VOLTS MAX INPUT CURRENT (DC) 13.5 AMPS MAX OCPD RATING (AC) 30 AMPS MAX NUMBER OF PANELS PER STRING 20 THWN-2 OR MC CABLE (EGC) VISIBLE LOCKABLE "KNIFE" A/C SOLAREDGE POWER OPTIMIZER P320 SOLAREDGE INVERTER DISCONNECT 30A/240V - 100 A V 30 A JUNCTION BOX LOCATED ON ROOF A JB CONSUMPTION CT KITS WILL BE INSTALLED IN THE MAIN PANEL WHERE APPLICABLE CT WIRES WILL BE RAN IN EXISTING CONDUIT BACK TO ENVOY METER WHERE POSSIBLE, OTHERWISE NEW CONDUIT WILL BE INSTALLED FOR CT WIRES AC PHOTOVOLTAIC SYSTEM RATINGS MAX AC OPERATING CURRENT 21 AMPS MAX AC OPERATING VOLTAGE 240 VOLTS *ROMEX WILL BE RAN THROUGH THE ATTIC WHERE POSSIBLE ** IF MORE THAN 12 CONDUCTORS, TWO SEPARATE RACEWAYS MAY BE INSTALLED WITH NO MORE THAN 12 CONDUCTORS IN EACH RACEWAY OTHERWISE, #4 WIRE AND 3/4" CONDUIT MUST BE USED WHERE APPLICABLE LF— C C EXISTING 240V/225A BUSBAR RATED LOAD -CENTER (NON -CENTER FED) PANEL. BREAKER WILL BE FURTHEST POSITION AWAY FROM DISCONNECT. RACEWAY AND CONDUCTOR SCHEDULE TAG CONDUCTOR TYPE MINIMUM WIRE SIZE # OF CONDUCTORS RACEWAY / CABLE TYPE MINIMUM CONDUIT SIZE A PV CABLE 10 2 USE -2 / FREE AIR N/A BARE COPPER (EGC) 6 1 BARE / FREE AIR B THWN-2 OR MC CABLE 10 2 EMT / MC 3/4" THWN-2 OR MC CABLE (EGC) 10 1 C THWN-2 8 3 EMT 3/4" THWN-2 (EGC) 8 I ION 4801 N UNIVERSITY AVE, #900 PROVO, UT 84604 (888)781-7074 M V e LICENSED ELECTRICAL CONTRACTOR COMPANY: ION DEVELOPER LLC CLASSIFICATION: C 10 AVDIORIZED CONTRACTOR: LICENSE NUMBER: I 1027027tz el EXPIRATION: 5/312019 SYSTEM SIZE: 5.88 kW DC 5.00 kW AC 21 MODULES DATE: 11/24/2017 DRAWN BY: JPL 1 -LINE EL 1.0 0 1. THE ENPHASE M250, M215 METAL PARTS OF PV MODULE FRAMES, GROUNDING COMPONENTS OR UL -2703 ION (M215-60-2LL-SXX-IG), AND C250 FOURTH ELECTRICAL EQUIPMENT, AND LISTED MOUNTING HARDWARE. IN AN GENERATION MICROINVERTERS MEET THE CONDUCTOR ENCLOSURES SHALL BE ENPHASE MICROINVERTER SYSTEM, IF 4801 N UNIVERSITY AVE, #900 PROVO, UT 07404 REQUIREMENTS OF THE NATIONAL - PROVIDED WITH EQUIPMENT GROUNDING. THE MICROINVERTERS AND MODULES ELECTRICAL CODE ARTICLE 690.35 FOR 690.43(C) STRUCTURE AS EQUIPMENT ARE BONDED TO THE RACKING UNGROUNDED PHOTOVOLTAIC POWER GROUNDING CONDUCTOR ALLOWS FOR ASSEMBLIES WITH THE USE OF LISTED SYSTEMS. NEC 690.35 ALLOW_ S FOR EQUIPMENT TO BE USED AS THE AND APPROVED GROUNDING CLIPS OR Z PHOTOVOLTAIC POWER SYSTEMS TO BE EQUIPMENT GROUNDING CONDUCTOR IN GROUNDING COMPONENTS THE _ INSTALLED WITH UNGROUNDED A PHOTOVOLTAIC SYSTEM. SPECIFICALLY, EQUIPMENT GROUNDING CONDUCTOR R O on u PHOTOVOLTAIC SOURCE AND OUTPUT "DEVICES LISTED AND IDENTIFIED FOR PROVIDED TO THE MICROINVERTERSZ M " CIRCUITS. SYSTEMS THAT MEET THE GROUNDING THE METALLIC FRAMES OF THROUGH THE ENPHASE ENGAGE CABLE REQUIREMENTS OF NEC 690.35 ARE PV MODULES OR OTHER EQUIPMENT MAY ALSO BE USED TO GROUND THE - EXEMPT FROM THE SYSTEM GROUNDING SHALL BE PERMITTED TO BOND THE OTHER PHOTOVOLTAIC SYSTEM LICENSED ELECTRICAL CONTRACTOR - COMPANY: ION DEVELOPER LLC REQUIREMENTS OF NEC 690.41 SYSTEM EXPOSED METAL SURFACES OR OTHER COMPONENTS. CLASSIFICATION: ATION: LICENSE NUMBER; "trruoaveurn'nxncron: ENSE LIC27027 10TION Imo/ /IL /404� GROUNDING. EQUIPMENT TO MOUNTING, Il�//[]//�,W_ 5/31/2019 SYSTEM SIZE: 5.88 kW DC 2. - NEC ARTICLE 690.43 EQUIPMENT SURFACES." THE DEVICES LISTED AND 215.00kW AC oMODULES DATE: 11/24/2017 GROUNDING. SPECIFIES THAT ALL -IDENTIFIED FOR GROUNDING THE DRAWN BY: JPL EXPOSED NON—CURRENT—CARRYING EQUIPMENT MAY BE STAND—ALONE (SHEET: TRICAL NO EL 2.0 Photovoltaic Rooftop Solar System Permit Submittal Q Project Information: Project Name: Janice Weigand Project Address: 616 Woodward Ave, Orland, CA 95963 A. System Description: The system consists of a 5.88 kW DC roof -mounted Photovoltaic power system operating in parallel with the utility grid. There are (21) TRINA TSM-280DDOSA.08(II) modules and (1) SOLAR EDGE SE5000H-US string-inverter(s), connecting to the utility grid through a line -side tap. This system includes (0) PV string(s). B. Site Design Temperatures: From 2009 ASHRAE Handbook - Fundamentals (RED BLUFF MUNICIPAL ARPT WEATHER STATION) Record low temperature: -4 'C Average high temperature: 40'C C: Minimum Design Loads: (ASCE-7-10(7.2)) Ground snow load 0 psf Wind speed 110 mph Q Structural Review of PV Arraying Mounting System: (The array will be mounted on a defined, permitted roof structure) A. Roof Information: 1. Roofing type is Composite Shingle 2. Roof has a single roof covering 3. Method and type of weatherproofing roof penetrations: Comp Mount Flashings B. Mounting System Information: 1. Mounting system is an engineered product designed to mount PV modules 2. For manufactured mounting systems, following information applies: a. Mounting System Manufacturer: Mounting Systems Inc. (MSI) b. Product Name: MSI Traditional Rails c. Total weight of PV modules, Inverters, and rails: 1546.3 pounds d. Total number of attachment points: 28 e. Weight per attachment point: 55.23 pounds f. Maximum spacing between attachment points: ' See attached MSI engineer g. Total surface area of PV array: 370.64 square feet h. Array Pounds per square foot: 4.17 pounds per square foot i. Distributed weight of PV array on roof: Roof Section A: (21 Modules, 28 Attachment 55.23 Q Electrical Components: ' A. Module Quantity TRINA TSM-280DD05A.08(ii) (UL1703 listed) 21 attachment r Impp - rated current 8.84 amp Isc - short circuit current 9.35 amp B. Inverter (micro) Quantity SOLAR EDGE SE5000H-USr 4 (UL37411isted) 1 Inverter Specs 1. Input Data (DC) Recommended input power (DC) 0 watts Max. input DC voltate 480 volts Peak power tracking voltage 0 Min./Max. start voltage p Max. DC short circuit current 45 amp Max. input current 13.5 amp 2. Output Data (AC) Max. output power 5000 watts Nominal output current 21 amp Nominal voltage 240 volts Max. units per PV circuit 20 inverters Max. OCPD rating 30 amp C. System Configuration 1. Number of PV circuits Modules/Inverters in PV circuit 1 21 2. Circuit max overcurrent protection ampacity, Overcurrent protection PV circuit 1 30 amp (Noc x a of Panels in circuit x 1.25) D. Rooftoo Electrical Calculations ' 1. Max circuit current PV circuit nominal current 21 amp Continuous current 125% PV circuit continous current rating 26.3 amp 2. Max circuit overcurrent protection device rating PV circuit continous current rating 26.3 amp Next standard size fuze/breaker to protect conductors - 30 amp Conductor must be rated for a minimum of 30 amp after derating (2014 NEC Article 705.60(B)) . Use 30 Amp AC rated fuse or breaker 3. Rooftop conductor conditions of use (Ampacity derate) a. Temperature adder Average high temperature 40 °C Conduit is installed 1" above the roof surface +.22 °C to ambient Adjusted maximum temperature 1 62 °C (2014 NEC Table 330.15(B)(3)(c)) E 2. Circuit max overcurrent protection ampacity, Overcurrent protection PV circuit 1 30 amp (Noc x a of Panels in circuit x 1.25) D. Rooftoo Electrical Calculations ' 1. Max circuit current PV circuit nominal current 21 amp Continuous current 125% PV circuit continous current rating 26.3 amp 2. Max circuit overcurrent protection device rating PV circuit continous current rating 26.3 amp Next standard size fuze/breaker to protect conductors - 30 amp Conductor must be rated for a minimum of 30 amp after derating (2014 NEC Article 705.60(B)) . Use 30 Amp AC rated fuse or breaker 3. Rooftop conductor conditions of use (Ampacity derate) a. Temperature adder Average high temperature 40 °C Conduit is installed 1" above the roof surface +.22 °C to ambient Adjusted maximum temperature 1 62 °C (2014 NEC Table 330.15(B)(3)(c)) Derate factor for 62 °C 0.71 b. Ampacity adjustment for conduit fill Number of current -carrying conductors 16 conductors Conduit fill derate factor 0.45 c. Wire ampacity adjustment after derates THWN-2 (90°C) #4AWG conductor ampacity rating 95 amp 95 x 0.71 x 0.5 = Adjusted wire ampacity 33.725 amp (2014 NEC Table 310.15(B)(2)(a)) (2014 NEC Table 310.15(B)(3)(a)) (2014 NEC Table 310.15(B)(16)) THWN-2 (90"C) #4AWG Wire Max ampacity after derates 33.725 amp Max OCPD used for roof circuits 30 amp ' E. System Electrical Calculations 1. System current PV circuit nominal current 21 amp Continuous current 125% (2014 NEC Article 705.60(B)) PV circuit continous current rating 26.3 amp - " Exception: OCPD may increase when AHJ requires breakers in combiner panel added for the solar interconnection Conductor must be rated for a minimum of 30 amp 4 Use 30 amp AC rated fuse or breaker 3. System conductor conditions of use (Ampacity derate) a. Ampacity adjustment for new ambient temperature Average high temperature 40'C Derate factor for 40 "C 1.00 b. Ampacity adjustment for conduit fill Number of current -carrying conductors 2 conductors Conduit fill derate factor 1.00 c. Wire ampacity adjustment after derates THWN-2 (75-C) #10AWG conductor ampacity rating 30 amp 30 x 1 x 1= Adjusted wire ampacity 30 amp (2014 NEC Table 310.15(8)(2)(a)) (2014 NEC Table 310.15(B)(3)(a)) (2014 NEC Table 310.15(B)(16)) THWN-2 (75"C) #10AWG Wire Max ampacity after derates 30 amp Max OCPD used for interconnection 30 amp 4 F. Voltage Drop 2 parts: 11. Voltage drop across longest PV circuit micro -inverters (from modules to junction box) 2. Voltage drop across AC conductors (from junction box to point of interconnection) 1. Micro -inverter voltage drop: 0.48% The largest number of micro -inverters in a row in the entire array is 1 in Circuit 1 - According to manufacturer's specifications this equals a voltage drop of 0.48%. 2. AC conductor voltage drop: 1.12% = 1 x R x D (= 240 x 100 to convert to a percent) = (Nominal current of largest circuit) x (Resistance of #10AWG copper) x (Total wire run) =21x0.00129x100=240x100 Total system voltage drop: 1.6% G. AC point of interconnection Interconnection Method: LOAD -SIDE BREAKER S Load center busbar rating 200 amp' Load center main disconnect rating 200 amp Standard overcurrent protection for PV circuit(s) 30 amp 2014 NEC 705.12 (D) - The output of a utility -interactive inverter shall be permitted to be connected to the load side of the service disconnecting means of the other source(s) at any distribution equipment on the premises. (2) - The sum of the ampere ratings of overcurrent devices in circuits supplying power to a busbar or conductor shall not exceed 120 percent of the rating of the busbar or conductor. Main Panel ampacity Calculation 120% of the Existing busbar 240 amps — Existing load center main disconnect rating 200 amps = Available ampacity for PV circuits: 40 amps ° r 2014 NEC 705.12 (D)(7) - Unless the panel boards in rated not less than the sum of the ampere ratings of all over -current devices supplying it, a connection in a panelboard shall be positioned at the opposite (load) end from the input feeder location or main circuit location... A permanent warning label shall be applied to the distribution equipment with the following or equivalent wording: WARNING INVERTER OUTPUT CONNECTION. DO NOT RELOCATE THIS OVERCURRENT PROTECTION DEVICE E t T THE ALL-MAX'PLU'S" MODULE 1-s: 60 CELL•• MONOCRYSTALLINE- MODULE,•.- • ' .. .. .r ,.F POWER OUTPUT RANGE Vr,.f y- ••� �����• tit � .`.r •r 1 "MAX IMUM EFFICIENCY ri ` f; E • Y • ••tY••Yil�.5W •+ `r 0 a POSITIVE POWER TOLERANCE' . _ 1 _ .As o leading global manufacturer -,=.i of. next generation photovoltaic prodiicts,vre believe dose co6perotion with our'parfners a is critical to success With local -. . presence around the globe, Trina is. oble to provide exceptional service , to each customer in each market and supplement our innovative, ` reliable products vAh the backing , of Trina as a strong, bdnkable ¢ partner. We are committed to building strategic, mutually beneficial collaboration with installers, developers, distributors and other pdrtners'as the backbcne.of our shared success in driving Smdrt'Energy Together. 1 Trina Solar limited . www.trinasolor.com . �onesoar., Smart EnergyTogether Maximize limited space with sop -end efficiency Up to 177 W/mz power density • Low thermal coefficients for greater energy production at.. high operating temperatures Highly reliable due to stringent quality con-pol' • Over 30 in-house fes -.-s (UV, TC, K__'.and many morel. • In-house testing goe: well beyond certfication requirements Certified,to withstand challe"ging, environmental conditions • 2400 Pa wind load • 5400 Pa snow load • 35 mm hail stones at 27 kmlh y LINEAR PERFORMANCE WARRANTY 10 Year Product Warranty • 25 Year linear 'ower Warrarity 3100% Add a Onol value f u °m'Jrina Solar's Ilrecr N ci rrcplty Years 5 t0 15 20 25 © Trinastandard ard THE ALWAX pus' MODULE PRODUCTS}F 1 POWER RANGE . ELECTRICAL DATA (STC) TSM.DDOSA 08(II)p 275 290W ', , r - Peak Power Watts-Pm, x (Wp) I 270 ' 275 i 280 ' 285 290 TSM DDOSA OS(fi) s 270 275W'" •T Power Output Tolerance-PA Ax (W) ; .. . .' •? s;; x �a , z yTq 4 Maximum Power Voltage-Vnw 2 :a 31.4' 31.8 32.2 « DIMENSIONSOF,PV'MODULE' Maximum Power Current-I PP (A) 8 66 8.76 8:84 8.97 • < ':, 96 wa unit'mm%Ih �• ala 4�v 9at/37o,s /* 3^: E. *i, ,t i Open Circuit Volta a-Vac V M g O 1 38 4 38 7 T "" 39.0 39.3 39.5 j # s Short Circuit Current-Isc (A) 918 9 26 9.35 T 9.45. ; , 9.50 y ii_ . 941 • ) , yt v, Module Efficiency qm (�1 . I 16.5 16.8 17.1 - 17:4 o r - - STC: Irradiance 1000 W/m'. Cell Temperature 25°C. Air Nass AMI.5. :'. WAWNG HOLE ; , � 1 _ ,{ �. NAMEPLATE • C Lo �` ELECTRICAL DATA (NOCT) a x l r Maximum Power-P- (WO) - r 0 .t - 201 205 209J .r vM212; 216 t� tE..- _ r: - Maximum Power Voltage-VMPP (VJ 28.9 i 29.2 29.4si = 29.6 - - 29.9 L JA `t JF�# s/ r fo ;sy Maximum Power Curlent-IMrrIAl 6.96 702-•� `7.10 7.17 a 7.23 +1 k 1 t / t e ® r ( o - e t Open Circuit voltage-Vac (V) 35 7 36 0 36 3 36.6 .36.7 `' pt 4,4 Short Circuit Current-Isc (A) I 7.41 o 7 48 _) 7.55_ :' •� 7.63 t t t 7.67 - 3°'�' * • } -h NOCT: Irradiance at 800 W/m', Ambient Temperature 20"C, Wind Speed I m/s. MECHANICAL DATA Eau GROUNDDIG HOLE Solar cells 4 '7' "' '. = Monocrystolline 156 x 156 mm (6 inches) i 13-DRWHOLE Cell orientation , 60 cells (6 x 10) a - "Module dimensions 1650 x 992 x 35 mrr (6S.0 x'39.1 x 1.4 inches) °,r .Li' - �. - •taD/zt' Weight - 4 : 9 18.6 kg (41 Ib) 992/39.1 _ - . • ` - ' • - •. - • , s BACK VIEW • "Glass • ' r t,3.2 mm (0.13 inches).",High Transmission, AR Coated Tempered Glass Backsheet. ' White DD05A.08 (1t); Black (DDOSA.05 (II) r. n/o.63 Frame ., W Black (DD05.08 (1I), )5A.05 (II))�' [J-Box _ "' .; r•. `e IP65 or I1`67 rated ' ° ^ �- T Cables . Photovoltaic Technology cable 4:0mm' 0.006 inches' . •� I tiY Ski- a s. !_ •ri,_-I 'j1000rnm (39.4 inches) ( ) rmn,a r• i Connector'" UTX Amphenol 35/1.38 Fire Type Type 1 or 2 - , - • • � �.. „ . -_-----.,. «.., �_,,,.. � " - ' TEMPERATURE RATINGS MAXIMUM RATINGS I-V CURVES OF PV MODULE(285W): Nominal Operating Cell . 44°C(t 2°C) Operational Temperature-40-+85°C - Temperature (NOCT) 0'00 Temperature Coefficient of PMAx 0.39%/°C Maximurn System Voltage a000V DC (IEC) ° ew - ---• _ ;:1000V DC (UL) Temperature Coefficient of Voc 0.29%/°C Max Series Fuse Rating ISA zoo-.__._--___ -__ Temperature Coefficient of Isc ' O.O5T/P-7) d a.o° aro `.-_-.-._------------- --- WARRANTY i zoo ` 10 year Product Workmanship Warranty ,u --- -� ---' - - 25 year Linear Power warranty r. ' 30 ' ao eo I vw,wfvl IPleose refer to product worronty for details) CERTIFICATION i D iIL Its ;`, `) PACKAGING CONFIGURATION UMD Modules per box: 30 pieces l PV CYtI E t., L ) Modules per 40' container: 840 pieces E"BWEEE COMVIIAM - ��'ilt-asolar CAUTION: READ SAFETY AND INSTALLATION INSTRUCTIONS BEFORE USING THE PRODUCT. ® 2016 Trino Solar Limited. All rights reserved. Specifications included in this dotosheet are subject to change without notice. Smart Energy Together Sv,\s%te El m S.\N\- ce" . t in �Ly, \,Svs"tk-,l mounting systems Alpha' System Bonding Background Mounting Systems, Inc. manufactures the Alpha' ("Alpha plus") PV mounting system. In recent years the issue of PV system bonding and grounding. has received increased attention in North America from standards issuing bodies such as Underwriters .Laboratories NO, the National Fire Protection Association (NFPA) .through the National Electrical Code (NEC) and various Authorities Having Jurisdiction (AHJ). After issuing Standard 1703 which, among other things, requires and tests for suitable connection of PV module frames to ground, UL has focused on the electrical bonding of the framework which supports the PV modules. This bonding includes electrically bonding the module frames to the support structure and the bonding of the Various components of the racking structure to each other to form a single, continuously electrically bonded structure which can then- be connected to the system. grounding electrode. Module bonding Lay -in lugs Because most PV mounting systems are constructed of mill -finish aluminum while most PV module frames. are anodized, the task of connecting the aluminum frame of :the module to the mounting system has traditionally been cumbersome and expensive. The, anodized layer on the module frame is essentially non-conductive and forms an insulating barrier between the :frame and other elements of the mounting system. The nearly universally accepted method of connecting or bonding the module frame to the mounting system is via use of lay -in lugs (Figure 1) certified to UL' Standard 467 as being suitable for system bonding and grounding as specified in the NEC. These lugs are readily available from various vendors. C .' Figure la. Typical lay in lug Figure lb. Lay in lug installation Figure 1. Typical lay -in grounding lug mounting systems The lugs are secured to the module frame .as shown in Figure lb. The serrated or star=washers pierce the anodized coating on the module and make contact with the conductive aluminum frame. A suitably sized copper wire is then inserted and fastened in the lug and connected to the system grounding point. Lay -in lugs, are expensive to purchase and time-consuming to install. Mounting Systems, Inca has developed. instead, an integral bonding system which eliminates the need for lay -in lugs and other third -party devices. Alpha' Clickstone bonding The Alpha' Clickstone PV mounting system provides an integrated bonding system comprised of specially designed clamp bodies, rail latching and threaded connections'. There are two versions of the Alpha' clamp bodies. Pre -production and early -production versions of the -Alpha' bonding clamp employ stainless steel, cone point set screws (Figure 2) mounted in the clamp body. After the clamp is secured on the modules, the set screws are tightened so that the points on the set screws pierce the anodized module coating and bond the module frame to the clamp body through the set screw threads'. Set screw locations PA Cone point set screws Figure 2. Early production version clamp body with set screws Standard production versions of the bonding clamp use a proprietary, stainless steel bonding . plate (Figure 3) preassembled on the Clickstone. The bonding plate is formed . with angled bonding teeth at each end. rigure 3. ounuing plate ' Per UL Subject 2703 Ed.2, Section 9.4, two or more threads in contact with the threaded. body constitutes an acceptable electrical bond. u mounting systems The plate is preassembled to the Alpha' clamp below the clamp body as shown in Figure 4. When the 'clamp is tightened into place on themodule frame the teeth pierce both the anodized 'coating'on the module and the oxide or anodized coating 'on the clamp body, thus forming an electrical path between the module•frame and the clamp body: An external -tooth star washer' between the Clickstone bolt head and the clamp body serves to electrically bond the clamp body, bonding plate and module to the Clickstone bolt which threads into the actual Clickstone,itself. Clamp body 2 Bonding plate 3 Clickstone bolt Figure 4a. Bonding plate assembled to bolt Figure 4b. Clickstone bolt assembly The Clickstone (Figure 5) anchors the module and clamp to. the Alpha' rail and plays an integral role in the system bonding. As shown in Figure 5, specially designed, sharp ridges on the latching mechanism of the Clickstone engage complementary, sharp ridges in the rail channel. As the clamp bolt is tightened, the latching teeth engage the rail channel ridges, crushing or piercing the oxide or anodized layers on each component to the base aluminum. This creates a solid, high-ampacity electrical connection. As the bolt is tightened to the recommended torque setting specified in the Alpha' Installation -'Manual (15 ft -lbs 1 20 N -m), the complementary shapes of the Clickstone and rail channel .form a seal, preventing further oxidation and ensuring a reliable electrical bond between the modules, clamp components and the rail. TL Bonding ridges r - Figure 5. Clickstone and rail ' Per UL Subject 2703 Ed.2, Section 9.4. A bolted, screwed or riveted connection that incorporates a star washer under the head of the fastener, a serrated screw head, or a bonding device between surfaces may be acceptable for penetrating nonconductive coatings. Figure 6. Alpha' bonding path • , f Rail=to-Rail Bonding It is often the case that module mounting rails are spliced together to form` a longer, length of rail. The Mounting Systems Alpha` system uses a dedicated rail splice (Figure 7) for this purpose. Rail•splice d 74 v ' • ry{ 1 � �Id .y Lq'�Y 1�3�?'•'� r Splice shown connected to'one rail only Figure 7. Alpha* rail splice 14 Figure 6. Alpha' bonding path • , f Rail=to-Rail Bonding It is often the case that module mounting rails are spliced together to form` a longer, length of rail. The Mounting Systems Alpha` system uses a dedicated rail splice (Figure 7) for this purpose. Rail•splice d 74 v ' • ry{ 1 � �Id .y Lq'�Y 1�3�?'•'� r Splice shown connected to'one rail only Figure 7. Alpha* rail splice �Dovcft mounting systems The Alpha' splice, is comprised of the aluminum splice body, stainless steel bolts, stainless steel square nuts and stainless steel, external -tooth star washers as shown in Figure 8. 0 When the rails to be connected are inserted into the splice and the bolts are tightened to the torque recommendation in the Alpha' Installation Manual, the bolts pierce the oxide or anodized layer on the rails and create an electrical bonding path to the bolts. These bolts then connect through the square nut threads, to the star -washers and then to the splice body, thus providing a conductive path through the body of the splice and electrically bonding the entire assembly as shown by the green line in Figure 8. No additional, external bonding devices are required. Rail -Roof attachment bonding Alpha' 'ails are connected to the roof attachments (L -feet or various the roof hooks) by means of stainless steel hammer -head bolts and serrated nuts as shown in Figure 9. When properly tightened, the pressure on the bolt head is sufficient to break through the oxide or anodizing on the rail and form an electrical connection from the rail, through the bolt shaft to the serrated nut and then to the roof attachment device. 1-1O11TG Q 41nhn, rail -_..__4_ �nountang systems System grounding The combination of the Alpha' Clickstone clamp assembly, rail splices and roof attachment, devices provides a completely bonded PV structure. Grounding this bonded structure may be accomplished using approved lay -in lugs or other devices. Mounting Systems, Inc. recommends the use of Burndy WEEB-Lugs specifically intended for use on Alpha' rails. These. pre.assembled lugs are available from Mounting Systems (Part Number•720-1235 [set of 4]). The WEEB-lug can. . be installed in any of the three channels in the Alpha' rail. A UL listed bonding.washer on the . lug bonds the lug to the Alpha' rail. A suitably sized conductor can then be connected to. the., WEEB-Lug for connection to the system ground electrode. UL Subject 2703 Ed. 2 Compliance By virtue of the bonding methods described above, the Mounting Systems, Inc.Alpha+ PV mounting system is fully compliant with UL Subject 2703 Ed. 23. Extensive testing on key bonding components of the Alpha' system has been performed. Testing Was carried out in excess of and under more rigorous conditions than required by UL Subject 2703 Ed. 2 as it is presently written. The system meets or exceeds all pertinent requirements. When .assemblecl.and .installed per the instructions provided in the Mounting. Systems, Inc. Alpha' Installation Manual and/or with appropriate use of third party devices in compliance with instructions in their respective installation manuals or instructions, the Mounting Systems, Inc. Alpha' system :will be fully and securely bonded electrically and can be grounded by approved methods. Mounting Systems, Inc. 820 Riverside Parkway West Sacramento, CA 95605 Phone 1 855 731 9996 info-us@mounting-systems.com www.mounting-systerns.us Subject to change without notice 2014©Mounting Systems, Inc. 3 Note that UL Subject 2703 was rejected by vote of the UL Subject 2703 Standards Technical Panel in September 2012 and returned to the author(s) for revision and re -submittal to the STP. UL Subject 2703 Ed. 2 has not, as of this writing, been accepted by the STP. It has not been approved nor does it have standing as an accepted standard. mounting systems . -- l Alpha.+ } The Alpha+ system is a robust mounting system designed and optimized for exceptionally fast and easy installation of PV modules on pitched roofs. Mounting l E Systems' patented Clickstone technology and extensive component pre-assembly r c speed installation and enhance system safety and reliability. • o Unlimited flexibility With the Alpha+, framed and frameless modules can be easily mounted on a wide Q-6 I R range of. pitched roof surfaces.' Systems can be designed in both landscape and C. portrait orientations for optimal system performance. Multiple rail offerings meet a' i a the demands of each projects decrease roof penetrations. Significant savings 41pha+ has been specifically designed to minimize installation times. Labor is iecreased by click, set and done Clickstone technology on all module clamps. a' Shared rail configurations can drastically increase savings by reducing roof penetrations and material use. Fully integrated, ETL listed UL 2703, Ed.1 system bonding eliminates third-party components and further speeds installation. .... Aesthetically Pleasing The Alpha+'s improved design provides vertical adjustability to'help compensate ` for roof irregularities and to make leveling the PV array easier. Black painted rails 1• as well as an optional wind skirt are also available for enhanced aesthetic appeal. r Mounting Systems' Flashmount provides discrete and watertight connection to the , roof. structure. Structural reliability •r Using Mounting Systems' Alpha+ QuickConfigurator software, the Bill of Materials (EOM) for any specific configuration can be calculated in minutes along with a PE-stamped, project-specific structural analysis and verification to the appropriate - s building codes and national standards. Alph+ is fully compliant with the most F stringent North American fire codes. Alph+ is ET listed as a Class A Fire Rated system with Type 1 and 2 modules. Maximum service life k eli^USA. _ a c All components are made of extruded aluminum and stainless steel. This CO a � �.. a t,.. �. guarantees both full recyclability and maximum service life due to high resistance 6) ,. v to corrosion. i0 '!!I tY - Ana 1 Alpha+ is compatible with nearly every type of roof. For detailed information, please contact us during tie planning phase. . mounting ; systems Application Pitched roof - on•roof Roof types - Suitable for most typesof' r roof cladding Roof slope Up to 60 t r`F -Building height't' YUp to 65 ft • 10 m - PV modules Hamed of frameless Module orientation Landscape, portrait v Size of module array . Any size possible 2 } '•'` U1 V Clickstone clamp installation oPosition. of the module array~ ^ No special requirements E Distance•betiveen roof .p ' • Up to 10i / 3 m . attachment points Standards% ' -IBC2009 o .,. IBC 2012 t " CLs. ASCE 7-05 ASCE/SEI7-10 f� CL Q , . CBC 2013 r i UL 2703,•Ed.;1 Integrated bonding Clickstone mid-clamp ULC ORD C1703 ANSI/RISC 360-05 7AC1318y08 + Aluminum Deslgn Manual 2010, YFa' ` Eurocode T DIN.EN 191'1=1 .Actions on structures ,` 'L,• - - -- Eurocode"9 Design of-aluminumstiu�tures` - .. .- �. Splice Supporting profiles Extruded, Aluminum (EN AW. 6063 f66) Nooks, small parts Stainless steel (V2A) color Mill finish or black paint Vllarianty 10 years r e - } r Universal roof hook with QuickAttach 0 ..........:.:....................................:................................... ........ - a r L • n a, CETA US Intertek 1 Different maximum values may apply, depending on site, building, choice of roof attachments and module type. _ 2 The Mounting Systems QuickConfiguratoi can be used to verify the structural adequacy of each specific project For further information: www.mounting-systems.us - quickly and easily. Subject to change without notice - 3 For details, please consult Mounting Systems, Inc. full warranty document, available upon request. 2016 0 Mounting Systems, Inc. IN GreenFasten'" GF1 - Product Guide Installation Instructions with Compression Bracket Consult an engineer or go to www.ecofastensolar.com for engineering data. �' - 415 4c 1. Locate the rafters and snap horizontal and vertical lines to mark the installation position for each GreenFasten flashing. 2. Drill a pilot hole (1 /4" diameter) for the lag bolt. Backfill with sealant. EcoFasten Solar recommends an EPDM mastic. 3. Insert the flashing so the top part is under the next row of shingles and pushed far enough up slope to prevent water infiltration through vertical joint in shingles. The leading edge of flashing must butt against upper row of nails to prevent turning when tourqued. See page 2.2 for vertical adjustment when leading edge of flashing hits nails in upper shingle courses. 4. Line up pilot hole with GreenFasten flashing hole. 4a Insert the lag bolt through the EPDM washer, the top compression component bracket (L-102-3, Rock—It SlideComp*, SCL-101-3*, Z-101*, Conduit Mount Bracket*) and the gasketed hole in the fl ashing and into the rafter. 4b Insert the lag bolt through the EPDM washer, the Comp Mount Slide compression bracket and the gasketed hole in the flashing and into the rafter. k Insert the lag bolt through the SS washer, the third -party bracket, the EPDM . bonded washer, the CP -SQ -Slotted compression bracket and the gasketed hole in the flashing and into the rafter. S. Torque: The range is between 100-140 torque inch -pounds depending on the type of wood and time of year. The visual indicator for proper torque is when the EPDM on the underside of the bonded washer begins to push out the sides as the washer compresses. If using an impact wrench to install the fasteners be careful not to over torque the fastener. You may need to stop and use a ratchet to finish the install. *not pictured. 877-859-3947 EcoFasten Solar® All content protected under coovOaht. All rights reserved. 8/27/14 GreenFasten`" GF1 — Product Guide Installation Instructions * Use for vertical adjustment when leading edge of flashing hits nails in upper shingle courses . Slide flashing up under shingles until leading edge engages nails. Measure remaining distance to ad - i. —l— shingle 3. Reinstall flashing with notched area upslope. shingle 877-859-3947 EcoFasten Solar®AII content protected under copyright. All rights reserved. 8/27/14 2. Remove flashing and cut "W notch at marks where nail shafts engaged leading edge of flashing the distance desired in Step 1. Notch depth not to exceed 2" length by 1/2" width. "V" notch 4. Position notched leading edge underneath nail heads as shown. shingle Gree'nFasten`" GF1 —'Product Guide - Cut'Sheets..Bracket Options - 7-i ni• . 3l 2 4X R l /8" 5/ 16' 1`1/2" , 7 0 3/8"±.002 THRU'ALL 1 , , \^0, 7/8"±.010 •X 820, NEAR SIDE I • I I I I I. • 3/4'.. • I I 3/4" . 877-859-3947 EcoFasten solar°All content protected under copyright. All rights reserved. 8/27/1 a ase'... TECHNICAL BRIE L..JE N E R..G Y NEC 2014 Enphase System, Code Compliance Overview This technical brief discusses new NEC 2014 requirements that apply to Enphase Microinverter Systems. It useful for installers, electricians, and electrical inspectors or authorities having jurisdiction (AHJs) in understanding how code -compliance is handled where NEC 2014 is adopted. Main topics discussed in this document are: NEC 2014 Section 690.12 Rapid Shutdown of PV Systems on Buildings • ' . NEC 2014 Section 705.12 Point of Connection NEC 2014 Section 690.11 DC Arc -Fault Circuit Protection NEC 2014 Section 69.0. 12 ROW Shutdown, of PV Systems on Buildings Enphase Microinverter Systems fully meet the rapid shutdown requirement without the need to install additional electrical equipment. Properly labeling the PV system power source and rapid shutdown ability is required per NEC Section 690.56 (B) and (C): Solar electric PV systems with Enphase Microinverters have one utility -interactive inverter directly underneath each solar module, converting low voltage DC to utility grid -compliant AC. When the utility grid is available and the sun is shining, each microinverter verifies that the utility grid is.operating. within the IEEE 1547 requirements. Only then does it export AC power into the electric service for use by loads onsite or export power to the utility grid for others to use. When the utility grid has a failure, or the PV. system AC circuits are disconnected from the utility service via an•AC breaker; AC disconnect, or removal of the solar or main utility service meter, the microinverters stop producing AC power in fewer than six AC cycles. Enphase Microinverters are not.capable of operating as an AC voltage source. This means that Without an AC utility source,. Enphase Microinverters are not able to energize connected wiring and no AC voltage or current can be injected into the inverter output circuits or the grid. When the AC utility source is removed from the. inverter output circuits via any means, such as an AC breaker, AC disconnect or removal. of the solar or main utility service meter, this equipment performs the rapid shutdown function per 690.12. With an Enphase Microinverter System this shutdown occurs well within the 690.12 required 10 seconds, and there are no. other conductors energized more than 1.5 m (5 ft) in length inside a building or. more than 3 m (10 ft) from a PV array: Code Reference 690.12 Rapid Shutdown of PV Systems on Buildings. PV system circuits installed on or in .. buildings shall include a rapid shutdown function that controls specific conductors in accordance with 690.12(1) through (5) as follows. (1) Requirements for controlled conductors shall apply only to PV system conductors of more than 1.5 m (5 ft) in length inside a building, or more than 3 m (10 ft) from a PV array. (2) Controlled conductors shall be limited to not more than 30 volts and 240 volt-amperes within 10 seconds of rapid shutdown initiation. (3) Voltage and power shall be measured between any two conductors and between any conductor and ground. (4) The rapid shutdown initiation methods shall be labeled in accordance with 690.56(6). (5) Equipment that performs the rapid shutdown shall be listed and identified. 1 © 2015 Enphase Energy Inc. All rights reserved. January 2015 NEC 2014 —Enphase System Code Compliance NEC 2014 Section 705.12 Punt of C®n61ieC 0®n (AC Arc -Fault Protection) In this section we explain how to comply with NEC 2014 Section 705.12 Point of Connection when installing Enphase Energy Systems with: • Supply Side Connection Load -Side Connection to Single -Phase 120/240 Volt Services r Three -Phase 208/120 Volt Services Supply Side Connection Solution: No AC AFCI (Arc -Fault Circuit Interrupter) protection is required. Code Reference 705:12 Point of Connection The output of an interconnected electric power source shall be connected as specified in 705.12(A), (B), (C) or (D). Since the operator "OR" is used to define connection types, the code seems to intend that if one criteria is met, for example (A), the other criteria are not.applicable. Code Reference 705.12(A) Supply Side. An electric power production source shall be permitted to be connected to the supply side of the service disconnecting means as permitted in 230.82(6). The sum of the ratings of all overcurrent devices connected to power production sources shall not exceed the rating of the service. .705.12(6) Integrated Electrical Systems.... 705.12(C) Greater Than 100 kW.... 705.12(D) Utility -Interactive Inverters.... 230.82(6) lists solar photovoltaic systems as eligible for equipment permitted to be connected to the supply side of the service disconnecting means. Since Enphase Energy Systems are solar photovoltaic systems; a supply side connection of an Enphase System may be accepted by AHJs to fully meet Code section 705.12. Since 705.12(A) requirements are met, it seems logical that the 705.12(D) requirements for connections to the load -side of the service disconnect means are not applicable. Load -Slide Connection to Single -'Phase 120/240 Volt Serrices Solution: Refer to section 90.4 and the previous code edition, NEC 2011. No listed backfeed capable AC AFCI solutions or acceptable equipment to enclose the cable harness exist. Until such products are generally available from manufacturers, when making load side connections, complying with NEC 2014 Section 705.12 (D) (6) is achieved by discretionary guidance per NEC 2014 Section 90.4. This means to refer to the previous code edition NEC 2011 Section 705.12; where AC Arc -Fault Circuit Protection is not a requirement for utility -interactive inverters. NEC 2014 Code Reference 705.12(D) Utility Interactive Inverters. The output of a utility -interactive inverter shall be . permitted to be connected to the load side of the service disconnecting means of the other source(s) at any distribution equipment on the premises. Where distribution equipment, including switchgear, switchboards, or panelboards, is fed simultaneously by a primary source(s) of electricity and one or more utility -interactive inverters, and where this distribution equipment is ` 2 © 2015 Enphase Energy Inc. All rights reserved. January 2015 NEC201 e _ . 4 Enphas System Code Compliance capable of supplying multiple branch circuits or feeders, or both, the interconnecting provisions for the utility -interactive inverter(s) shall comply with 705.12(D)(1) through (D)(6). 705.12 (D) (4) Suitable for Backfeed. Circuit breakers, if backfed, shall be suitable for such . operation. 705.12(D)(6) Wire Harness and Exposed Cable Arc -Fault Protection:.A utility -interactive inverter(s) that has.a wire harness or cable output circuit rated 240 V, 30 amperes, or less, that is' - not installed s'notinstalled within an enclosed raceway, shall be provided with listed ac AFCI protection.:. . This NEC 2014 code section allows connection of an electric power source to.the load side of, service disconnect means and requires that the ".interconnecting provisions for the utility -interactive Interactive inverter s 4. 9 P tY-� O ... shall comply with 705.12(D)(1) through (D)(6)"..Since the Enphase system contains one or more microinverters, which are the utility -interactive inverter(s), this section applies when connecting a system. . to the load side of a service disconnecting means. 705.12(D)(6) specifically requires that exposed AC - cable systems, such as the Enphase Engage Cable, which is not feasibly run in enclosed raceway,.to be protected by listed AC Arc -Fault Circuit Interrupter (AC AFCI) functionality. Given that utility interactive inverters cannot operate without a utility service source, the location of the AC AFCI protecting the cable rnust_logically be applied at the utility source side of the circuit. AC AFCI circuit breakers are the commonly available devices for single-phase branch circuits. No suitable for backfeed AC AFCI circuit breakers exist. Since Enphase Microinverters are, utility -interactive inverters that backfeed into the electrical service through the overcurrent protection device, any AC AFCI circuit breakers must be specifically backfeed, capable, per 705.12(D)(4). If terminals of circuit breaker AFCls are marked "Line" and "Load," then the AFCI product isnot backfeed capable. No UL standard for backfeed testinq exists for AC AFCI circuit breakers. . Furthermore, 705.12(D)(6) requires that ac AFCI protection must be "listed." For a product or product category to become "listed;" a standard safety test procedure, such as a UL standard, must exist. The testing standard for AFCI circuit breakers is UL1699, which currently does not have provisions.for testing this product category for backfeed applications. It is clear, that the code requirement is ahead of new product availability. Summary Until suitable for backfeed and listed AC AFCI circuit breakers become generally available, an AHJ is permitted 'to refer to 90.4; i.e., the previous code edition, NEC 2011. Code Reference 90.4 Enforcement. This Code may require new products, constructions, or materials that may not yet be available at the time the Code is adopted. In such event, the authority having jurisdiction may permit the use of the products, constructions, or materials that comply with the most recent previous edition of this Code adopted by the jurisdiction. 3 © 2015 Enphase Energy Inc. All rights reserved. January 2015 NEC 2014 — Enphase System Code Compliance Three'Ph.ase 208/120 Volt Services Solution: The -compliance solution for systems interconnected to three-phase systems is to defer to NEC 90.4. There are no three-phase AC AFCI detection devices in existence. Until backfeed capable three- phase AC. AFCI circuit breakers become generally available, an AHJ is permitted to refer to 90.4, i.e., the previous code edition, NEC 2011. Additionally, the NEC 210.12 code intention for any AC AFCI protection is for single-phase applications in dwellings or dormitory units and not meant for three-phase applications, example:, Code Reference 210A2 Arc -Fault Ciircuit-Interrupter Protection:... . 210.12(A) Dwelling Units. All 120 -volt, single-phase, 15- and 207 -ampere branch circuits....:. 210:12(B) Branch Circuit Extensions or Modifications = Dwelling Units:..: . 210.12(C) DorinitoryUnits. All 120 -volt, single-phase, 15- and 20 -ampere branch circuits Although Chapter 7 applies to "Special Conditions," the industry must be able to supply generally -available equipment that is safe to use and meets the requirements for these special applications. For 705.12(D) (6) this. is not the case for three-phase applications as there are no listed three-phase AC AFCI detection devices available. NEC 2014 Section 690.11 ®C AIrc6Fau It Cir' uft Plr®4ectk®n This requirement is for direct current (DC) Arc -Fault Circuit protection and only applies to systems with DC voltages above 80 VDC. Enphase Microinverter systems are exempted from this requirement as they always operate well below 80 VDC. The requirement is basically unchanged from the NEC 2011, and it is unnecessary to add DC AFCI to an Enphase Microinverter System installation. Code Reference 690.11 Arc -Fault Circuit Protection (Direct Current). Photovoltaic systems with do source circuits, do output circuits, or both, operating at a PV system maximum system voltage,of 80 volts or greater, shall be protected by a listed (dc) arc -fault circuit internipter, PV type, or other system components listed to provide equivalent protection. 4 © 2015 Enphase Energy Inc. All rights reserved. January 2015 May 15, 2017 Mounting Systems; Inc.. 820 Riverside Pkwy Sacramento, California 95606 TEL: (855) 731-9996 Attn.: Mounting Systems, Inc. - Engineering Department Re: Engineering Certification for the Mounting Systems, Inc. 13/52 Rail Alpha+ System _Project No.: 2014-07680 PZSE, Inc. -Structural Engineers has reviewed Mounting Systems, Inc.'s 13/52 rail span charts, rail allowable uplift Wind force and performed rail component capacity check including L foot bracket, end clamp and mid -clamp. All information, data and analysis contained within the Mounting Systems, Inc. rail span charts are based on, and comply with Mounting Systems, Inc.'s Alpha Engineering and Technical Data and the following codes: 1. Minimum Design Loads for Buildings and other. Structures, ASCE/SEI 7-10 2. 2015 International Building Code, by International Code Council, Inc. 3. 2016 California Building Code, by California Building Standards Commission 4. 2015 Aluminum Design Manual, by The Aluminum Association 5. AC428, Acceptance Criteria for Modular Framing Systems Used to Support Photovoltaic (PV) Panels, November 1, 2012 by ICC -ES Following are typical specifications for the connections to meetthe above code requirements: Attachment Spacing: Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum span indicated on the charts. Cantilever: Maximum cantilever length is L/3, where "L" is the span noted in the Span Chart Tables Clearance: 2" to 10" clear from top of roof to bottom of PV panel This letter is to certify the structural capacity of the Mounting Systems Inc.'s rail. The requirements of the overall structure need to be in compliance with the above document and codes. If you have any questions on the above, do not hesitate to call. p,RoFEssiovgt . SEN E TN Prepared by: m LL, M PZSE, Inc.—Structural Engineers No.S3878 A Roseville, CA - Exp. 3-31-19 S�RUCTUR PgTF OF CAL���Q 8150 Sierra College Boulevard, Suite 150, Roseville, CA 95661 T 916.961.3960 F 916.961.3965 W www.pzse.com 1 of 5 a. The table above ONLY includes 13-52 rail capacity check. It does not include roof attachment or roof capacity check b. Wind risk category II per ASCE7-30 C. Topographic factor, kzt is 1.0 d.' Maximum mean roof height is 60 ft. e. Average parapet height is 0 ft f. Roof pitch is between 7 degree and 27 degree g. Maximum solar panel weight is 60 lbs h. Height of solar panel is between 2'.--' and.10" to roof L Deflection criteria of L/60 per AC428 Section 4.3 j. The wind speeds above are LRFD values k. Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum span indicated on the chart I. The span length applies to a seismic design category E or less M. Maximum cantilever is L/3 2 of 5 13/52 Rail Zone 1 Span Chart Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf, 70 psf 80 psf 90 psf ~ -„ 7.0'' ' 6.0 - 5.0 r, 55 - 4.5 -4.0-• z -4.0.--- 3.5 y' R• � N s , 105 10.0 8.5 - 7.0 3' 6.0 ' • 5.5 5.0 >.'4.5 ;'4.0 4.0 3.5 :a " 110 10.0 •. 8.5 7.0 6.0 5.5 5.0 . 4.5 4.0 4.0 3.5 ;'4, 120,; 10.0 = B. 7.0'. 6.0 5.5 . 5.0 4.5••'- 4.0 '4.0 3.5 Category .130 +• 9.5 S 8:5 7.0 6.0 . „ 5.5 _ •5.0e. `•45 4.0 4.0 • 3.5 ". B" ;; 140 9.0 ;. 8.5 a7.0`" 6.0 5.5: y 5.0'li S _ 4.5' : 4.0 • 4.0 3.5 M.y150 =8.0 ='° : 8.0_ v -.n7.0-' 6.0.: a 5.5 -*1 ' S:Ov 4.5-::.: 4:0:.: 4.0, * 3 _ti 160 7.5 7.5 �°• : 6:5- - ,`,6.0 - 5.5' S:0 " 4.5 -' 4.0 4:0 3.5 170 r :7.0 t 7.0.' 6.5 6.0 _ 5.5', 5.0_,. ,:: 4.5 _ 4.0 , ; -4.0 = 3.5 . -180- 7.0 - 7.0 • 6.5 6.0 5.5 5.0 4.5 : ; 4.0 : • 4.0 • :: 3.5. „. Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf .80 psf 90 psf 100 10.0 8.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 _c 105 10.0 8.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 110 9.5 8.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 120 9.0 8.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 Category 130 8.0 8.0 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 C 140 7.5 7.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 150 7.0 • 7.0 6.5 6.0 5.5 5.0 4.5, 4.0 4.0 3.5 1606.5 6.5 6.5 5.5 5.0 5.0 4.5 4.0 4.0 3.5 170 6.0 6.0 6.0 5.5 '5.0 5.0 4.5 4.0 4.0 3.5 180 6.0 6.0 6.0 1 5.5 5.0 4.5 - 4.5 . 4.0 4.0 3.5 Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf `100. 10.0. 8.5', `,7.0`=: `6.0 5.5 +, 4:5 4.0 6':4:0 g ', 3:5' 105. " 9.5' -8.5 ,. 7.0 '6.0,. 5.5 _5.0_ 5.0 4.5 _ 4.0 4.0"' 3.5 110, 9.0 8.5- ' 7.0 6.0 '5.5• ,`'S.0 4.5 4.0.' 4.0 3.5 r :120' 8.5 -% 8.0 a `7.0' , 6.0t:5.5 5.0 4.5 • '. 4.0 "- :, 4.0 ,3.5 Category '.' 130 s 7.5: 7.5' 7.0 '6.0 ^ 5.5 - ,. 5.0 -4.5 4.0 4.0' 3.5" D ` , . - 140 ', 7.0 • 7.0 6.5 ' 6.0 ' > . ,. 5.5. - 5.0 4.5 4.0 ` 4.0..°; _ 3.5 "`'`:'• ry 150 6.5 6.5' " 6.5 ,.r �' 6.0 .'' S.5 5.0 .. 4.5 • 4.0 _<•. 4.0 . x.3.5 '-`160 ..•, :6.0 '--• 6.0',, ..° 6.0 ?` 5.5 �. 5.0;-- c; 4.5 4.5 4.0 4.0" .' .'f •. 3.5 ' -. 170 -' a 5.5•. 5.5 " 5.5=_ 5.5'- 5.0`,< 4.5-. 4.5 4.0 4.0., 3.5 180 • ' 5.5 . 5:5' 5.5 5.5 5.0 r. 4.5 4.5,-, 4.01- X 4:0 ' 15. a. The table above ONLY includes 13-52 rail capacity check. It does not include roof attachment or roof capacity check b. Wind risk category II per ASCE7-30 C. Topographic factor, kzt is 1.0 d.' Maximum mean roof height is 60 ft. e. Average parapet height is 0 ft f. Roof pitch is between 7 degree and 27 degree g. Maximum solar panel weight is 60 lbs h. Height of solar panel is between 2'.--' and.10" to roof L Deflection criteria of L/60 per AC428 Section 4.3 j. The wind speeds above are LRFD values k. Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum span indicated on the chart I. The span length applies to a seismic design category E or less M. Maximum cantilever is L/3 2 of 5 a. The table above ONLY includes 13-52 rail capacity check. It does not include roof attachment or roof capacity check b. Wind risk category II per ASCE7-10 C. Topographic factor, kzt is 1.0 d. Maximum mean roof height is 60 ft. e. Average parapet height is 0 ft f. Roof pitch is between 7 degree and 27 degree g. Maximum solar panel weight is 60 lbs h. Height of solar panel is between 2" and 10" to roof ' L Deflection criteria of L/60 per AC428 Section 4.3 j. The wind speeds above are LRFD values k. Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum span indicated on the chart I. The span length applies to a seismic design category E or less M. Maximum cantilever is L/3 3 of 5 13/52 Rail Zone 2 Span Chart , Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf 100: 9.5 8:5'- '' 7.0 -6.0 - 5.5 5.0- r 4.5 ` 4.0. 4:0 3.5 105^ 9.0•" 8:5 7.0' 6.0 5.5 5.0' 4.5 4.0 4.0'. 3.5`." - 110 . 8.5 8.0 ;• 7.0 6.0 a' 5.5 5.0 4.5 • 4.0,-. -4.0 3.5 = _ 120 7.5 ,• 7.5 7.0 6.0 ,5.5 5.0 4.5 4.0 • `; 4.0 3.5 Category 130 - 7.0 1: 7.0 6.5 6.0 5.5 - = 5:0 . ' ' 4.5 r... _ " 4.0 4.0 3.5 B 140 `-.. 6.5.. ,6.5' _'.6.5 5.5. -..5.0 5.0-. 4.5,.•,_ _. 4.0.`,. .4.0 3.5.-_=: U 150 x•6.0. ` 6.0� . 6.0 5.5 _ 5.0, 4.5"- - 4.5 4.0 4.0 ' >� 3.5'' �t GR 160.-- 5.5 ` 5,5 > 5.5: 5.5 f - 5.0 4.5 4.5 4.0 4.0 3.5 _ 170 5.0 5.0 5.0 5.0 5.0' "' 4.5 4.5 4.0 4.0 ^ 3.5' 3? .�.,�:7.., ,.• 180 5.0 5.0 5.0 5.0 5:0, - 4.5 4.5 4.0 '4.0. a .x.3:5 ;',. Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf 100 8.0 8.0 7.0 6.0 5.5 5.0 4.5 4.0 4.0 ` 3.5 105 7.5 7.5 7.0 6.0 5.5 5.0 4.5 4.0 4.0 3.5 110 7.5 7.5 6.5 6.0 5.5 5.0 4.5 4.0 4.0 3.5 120 6.5 6.5 6.5 6.0 5.5 5.0 4.5 4.0 4.0 3.5 Category 130 6.0 6.0 6.0 5.5 5.0 4.5 4.5 4.0 1 4.0 3.5 C 140 5.5 5.5 5.5 5.5 5.0 4.5 4.5 4.0 • 4.0 3:5 +' 150 5.0 5.0 5.0 5.0 5.0 4.5 4.5 4.0 4.0 3.5 5.0 5.0 5.0 5.0 5.0 4.5 4.5 4.0 4.0 3.5 170 4.5 4.5 4.5 4.5 4.5 4.5 4.5 4.0 4.0 3.5 180 4.5 4.5 4.5 4.5 4.5 4.5 4.5 4.0 4.0 3.5 Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf. 70 psf 80 psf 90 psf 100 - 7.5' 7:5, .. 6.5' 6.0, ...` ` 5.5 5.0 4.5 - 4.0 . '! 4.0 •. 3.5 ._ 105 7.0 ,, 7.0 6.5 6.0 S.5 5.0 4:5 4.0 4.0 3.5 , 110 6.5 6.5 6.5 6.0 5.5 -'.5.0 : 4.5°' 4.0 _ 4.0 3.5: 120 6.0 6.0 6.0 5.5 5.0 4.5 4.5 4.0 4.0'- ;' 3.5 Category "130 5.5:'3 ° _• ' 5.5 5.5 5.5 `W 5.0- 4.5 ' 4.54.0 r: " 4.0 ` 3.5 '+ D e; .,- -140 -- „ 5.0' "".5.0 5.0 5.0 5.0 4.5. 4.5' ; • 4.0" ' 4.0 + 3.5 i .. 150 5.0 5.0 5.0 : 5.0- 5.0 4.5 - 4:5 - 4:0 4.0 P160' 4.5 .• 4.5 4.5' •4.5 -4.5 4.5 4.5 4.0 4.0 170 4.0" 4.0 : 4.0' 4.0 : 4.0'.. 4.0 4.0 ; - 4.0 4.0 • 3.5 + 180 .4.0?'y 4.0 • 4.0 4.0 4.0 4:0'- 4.0-•' 4.0 , 4.0W a. The table above ONLY includes 13-52 rail capacity check. It does not include roof attachment or roof capacity check b. Wind risk category II per ASCE7-10 C. Topographic factor, kzt is 1.0 d. Maximum mean roof height is 60 ft. e. Average parapet height is 0 ft f. Roof pitch is between 7 degree and 27 degree g. Maximum solar panel weight is 60 lbs h. Height of solar panel is between 2" and 10" to roof ' L Deflection criteria of L/60 per AC428 Section 4.3 j. The wind speeds above are LRFD values k. Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum span indicated on the chart I. The span length applies to a seismic design category E or less M. Maximum cantilever is L/3 3 of 5 Exposure Wind 4.0 - 4.0 4.0 .. 4.0 is/sZ Kan cone 3 Span Chart Ground Snow Load 4.0 .0 4.0 • • .;•„3.5 3:5 �= Exposure Wind Speed 100 -. 0 psf ',- 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf t�> 105 7.5 7.5. =6.5 •. 7.0 K. 6.04.5 - *° 4.0'> 5.0 r�. 4.0 4.0 7.0 6.5 _ 6.0 '5.5 • 5.0 r 4.5 4.5 4.0 4.0 z 110 ;6.5 6.5 6.5 6.0 5.5 4.0 3.5 120 5.0 5.0 5.0 5.0 .` 120,- 6.0_ 6.0' 6.0. -5.5 5.0 ;_4:5_ 4.5•. 4.0 4.0....=:3.5'" Category B ' • 130 w'S.5 5.5. „ .5.5 5.5 •` -5.0 y { 140 5.0 5.0' 5.0 5.0 5.0 _ 4.5 4.5 4.0 4.0 3.5 '6150' '• 5.0 5.0 S.O. 5.0 =' = 5.0 4:5° J 4.5 160 4.5 4.5 4.5 4.5 4.5 4.5 a 4.5 4.n An c_ 4.0 , 4.0_ 4.0 180 ' 4.0 4.0 _4.0' 4.0 - 4.0 4.0 .. 4.0 4.0 4.0 .0 4.0 • • .;•„3.5 3:5 �= Exposure Wind Ground Snow Load Speed. 0 psf. 10 psf 20 psf 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf 100 6.5 6.5 6.5 ''. 5.5 5.0 5.0 4.5 4.0 4.0 3.5 �•+ 105 6.0 6.0 6.0 5.5 5.0 4.5 4.5 4.0 4.0 3.5 110 5,5 5.5 5.5 5.5 5.0 4.5 4.5 4.0 4.0 3.5 120 5.0 5.0 5.0 5.0 5.0 Category .' 130 5.0 5.0 5.0 5.0 C 140 4.5 4.5 4.5 150 4.0 4.0 160 4.0 4.0 _ 170 3.5 3.5 180 Exposure Wind Ground Snow Load Speed 0 psf 10 psf 20 psf, 30 psf 40 psf 50 psf 60 psf 70 psf 80 psf 90 psf • s< 100. 6.0 _ 6.0...E 6.0 5.5- 4.5 r 4.0 4.0 3:5 105 "5.5 -5.5 5.5 `r+ ` 110 5.0 5. 5.0 : 5.0 t. 120- 5,0 5.0 5.0 Category 130 ' 4.5 • 4.5 - -::. 4.5 z:- 4.5 '.. 4.5. "• ; 4.5 4.5 : ; 4.0 4.0 3.5 4.0 4.0: 4.0, 4.0 4.0 '• 4.0 4.0 3.5 ''x' 4.0 4.0 ' 4.0 - ,'�4.0 4.0 .. 4.0 4.0 - 4.0.•, 4.0 ° '`. 3.5 ••_ 160 3.5 . 3.5 '. 3.5 3.5 •:. ,,�: • s • 3.5 3.5 3.5 � 3 5 • :„ 3.5 ;, -..3.5 of .170 3:5. 3.5 L - _ °180 .`3.0. 3.0 •3.0 -3.0 '`'3.0°• •3.0, 3.0 _�3.0 3.0• 3.0, a. The table above ONLY includes 13-52 rail capacity b.. Wind risk category II per ASCE7-10 check. It does not include roof attachment or roof capacity check C. Topographic factor, kzt is 1.0 d. LMaximum mean roof height is 60 ft. e. Average parapet height is 0 ft f. Roof pitch is between 7 degree and 27 degree g. Maximum solar panel weight is 60 lbs h. Height of solar panel is between 2" and 10" to roof i'. Deflection criteria of L/60 per AC428 Section 4.3 j. The wind speeds above are LRFD values k. Mounting Systems, Inc. strongly recommends a maximum span of 8 feet, but in any case, not to exceed the maximum indicated on the chart span I. The span length applies to a seismic design category E or less M. Maximum cantilever is L/3 4 of 5 solar'- .. -. SolarEdge Single Phase Inverters for North America SE3000H-US / SE380OH-US / SE5000H-US / SE6000H-US / SE760OH-US •. M { � Y . "•r:° y solar-.: wMD^ we F i ' ♦ Y i t yM1 • r� /A ,J � k�t �]'�^ � �4' �.+s :r -mac..+ -_ - • .. �, �f �.. ., '�} •f +r ' � �. �Yy r s r'• �C, b5,,A C 1 t Optimized installation' With HD -Wave technology Specifically designed to work.w,ith power optimizers ' Record-breaking efficiency } Fixed voltage inverter for longer strings. ' �, Integrated arc fault protection and rapid shutdown for NEC 2014 and 2017, per.•article'690.11 and 690.12 F UL1741 SA certified, for CPUC Rule 21 grid compliance .Extremely small and easy to install outdoors or indoors High reliability without any.electrolytic capacitors P mninisia►0. "`={ Bullt m module' el'monLtoring �'; ' n { `' " waver 'Optional: Revenue grade data, ANSI C12.20 Class 0.5 (0.5% accuracy) USA -CANADA -GERMANY -UK -ITALY -THE NETHERLANDS-JAPAN-CHINA-AUSTRALIA-ISRAEL-FPANCE-BELGIUM-TURKEY-INDIA-BULGARIA-ROMANIA-HUNGARY-SWEDEN- www.solaredge.us SOUTH AFRICA -POLAND -CZECH REPUBLIC solar Single Phase Inverters for North America SE3000H-US / §E3800H-US / SE5000H-US / SE60004-US/ SE760OH-US M For other regional settings please contact SolarEdge support IA A higher current sour:e may be used; the inverter will limit its input current to the values stated Revenue grade invertar P/N: SExxxxH-USOODNNC2 Power de -rating from.50'C t'l -40 version P/N: SE)o=H-USOOONNU4 SE3000H-US Sb800H-US SESOOOH-US SE6000H-US SE760OH-US IOUTPUT A Rated AC Power Output 3000 3 00 800 0, ... .... ..... ........ 7�90 VA ............. AC Power Output 30 0 ........ 3800 5, 6000 ......... ......... ........ .......... 7600 VA AC Output Voltage (183 - 208 _229) : V Vac AC Output V oltag e Min: Nom. -Max. (21 1 240 2 64) ................... ............. ........................................................ AC Frequency (Nominal) ...... : .. ................... .... ................... ................... ................... 59.3 - 60 - 60.51l1 .. Hz ....A . ....... ...Maximum .Continuous .Output .Current . 2.08Y .......... ........ �........16........ ........ .......... ............. Maximum Continuous OutputCurrent240V ........................... 12. 5 ................... 21 2 ................... .......... ........ .......... .3 .... A ............. GFDI Threshold ................................................Yes A .. ... .... . * . ..... Utility *I� on ito ririg Islan di ng Prote c tion Country Configurable Thresholds I INPUT M�F ........... 4 ................... ................... ....... 7� ...... ....... ?Aq� ...... ................... W ............. ..Maximum .D.C.pq, ........................ Tran.... p9ppu.n..c.e.d.......................... . • ....................... ............. ..Maximum Input Voltage................................... ............ ........... :Yes 4 0 ......... .................... Vdc 'V'*d'c... Nominal DC Input Volta ... ................... ............................. .......... 380 466*-*- ................... .... Maximum Input Current 208V .......... ......... 1 . I ................. A-dc ............. Maximum Input Current n' t- 8.5 10.5 13.5 16.5 ................... ................... 20 ................... Adc ............ ..................... .................................... !qpq!5ho,1 Circuit Current .......... ............................ ................... ................................................ ................... 45 ................................................ --- .... Adc ..��Y�rs.e-.Polarity Protection ............................. .... I .................................. ......... Yes Ground -Fault Isolation Detection .. Sensitivity 600koSensitvi ............. Inverter Efficiency 99 ...... ...................................... 99..2 ......................... ........... ...... % ...... ..Maximum ...... ..CEC Weighted Efficiency ........ 99% Nighttime Power Consumption < 2.5 W I ADDITIONAL FEATURES,., e Suppo.rte.d. Communication interfaces ..... I .. .. ........ . ............................... ............................................... RS485, Ethernet, ZigBee (optional), Cellular (optional) ................................................... ............. ..��Y�nue Grad.e.Data,AN.SI.C.12,20 ..................... .. ...... . ..... .. . ...................................... OptionalM ....... Rapid Shutdown.- NEC 2014 and 2017 690.12_ Automatic Rapid Shutdown upon AC Grid Disconnect 'I STANDARD COMPLIANCE Safety UL1741, UL1741 SA, UL1699B, CSA C22.2, Canadian AFCI according to ....... . . . .... .................... *Rule *2*'l',''1"4*(HI)' T.I.L. M-07 ............. Grid Connection Standards I*E'E*E'1'5"4*7*,' Rule Emissions FCC Part 15 Class B PECIFICATIONV' INSTALLATION SPECIFICATIONS .,ACOut put Conduit . Size./ AWG. Rang.e ................. ... ... .. .. .... ...... . ... . ................................... 0.75-1" Conduit 14-6 AWG .................................... ..................... .... ......... DC Input Conduit Size / # of Strings / AWG Range .............................................. 0.75-1" Conduit -.?��(iqAs�A4_15AWG �! . ... ............. ................................................... ..Pimensions with Safety Switch (HxWxD) ........................... I ........................... ........................... , 17.7 x 14.6 x 6.8 450 x 370 x ii� ........... ..... ....................................... "*'* in/mm ............. Weight with Safety Switch ........................................................... ............... 22/10 1 1* 1*'. 4 1 26.2/11.9 ...................... ....25.1I............ ................... ................... lb / kg ............. < 25 < 50 dBA Natural convection and Cooling Natural Convection internal fan (user ....................................... ................................................................................ replaceable)... ... ?) ... ............. ......................... ......................... 13 to +140 / -25 to +60(') (-407 / -40'C.option)l1) ........................ ............... .................... ...... ......... 7 /'C ............. Protection. Rating ...................................... ..................... ........... NE.M.A.3RAI.riverl:6.r.with. Safety Switch) ................. i ........... ............. M For other regional settings please contact SolarEdge support IA A higher current sour:e may be used; the inverter will limit its input current to the values stated Revenue grade invertar P/N: SExxxxH-USOODNNC2 Power de -rating from.50'C t'l -40 version P/N: SE)o=H-USOOONNU4 CERTIFICATE OF' COMPLIANCE Certificate Number 20170629-E341165 . Report Reference E341165-20170629 Issue Date 2017 -June -29 Models covered by this certificate provide functionality incompliance with UL 1.741 Supplement A (SA Grid Support): Compliance testing was conducted.on samples of the products according to the test methods in the following sections of UL 1741 with compliant results: Grid Su ort. Function Tested ANTI-ISLANDING PROTECTION - UNINTENTIANAL ISLANDING WITH GRID SUPPORT FUNCTIONS -ENABLED Source Requirement Documents ' Electric Rule No. 21 Hh.1a Test Standards) and Section s UL 1741 SA 8 Re ort Date 2017 -JUNE -29 LOW/HIGH VOLTAGE RIDE - THROUGH ule No. 21 Table Hh.1 UL 1741 SA 9 2017 -JUNE -29 LOW/HIGH FREQUENCY RIDTHROUGH EEIectEricRuleNo. 21 Table Hh.2 UL 1141 SA10 2017 -JUNE -29 RAMP RATES Electric Rule No. 21 Hh.2k UL 1741 SA 11 2017 -JUNE -29. RECONNECT BY "SOFT START" Electric Rule No, 21 Hh.2kUL 1741 SA 11 2017_JUNE-29 SPECIFIED POWER FACTOR Electric Rule No. 21 Hh.2i UL 1741 SA 12 2017 -JUNE -29 'DYNAMIC VOLT/VAR OPERATIONS Electric Rule No. 21 Hh.2J UL 1,741 SA 13 2017 -JUNE -29 FREQUENCY -WATT Electric Rule No. 21 .Hh.2.l UL 1741 SA 14 2017 -JUNE -29. VOLT -WATT Electric Rule No. 21 Hh.2:m UL 1741 SA 15 2017-JUNE729 Testing conducted to the requirements of UL 1741 -SA corresponds to the minimum requirements for CA Rule 21, 2015. Complete ratings, available certified settings for the Grid Support functions, and results of compliance testing are retained in the complete UL Report for this product. Bruce Mahmnhok Director North American Certification Program UL LLC Any Inforrnallon and documentation Involving UL Mark services are provided on behalf of UL LLC (UL) or any authorized Ilcenseo of UL For questions, please contact a local UL Customer Service Representative at htlollul comlaboutulflo ati ns1 - Page 3 of 6 A9: Low/High Voltage/Frequency Ride hrough (LiHVIFRT) end Must Trip Settings - qhs Must,Tnp 1 t "x: ` .x Nlax NdFn Max Min High voltage 3 - time s NA NA 0.500 0.100 High voftatge 3 - magnitude percentage NA NA 121.7 10£ High voltage 2 - time s 99.800 0.300 20.000 0.500 High voft3ge 2 - magnitude percentage 1.19 104 119 904 High voltage 9 - time s 299.800 0.800 300.0 1.0 High voltage 1 - magnitude percentage 115 902 115 102 Nomaml operating rarer percentage 110 88 110 88 Latin voltage 9 - time s 299-800 0.300 300.0 0.5 tow age 1 - magnitude percentage 98 70 98 70 Lave vantage 2 - time s 149.800 0.000 150.0 0.2 Low voltage 2 - magnitude pementa se 96 50 96 50 Lori voftage 3 - time s 29.800 0.000 30.0 0.1 Low voltage 3 - magnitude percentage 94 s 94 50 Bruce Mahrenholz, Director North American Certification Program UL LLC Any Information and documentation Involvtng UL Marc services are provided on behaB of UL LLC_ (UL) or any authorized licensee of UL For questions, please contact a local UL Customer Service Representative at hlto:/lul cornlaboutulnocatlonW - Page 4 of 6 r a t CERT IFICA`TE •OF C'OMPLIAN'C:E Certificate Number '20170629-E341165' Report Reference'. E341165-20170629 , Issue Date 2017 -June -29 SA'I®: Lo�e/HigFi Frequency Ride p �"�� Ride Tough *` [�%st Tnji F Tr1p Setdi Throiegh ( RT) and Must nas s� �z r `: r" x , ` ' --M.,:3 M�,.. ,,.�"*�..*.�� • . tiQr3x 'titin__ •' .r � ,��N��� w --100 Ramp - p rate %trateft VAr Soft start ramp rate %trafaft 100 " 0.11 sA1a� s ' , N' h frequency 2 -time s NA AIA D.S 0.1 High frequency 2 -magnitude Hz NA NA 65 For ques tions, lease p 60.3 Page 5 of 6 High frequency 1 -time s 599.8. - 0.8 600 0.16 r High frequency 1 -magnitude Hz • 65 60.1 65 _ 60.9 Law frequency 1 -time 8, 59.9.8 0.8 600 0.16 Lows tre4twncy 1 -magnitude Hz 59.9 57 59.9. 57 Ldw frequency 2 --time NA NA Low frertuency 2-(nagnitude Hz, NA SD T SA11: Ramp Rate MR) and Soft Start 4SS1 1 pecked Power Factor (SPF), aka (INV3 .� _rUh[LsFAdlustinentR ge; Mai -Mini �- Induetive,'underexcited, power factor VAdW Capacitive, overexcited, power factor VAdW " 1.0 ` SA13: VoIt/VAr Mode t _Unity?x�+ IWIMMum AC EPS voUge range � 'jAcQustrneritRatt MaxNFia� . 0.80 1.0 • � s a Uit� � e...� . _....w, �A�ju$tEnrR_�R_ onge � ;W1� `�.+�•��'"� ` � t� .,�� �To�rance niti 120 1.0 . ,,.�"*�..*.�� • . tiQr3x 'titin__ •' .r � ,��N��� w --100 Ramp - p rate %trateft VAr Soft start ramp rate %trafaft 100 " 0.11 sA1a� s ' pecked Power Factor (SPF), aka (INV3 .� _rUh[LsFAdlustinentR ge; Mai -Mini �- Induetive,'underexcited, power factor VAdW Capacitive, overexcited, power factor VAdW " 1.0 ` SA13: VoIt/VAr Mode t _Unity?x�+ IWIMMum AC EPS voUge range � 'jAcQustrneritRatt MaxNFia� . 0.80 1.0 P.U: Maximum EUT input voftege P_U. 120 1.0 . . AC pouter W , 280 0 Reactive power absorption (inductive, umL-r excited) VAr 200 50 Reactive power production (capacitive, 016Tmxcifed) VAr 200 50 ' , Deadbared V 48 4.8 Scope VArti� 50 '0 RSA11 Tolerance: 5% plus 10% of command power , Bruce M_ahrenhol; Director North Amortcan Certification Program { UL LLC � Any Information and documentation Involving UL Mark services are provided on'behalf of UL' LLC (UL) or any autirortzed licensee of UL contact a local UL Customer Service Representative at htlpJful.com /aboutu1f1ocationN For ques tions, lease p - Page 5 of 6 .. AC frequency with function enabled +r+M-�+w.ifi+.'�t Y'-; +is"NpeMfn"'.'fwi'F✓r Range- Max t4fm Kz -57 65 High end frequency droop settings Hz S2 60.1 Slope of frequencydroop %PrateQlHz 200 20 SATS: Volt -Watt (VW) Adjustment range of the start of the caraibmerd function 7T `A ent Ra e Uustm Max Mm b 138.0 121.0 Adjustment range of the stop of the curtailment function v 138.0 123.0 Slope of voltage c urtaibnerd e5pratedfV M 5.5