Generac Generator Sizing Guide : simplebooklet.com

ii Generator Sizing GuideIMPORTANT NOTICEThis booklet is designed to familiarize estimators and installers with correct sizing guidelines for residential and com-mercial generators. The information is not comprehensive, nor does it replace or supersede any material contained inany of the written documents shipped with the equipment. This booklet should only be used in conjunction with theowner’s manual, installation manual and other technical documents shipped with each product. Always read all accom-panying documentation carefully before attempting to install any generator, transfer switch, or related equipment.HOW TO USE THIS BOOKLETThis booklet contains electrical load information, plus an outline of generator surge capability, fuel pipe sizing, liquidpropane (LP) tank sizing, and UPS / generator compatibility. The worksheet pages can be removed from the book andphotocopied to create additional on-site estimating sheets for use with individual jobs.SAFETY INFORMATIONCorrect generator sizing is crucial to the success of any installation and requires a working knowledge of electricity andits characteristics, as well as the varying requirements of the electrical equipment comprising the load. When analyzingelectrical loads, see the manufacturer’s nameplate on each major appliance or piece of equipment to determine start-ing and running requirements in terms of watts, amps, and voltage. When choosing generator output for commercial orindustrial applications, select a rating approximately 20–25% higher than peak load (for example, if the load is about 40kilowatts, select a 50 kW unit). A higher rated generator will operate comfortably at approximately 80% of its full capac-ity and will provide a margin of flexibility if the load increases.For safety reasons, the manufacturer recommends the standby power system be installed, serviced, and repaired byan Independent Authorized Service Dealer (IASD) or a competent, qualified electrician or installation technician who isfamiliar with applicable codes, standards, and regulations.Strictly comply with all regulations established by the Occupational Safety & Health Administration (OSHA) and strictadherence to all local, state, and national codes is mandatory. Before selecting a generator, check for municipal ordi-nances which may dictate requirements regarding unit placement (setback from building and/or lot line), electrical wir-ing, gas piping, fuel storage (for liquid propane or diesel tanks), sound, and exhaust emissions.

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Table of ContentsGenerator Sizing Guide iiiGenerator PlacementCarbon Monoxide Detectors ......................................................................................................................................1Potential CO Entry Points ..........................................................................................................................................1Protect the Structure ..................................................................................................................................................1Fire Prevention ..........................................................................................................................................................2Load CalculationTable 1. Motor Load Reference AC & Heat Pumps ................................................................................................. 3Table 2. Motor Load Reference General Residential ............................................................................................... 3Table 3. Non-Motor Load Reference—Residential .................................................................................................. 4Table 4. Non-Motor Load Reference—Commercial ................................................................................................. 4Table 5. Surge Capability—Air-cooled Generators .................................................................................................. 5Table 6. Surge Capability—Liquid-Cooled Generators ............................................................................................ 5Table 7. Surge Capability—Protector Series Generators (Diesel) ........................................................................... 5Fuel System SizingTable 8. Fuel Pipe Sizing—Natural Gas ................................................................................................................... 7Table 9. Fuel Pipe Sizing Natural Gas—3.5–4.9 in water column ........................................................................... 7Table 10. Equivalent Straight Lengths in Ft / M of Sch. 40 Pipe Fittings and Valves ............................................... 7Table 11. Fuel Pipe Sizing LP Vapor (LPV)—10–12 in water column (2.488–2.986 kPa) ....................................... 9Table 12. LPV Weights and Measures ..................................................................................................................... 9Table 13. Equivalent Straight Lengths in Ft / M of Sch. 40 Pipe Fittings and Valves ............................................... 9Table 14. LP Vapor (LPV) Tank Sizing .................................................................................................................. 10Table 15. Fuel Required for Common Appliances ................................................................................................. 10Table 16. Generator Fuel Consumption ................................................................................................................. 11UPS SystemsUPS – Generator Compatibility ................................................................................................................................12UPS – Generator Compatibility Sizing Examples ....................................................................................................13NEC InformationNEC (700, 701, 702) Comparison .......................................................................................................................... 14Electrical Formulas, Weights and MeasuresTear-out WorksheetsSelected Circuit Load Calculator ..............................................................................................................................17Generator Sizing Instructions ...................................................................................................................................18System Capacity – Load Calculator .........................................................................................................................20Directions for 2020 NEC, Article 220, Part IV ..........................................................................................................20Additional Sheets......................................................................................................................................................23

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Generator Sizing Guide 1Carbon Monoxide DetectorsSee Figure 3-1. CO detectors (K) must be installed andused to monitor for CO and to warn individuals about thepresence of CO. CO detectors must be installed andtested in accordance with the CO detector manufac-turer’s instructions and warnings. Contact local buildinginspection department for any applicable requirementsconcerning CO detectors. See NFPA 72, National FireAlarm and Signaling Code, and Section R315 in the ICCInternational Residential Code for more information.IMPORTANT NOTE: Common smoke alarms do NOTdetect CO gas. Do not rely on smoke alarms to protectresidents or animals from CO. The only way to detectCO is to have functioning CO alarms.Potential CO Entry PointsSee Figure 3-1. Generator exhaust can enter a structurethrough large openings, such as windows and doors.However, exhaust and CO can also seep into the struc-ture through smaller, less obvious openings. Protect the StructureVerify structure itself is correctly caulked and sealed toprevent air from leaking in or out. Voids, cracks, or open-ings around windows, doors, soffits, pipes, and vents canallow exhaust gas to be drawn into the structure.Some examples of potential entry points are describedand included in, but not limited to, the accompanyingtable.Figure 3-1. Carbon Monoxide—Potential Entry PointsID Entry Point Description / CommentsA Windows and doors Architectural details which can be (or are) opened to admit fresh air into the structure.B Garage door CO can leak into garage if door is open, or does not seal correctly when closed.C Attic vent Attic vents, ridge vents, crawl space vents, and soffit vents can all admit generator exhaust.D Basement windows Windows or hatches allowing ventilation to or from lower level of a structure.EFurnace intake / exhaust ventAir intake and exhaust pipes for furnace.F Wall cracksIncludes (but not limited to) cracks in wall, foundation, mortar, or air gaps around doors, windows, and pipes. G Dryer vent Exhaust duct for clothes dryer.H Airflow restrictionsStructural corners and locations with heavy vegetation restrict airflow. Exhaust gases can collect in such areas.J Make up air systemIMPORTANT NOTE: Mechanical and gravity outdoor air intake openings for HVAC supply air systems shall be located not less than 10 feet (3048mm) horizontally from the generator enclosure. See Section 401 in the ICC Mechanical Code for any additional requirements.K CO detectorSemi-permanently mounted device that detects carbon monoxide within the living area of the structure.AKBACGAAAFDEAHAC008781J

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2 Generator Sizing GuideFire PreventionThe generator must be installed at a safe distance awayfrom combustible materials. Engine, alternator, andexhaust system components become very hot duringoperation. Fire risk increases if unit is not correctly venti-lated, is not correctly maintained, operates too close tocombustible materials, or if fuel leaks exist. Also, accu-mulations of flammable debris within or outside the gen-erator enclosure may ignite.Distance RequirementsSee Figure 3-2. Minimum clearances must be main-tained around the generator enclosure. These clear-ances are primarily for fire prevention, but also to providesufficient room for removing front and end panels formaintenance purposes.Figure 3-2. Generator Distance RequirementsID Description DefinitionAFront and end clearanceMinimum clearance from the front and ends of generator must be 3 ft (0.91 m). This includes shrubs, bushes, and trees. B Rear clearanceFuel and electrical connections are made here. 18 in (457 mm) minimum clearance per SwRI testing, labeling, and listing, unless state or local codes dictate otherwise. CWindows, vents, and openingsNo operable windows, doors, vents, window wells, or openings in the wall are permitted near any point of the generator set. See unit installation manual for more information.D Existing wall The generator should not be placed closer than 18 in (457 mm) from existing walls.E Removable fenceA removable barrier (non-permanent; without footings) installed as a visual surround.Removable fence panels for servicing cannot be placed less than 3 ft (0.91 m) in front of the generator.F Overhead clearance 5 ft (1.52 m) minimum distance from any structure, overhang, or projections from wall.GMaintenance and servicingManeuvering space around generator set for performing routine maintenance tasks such as battery replacement and engine service. Do not attempt to conceal generator set with shrubs, bushes, or plants. See NEC Article 110.26 for more information.CAADEGACCC008782FB

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Generator Sizing Guide 3Table 1. Motor Load Reference AC & Heat PumpsRunning Load Starting LoadDescription HpRunning kWAmps @ 240V 1ØAmps @ 208V 3ØAmps @ 240V 3ØAmps @ 480V 3ØLR Amps @ 240V 1ØLR Amps @ 208V 3ØLR Amps @ 240V 3ØLR Amps @ 480V 3Ø1 Ton (12,000 BTU)11 5 3 3 1 33 22 19 102 Ton (24,000 BTU)22 10 7 6 3 67 44 38 193 Ton (36,000 BTU)33 15 10 8 4 100 67 58 294 Ton (48,000 BTU)44 20 13 11 6 117 78 67 345 Ton (60,000 BTU)55 25 16 14 7 145 97 84 427.5 Ton (85,000 BTU)7.57.5 37 24 21 11 219 146 126 6310 Ton* (120,000 BTU)5 Hp (x2) 10 49 33 28 14 145 97 84 4210 Ton (120,000 BTU)10 Hp10 49 33 28 14 250 167 144 7215 Ton* (180,000 BTU)7.5 Hp (x2)15 74 49 42 21 219 146 126 6315 Ton (180,000 BTU)15 Hp15 74 49 42 21 375 250 217 10820 Ton* (240,000 BTU)10 Hp (x2)20 98 65 57 28 250 167 144 7220 Ton (240,000 BTU)20 Hp20 N/A 65 57 28 500 333 289 14425 Ton (300,000 BTU)2525 N/A 82 71 35 625 416 361 18030 Ton* (360,000 BTU)15 Hp (x2)30 N/A 98 85 42 375 250 217 10830 Ton (360,000 BTU)30 Hp30 N/A 98 85 42 750 500 433 21740 Ton* (480,000 BTU)20 Hp (x2)40 N/A 131 113 57 500 333 289 14440 Ton (480,000 BTU)40 Hp40 N/A 131 113 57 1000 666 577 28950 Ton* (480,000 BTU)25 Hp (x2)50 N/A 163 142 71 625 416 361 18050 Ton (480,000 BTU)50 Hp50 N/A 163 142 71 1250 833 722 361* For multiple motor configurations, sequence starting is assumed. Air Conditioning1 hp per 1 ton1 ton = 12,000 BTUsTable 2. Motor Load Reference General ResidentialRunning Load Starting LoadDescription HpRunning kWAmps @ 120V 1ØAmps @ 240V 1ØStarting kWLR Amps @ 120V 1ØLR Amps @ 240V 1ØRefrigerator pump, sump, furnace, garage opener 0.5 0.5 4.9 2.5 1.5 25 13Freezer, washer, septic grinder 0.75 0.75 7.4 3.7 2.3 38 19General 1 Hp 1 1 9.8 4.9 3 50 25Well and septic lift pump 2 2 19.6 9.8 6 100 50

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Generator Sizing Guide 5Table 5. Surge Capability—Air-cooled GeneratorsRated Output (Running Amps) LP / NG Maximum Surge CapabilitySize (kW) RPM 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø7.5 3600 31/25 N/A N/A N/A 62 N/A N/A N/A10 3600 42/38 N/A N/A N/A 70 N/A N/A N/A13 3600 54/54 N/A N/A N/A 95 N/A N/A N/A14 3600 58/58 N/A N/A N/A 102 N/A N/A N/A15 ECO 3600 63/63 N/A N/A N/A 185 N/A N/A N/A16 3600 66/66 N/A N/A N/A 130 N/A N/A N/A18 3600 75/70.8 N/A N/A N/A 150 N/A N/A N/A20 3600 83/75 N/A N/A N/A 185 N/A N/A N/A20 kW - 3 Phase 3600 N/A 69/59 N/A N/A N/A 112 N/A N/A22 3600 92/81 N/A N/A N/A 210 N/A N/A N/A24 3600 100/89 N/A N/A N/A 220 N/A N/A N/A26 3600 108/93.8 N/A N/A N/A 230 N/A N/A N/AMaximum power decreases approximately 3.5% for each 1,000 ft (304.8 m) above sea level, and will decrease approximately 1% for each 10 °F (6 °C) above 60 °F (16 °C).Table 6. Surge Capability—Liquid-Cooled GeneratorsRated Output (Running Amps) LP / NG Maximum Surge Capability Size (kW) RPM 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø22 1800 92/92 76/76 66/66 N/A 135 92 80 N/A25 3600 104/104 87/87 75/75 N/A 170 130 112 N/A27 1800 113/104 94/87 81/75 N/A 170 120 103 N/A30 3600 125/125 104/104 90/90 N/A 180 155 134 N/A32 1800 133/133 111/111 96/96 48/48 180 210 182 8736 3600 150/150 125/125 108/108 54/54 240 130 115 6038 1800 158/158 132/132 114/114 57/57 180 210 182 8745 3600 188/188 156/156 135/135 68/68 240 130 115 6048 1800200/200 167/167 144/144 72/72300 242 260 12360 3600250/250 208/208 180/180 90/90320 210 182 9160 1800250/250 208/208 180/180 90/90413 313 289 12280 1800312/333 260/278 226/241 113/120600 500 432 192100 1800 400/400 347/333 300/288 150/144 854 430 372 244130 1800 542/542 451/451 391/391 195/195 854 816 707 351150 1800 583/600 486/520 421/451 210/226 617 619 536 351Temperature Deration: 1.65% for every 10 °F above 77 °F or 3% for every 10 °C above 25 °C.Altitude Deration (22, 25, 27, 30, 45, 48, 70, 100, 130 and 150): 3% for every 1,000 ft above 600 ft or 1% for every 100 m above 183 m.Altitude Deration (32, 36, 38, 60, and 80 kW): 3% for every 1,000 ft above 3,000 ft or 1% for every 100 m above 915 m.Table 7. Surge Capability—Protector Series Generators (Diesel)Rated Output (Running Amps) Maximum Surge Capability (LR Amps @ 30% Voltage Dip)Size (kW) 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø 240V 1Ø 208V 3Ø 240V 3Ø 480V 3Ø15 62 52 45 N/A 129 90 78 N/A20 83 69 60 N/A 211 143 124 N/A30 125 104 90 45 168 144 125 6448/50 200 173 150 75 189 218 189 87

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Generator Sizing Guide 7Natural Gas1 cubic foot = 1,000 BTU1 therm = 100,000 BTUGas consumption = 13,000–16,000 BTU per kW/hrPressure1 in Hg = 13.61 in water column1 in water column = 0.249 kPa3.5–14 in water column = 0.872–3.487 kPaNOTE: • Pipe sizing is based on 0.5 in water column pressure drop.• Verify adequate service and meter sizing.• Tables based on schedule 40 black pipe.NOTE: Size fuel pipe according to sizing charts or local codes.When installing fuel piping other than Sch. 40 black pipe, seemanufactures sizing charts and size that product to comply withthe requirements outlined here-in.The piping system between the primary pressure regulatorand generator must be correctly sized to provide fuel vol-ume required at 100% load, while also staying within pres-sure range noted on unit specification sheet.Table 8. Fuel Pipe Sizing—Natural Gasin WC / kPa kWPipe Size (in / mm)Allowable Pipe Distances (ft / m)0.75 / 19 1 / 25 1.25 / 32 1.5 / 38 2 / 51 2.5 / 63 3 / 765–7 / 1.24–1.747.5/10 60 / 18.3 200 / 61 750 / 228.613, 14/16, 18 10 / 3.1 55 / 16.7 200 / 61 450 / 137.115 ECO/20 10 / 3.1 35 / 10.7 140 / 42.6 300 / 91.420-3Ph. 10 / 3.1 35 / 10.7 140 / 42.6 300 / 91.422 10 / 3.1 30 / 9.1 115 / 35 250 / 76.224 10 / 3.1 30 / 9.1 115 / 35 250 / 76.226 10 / 3.1 30 / 9.1 115 / 35 250 / 76.25–14 / 1.244–3.48425 & 30 10 / 3.1 60 / 18.2 125 / 38.1 450 / 137.122 & 27 20 / 6.1 100 / 30.4 200 / 61 700 / 213.332 20 / 6.1 100 / 30.4 200 / 61 700 / 213.336 30 / 9.1 60 / 18.3 220 / 6738 10 / 3.1 70 / 21.3 150 / 45.7 500 / 152.445 10 / 3.1 60 / 18.3 200 / 61 450 / 137.148 10 / 3.1 60 / 18.3 200 / 61 450 / 137.160 20 / 6.1 40 / 12.2 150 / 45.7 350 / 106.6 1000 / 304.811–14 / 2.739–3.48770 10 / 3.1 30 / 9.1 100 / 30.4 200 / 61 700 / 213.380 10 / 3.1 20 / 6.1 75 / 22.8 170 / 51.8 475 / 144.7100 10 / 3.1 20 / 6.1 75 / 22.8 170 / 51.8 475 / 144.77–11 / 1.744–2.739130 10 / 3.1 40 / 12.2 90 / 27.4 250 / 76.2150 10 / 3.1 30 / 9.1 70 / 21.3 200 / 61Table 9. Fuel Pipe Sizing Natural Gas—3.5–4.9 in water columnPipe Size(in / mm)Allowable Pipe Distances (ft / m)0.75 / 19 1 / 25 1.25 / 32 1.5 / 3810 kW 20 / 6.1 60 / 18.3 175 / 53.313, 14/16, 18 kW30 / 9.1 125 / 38.1 200 / 6115 ECO kW 10 / 3.1 60 / 18.3 125 / 38.120/22/24/26 kW 10 / 3.1 60 / 18.3 125 / 38.120-3Ph. kW 10 / 3.1 60 / 18.3 125 / 38.1Table 10. Equivalent Straight Lengths in Ft / M of Sch. 40 Pipe Fittings and ValvesPipe Size (in / mm)45˚ Elbow 90˚ Elbow Tee Fitting Fuel Shutoff0.75 / 19 0.96 / 0.29 2.06 / 0.63 4.12 / 1.25 0.48 / 0.141 / 25 1.22 / 0.37 2.62 / 0.80 5.24 / 1.60 0.61 / 0.181.25 /32 1.61 / 0.49 3.45 / 1.0 6.9 / 2.10 0.81 / 0.251.5 / 38 1.88 / 0.57 4.02 / 1.22 8.04 / 2.45 0.94 / 0.292 / 51 2.41 / 0.73 5.17 / 1.57 10.3 / 3.14 1.21 / 0.372.5 / 63 2.88 / 0.88 6.16 / 1.88 12.3 / 3.75 1.44 / 0.443 / 76 3.58 / 1.10 12.6 / 3.84 15.3 / 4.66 1.79 / 0.55

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8 Generator Sizing GuideLP Gas Installation (Typical)Figure 3-4. LP Gas Vapor Installation (typical)LPG Megajoules/h = m3/h X 93.15 BTU/h = ft3/h X 2520A Fuel data decalB Minimum distance from rear obstruction—see unit installation manual for distance requirementsC Manual fuel shutoff valve (pressure port optional)Must be located no more than 6 ft (1.83 m) away from fuel inlet.D Pipe fittings (field supplied)E Flexible fuel lineF Verify minimum distance requirements for regulator vent according to local gas codes. Regulator should be a minimum of 5 ft (1.5 m) from generator. Local codes and regulator manufacturer may have further clearance requirements.G ClampH Secondary fuel pressure regulatorJ Manual fuel shutoff valveK Primary fuel pressure regulatorL Fuel tank—sized large enough to provide required MJ/BTU for generator set operating at FULL load and ALL connected appliance loads. Be sure to correct for weather evaporation.M Sediment trap008966DEJLHGCKBFA

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Generator Sizing Guide 9NOTE: • Pipe sizing is based on 0.5 in water column pressure drop.• Verify adequate service and meter sizing.• Tables based on schedule 40 black pipe.NOTE: Size fuel pipe according to sizing charts or local codes.When installing fuel piping other than Sch. 40 black pipe, seemanufactures sizing charts and size that product to comply withthe requirements outlined here-in.The piping system between the primary pressure regulatorand generator must be correctly sized to provide fuel vol-ume required at 100% load, while also staying within pres-sure range noted on unit specification sheet.Table 11. Fuel Pipe Sizing LP Vapor (LPV) 10–14 in water column (2.488–3.487 kPa)NOTE: This table is for the length of low pressure fuel pipe between the secondary regulator and the generator.kWPipe Size(in / mm)Allowable Pipe Distances (ft / m)0.5 / 13 0.75 / 19 1 / 25 1.25 / 32 1.5 / 38 2 / 51 2.5 / 63 3 / 767.540 / 12 150 / 46 500 / 1521040 / 12 150 / 46 500 / 15213/1460 / 18 200 / 6115 ECO50 / 15 160 / 49 600 / 18316/1840 / 12 125 / 38 500 / 1522020 / 7 90 / 27 350 / 107 700 / 21320 kW-3Ph.30 / 9 100 / 30 350 / 107 800 /2442220 / 7 80 / 24 300 / 91 650 / 1982420 / 7 90 / 27 350 / 107 750 / 2292510 / 3 50 / 15 200 / 61 450 / 1372620 / 7 90 / 27 350 / 107 750 / 2292720 / 7 80 / 24 300 / 91 650 / 1983220 / 7 60 / 18 200 / 61 500 / 152 1700 / 5183810 / 3 80 / 24 175 / 53 400 / 122 1400 / 4274520 / 7 80 / 24 175 / 53 600 / 183 1400 / 4274820 / 7 80 / 24 150 / 46 550 / 168 1300 / 3966010 / 3 60 / 18 125 / 38 450 / 137 1100 / 3357010 / 3 40 / 12 90 / 27 300 / 91 750 / 22910030 / 9 60 / 18 200 / 61 500 / 152 1400 / 42713010 / 3 30 / 9 100 / 30 250 / 76 750 / 22915010 / 3 20 / 7 80 / 24 200 / 61 550 / 168Table 12. LPV Weights and MeasuresUnits of Measure Equivalent Units1 US Gallon 4.23 Pounds1 US Gallon 91,502 BTU @ 60ºF1 cubic foot 2,488 BTU @ 60ºF1 US Gallon 36.4 ft3 Gas1 Liter 23,700 BTU1 Pound8.55 ft31 in Hg 13.61 in water column1 in water column 0.249 kPa11–14 in water column 2.739–3.487 kPaTable 13. Equivalent Straight Lengths in Ft / M of Sch. 40 Pipe Fittings and ValvesPipe Size (in / mm)45˚ Elbow 90˚ Elbow Tee Fitting Fuel Shutoff0.75 / 19 0.96 / 0.29 2.06 / 0.63 4.12 / 1.25 0.48 / 0.141 / 25 1.22 / 0.37 2.62 / 0.80 5.24 / 1.60 0.61 / 0.181.25 /32 1.61 / 0.49 3.45 / 1.0 6.9 / 2.10 0.81 / 0.251.5 / 38 1.88 / 0.57 4.02 / 1.22 8.04 / 2.45 0.94 / 0.292 / 51 2.41 / 0.73 5.17 / 1.57 10.3 / 3.14 1.21 / 0.372.5 / 63 2.88 / 0.88 6.16 / 1.88 12.3 / 3.75 1.44 / 0.443 / 76 3.58 / 1.10 12.6 / 3.84 15.3 / 4.66 1.79 / 0.55

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10 Generator Sizing GuideTable 14. LP Vapor (LPV) Tank SizingTotal Tank Capacity (Gal / L)Usable Tank Capacity (Gal / L)Minimum Temp (°F / °C)Tank Capacity (BTU/hr)Length (in / mm) Diameter(in / mm)Overall Height (in / mm)120 / 454* 72 / 272 40 / 4.420 / -6.60 / -17.77246,240164,16082,08057 / 1448 24 / 610 33 / 838150 / 567* 90 / 340 40 / 4.420 / -6.60 / -17.77293,760195,84097,92068 / 1727 24 / 610 33 / 838250 / 946 150 / 40 / 4.420 / -6.60 / -17.77507,600338,400169,20094 / 2388 30 / 762 39 / 991325 / 1230 195 / 567 40 / 4.420 / -6.60 / -17.77642,600428,400214,200119 / 3023 30 / 762 39 / 991500 / 1892 300 / 1135 40 / 4.420 / -6.60 / -17.77792,540528,360264,180119 / 3023 37 / 940 46 / 1168850 / 3217 510 / 1930 40 / 4.420 / -6.60 / -17.771,217,700811,800405,900165 / 4191 41 / 1041 50 / 12701,000 / 3785 600 / 2271 40 / 4.420 / -6.60 / -17.771,416,960944,640472,320192 / 4877 41 / 1041 50 / 1270NOTE: Vertical tanks smaller than 120 pounds should be paralleled together to provide enough fuel to the generator.Table 15. Fuel Required for Common AppliancesAppliance Approximate Input BTU/hrWarm air furnaceSingle familyMultifamily (per unit)60,000–120,00040,000–60,000Hydronic boiler, space heatingSingle familyMultifamily (per unit)80,000–140,00050,000–80,000Hydronic boiler, space and water heatingSingle familyMultifamily (per unit)100,000–200,00050,000–100,000Range, free standing, domestic 50,000–90,000Built-in oven or broiler unit, domestic 14,000–16,000Built-in top unit, domestic 40,000–85,000Water heater, automatic storage30 to 40 gal tank50 gal tank25,000–50,00030,000–55,000Water heater, automatic storage, instantaneous2.5 gpm3 gpm4 gpm115,000–125,000125,000–150,000155,000–200,000Water heater, domestic, circulating or side-armRefrigerator 1,500–2,000Clothes dryer, type 1 (domestic) 18,000–22,000Gas fireplace direct vent 20,000–90,000Gas log 35,000–90,000Barbecue 40,000–80,000Gas light 1,400–2,800

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Generator Sizing Guide 11Table 16. Generator Fuel Consumption – GaseousGenerator kW RatingFuel Consumption at 100% BTU/hr Fuel Consumption at 50% BTU/hrLP Vapor NGLP Vapor NG LP Vapor NGBTU/hr Gal/hr BTU/hr BTU/hr Gal/hr BTU/hrAir-cooled7.5 6 129,000 1.42 117,000 79,000 0.87 73,00010 9 135,000 1.48 127,000 90,000 0.97 101,00013 13 223,000 2.45 225,000 140,000 1.54 154,00014 14 279,000 3.07 256,000 165,000 1.81 195,00015 ECO 15 ECO 251,000 2.76 278,000 167,000 1.84 195,00016 16 272,000 2.99 245,000 155,000 1.70 182,00018 17 275,000 3.02 247,000 155,000 1.70 169,00020 18 324,000 3.56 301,000 216,000 2.38 204,00020-3Ph. 17-3Ph. 324,000 3.56 307,000 217,000 2.39 219,00022/24 19.5/21 355,000 3.87 327,000 230,000 2.56 228,00026 22.5 330,000 3.63 333,000 187,000 2.06 188,000Liquid-cooled22 22 313,000 3.4 332,000 188,000 2.1 200,00025 25 430,000 4.7 452,000 289,000 3.3 312,00027 25 358,000 3.9 377,000 195,000 2.1 207,00030 30 493,000 5.4 517,000 320,000 3.5 336,00032 32 415,000 4.6 394,000 243,000 2.7 237,00036 36 725,000 8.0 767,000 378,000 4.2 399,00038 38 463,000 5.2 459,000 257,000 2.9 268,00045 45 725,000 8.0 767,000 378,000 4.2 399,00048 48 601,000 6.6 634,000 378,000 4.2 353,00060 (3600 rpm) 60 (3600 rpm) 818,000 9.0 905,000 458,000 5.0 507,00060 (1800 rpm) 60 (1800 rpm) 764,000 8.4 848,000 403,000 4.4 454,00075 80 983,000 10.8 1,116,000 522,000 5.7 561,000100 96 906,000 13.4 1,148,000 550,000 8.1 667,000130 130 1,237,000 17.6 1,555,000 701,000 10.7 858,000140 150 1,409,000 19.8 1,768,000 771,000 11.8 963,000Table 17. Generator Fuel Consumption – DieselSize (kW)% of Rated LoadGal/hr L/hrExtended Tank Up-Sized TankTotal Capacity (gal / L) Usable Capacity (gal / L) Total Capacity (gal / L)Usable Capacity (gal / L)1525% 0.51 1.9333.5 G 127 L32 G121 L98.5 G 372.9 L95 G359.6 L50% 0.79 2.9975% 1.14 4.31100% 1.48 5.582025% 0.77 2.933.5 G 127 L32 G121 L98.5 G 372.9 L95 G359.6 L50% 1.03 3.975% 1.46 5.53100% 1.97 7.463025% 0.97 3.6761 G233 L57 G215 L138.5 G524 L132 G500 L50% 1.37 5.1975% 1.97 7.46100% 2.77 10.4945/5025% 1.35 5.1162 G234.7 L57 G215 L138.5 G524 L132 G500 L50% 2.15 8.1475% 3.06 11.58100% 3.98 15.07

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12 Generator Sizing GuideUPS – Generator CompatibilityPassive (also referenced as standby or off-line) and Line-InteractiveThese technologies are most common for personal workstations and point of sale applications. They are typically sin-gle-phase units with size ranges of 350–2,000 VA for passive, and 500–5,000 VA for line-interactive.Passive UPS systems are the simplest type. Under normal conditions, AC power passes straight through to the UPSload. When the input power supply goes outside of specifications, the UPS transfers load from input power to the inter-nal DC to AC power inverter. Passive UPS systems do not correct for voltage or frequency deviations under “normal”operation.Line-interactive is similar to passive technology except it has circuitry which attempts to correct for standard voltagedeviations. Frequency deviations under “normal” power operation are not corrected.Equipment NotesThese devices tend to be electrically / harmonically noisy. A single small UPS is not a significant concern, but applica-tions with multiple UPS systems can be problematic.Passive UPS technology typically has normal tolerances of 10–25% on voltage and 3 Hz on frequency. MinutemanUPS input tolerance is closer to 10–36%. UPS will switch to UPS battery source if input source goes outside of thesetolerances. Some line-interactive units may have frequency tolerances factory set to 0.5 Hz. These units will need tohave the frequency tolerance increased to a minimum of 2 Hz. Minuteman UPS products are closer to 5 Hz and not 0.5hertz.Generator Sizing RecommendationLimit total UPS loading to 15–20% of the generator capacity.Double-Conversion (also referenced as on-line)This technology is most common for critical load applications. Double-conversion UPS systems constantly rectify AC toDC and then invert the DC back into AC. This configuration results in an output which corrects for voltage and fre-quency deviations.There are single and three-phase models covering small to large applications. Most UPS applications larger than 5,000VA use double conversion technology. This approach is also the preferred technology for generator applications.Equipment NotesSingle-phase or unfiltered three-phase double conversion UPS systems tend to create a significant level of electrical/harmonic noise. This is illustrated by harmonic current distortions greater than 35%. Minuteman UPS products couldhave current distortion of 8%. When three-phase models are supplied with harmonic filters (current distortion less than10%), this concern is no longer an issue.Generator Sizing RecommendationSingle-phase models: limit total UPS loading to 25% of the generator capacity.Single-phase Minuteman UPS models: limit total UPS loading to 50% of the generator capacity.Three-phase models without filters (current distortion > 30%): limit UPS loading to 35% of the generator capacity.Three-phase models with filters (current distortion < 10%): limit UPS loading to 80% of the generator capacity.UPS Information2 x kVA rating for a filtered system3-5 x kVA rating for an unfiltered systemNOTE: Ferrups and Delta-Conversion UPS technologies not included in discussion.Supplier(s) Passive (Standby) Line-Interactive Double-ConversionMinuteman UPS Enspire Enterprise Plus EndeavorAPC Back-UPS Series Smart-UPS Series Symmetra SeriesLiebert PowerSure PST & PSP PowerSure PSA & PSI UPStation & NfinityPowerware 3000 series 5000 series 9000 series

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Generator Sizing Guide 13UPS – Generator Compatibility Sizing Examples• UPS systems create electrical or harmonic noise, which needs to be taken into consideration when sizing agenerator.• The generator alternator has to be sized large enough to accept the Total UPS Load from the connected UPSsystems.• Undersizing the generator can cause damage to the UPS equipment, connected equipment, and/or generator.Sizing Formula For UPS SystemsNumber of Systems X VA Rating X Harmonic Multiplier X Generator Multiplier = Minimum Alternator SizeSingle-phase generator backing up three, 2,500 VA Line-Interactive UPS Systems with a Harmonic Multiplier of 3* Generator range is 80–100 kW depending on any voltage and frequency adjustments with the UPS system.Three-phase generator backing up four, 10,000 VA Double Conversion UPS Systems with a Harmonic Multiplier of 2Sizing Notes:• Always contact the UPS manufacturer when in doubt of the Harmonic Multiplier for the UPS system.• Always use the full VA rating of the UPS system for sizing calculations.• Limit Total UPS loading on single-phase generators to 25% of the generators capacity.• Limit Total UPS loading on three-phase generators to 80% of the generators capacity.Number of UPS Systems 3VA Rating 2,500Harmonic Multiplier 3Total UPS Load 22,500 VAGenerator Multiplier 4 (25% of the generator capacity)Minimum Generator Alternator Size *90,000 VANumber of UPS Systems 4VA Rating 10,000Harmonic Multiplier 2Total UPS Load 80,000 VAGenerator Multiplier 1.25 (80% of the generator capacity)Minimum Generator Alternator Size 100,000 VA

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14 Generator Sizing GuideTable 18. NEC (700, 701, 702) ComparisonArticle 700 - Emergency Article 701 - Standby Article 702 - Optional StandbyScope Life safety Legally required critical support (fire fighting, health hazards, etc)Protect property & facilitiesEquipment approval For Emergency / (UL2200) For Intended Use / (UL2200) For Intended Use / (UL2200) / Not in 2008TestingWitness Testing (on-sight) At install & periodically At install NonePeriodic testing Yes Yes NoneBattery maintenance Yes Yes NoneMaintenance records Yes Yes NoneLoad testing Yes Yes NoneCapacity All Loads All loads intended to operate at one timeAll loads intended to operate at one timeOther standby loads allowed Yes with load shedding Yes with load shedding Yes with load managementPeak shaving allowed Yes Yes YesTransfer SwitchAutomatic Yes Yes NoEquipment approval For Emergency / (UL1008) For Standby / (UL1008) Optional standby / (UL1008)Means to permit bypass Yes No NoElect. operated - mech. held Yes No NoMax. fault current capable Yes Yes YesSignals (Audible & Visual)Malfunction Yes / Standard common alarm Yes / Standard common alarm Yes / Standard common alarmCarrying load Yes / Displayed at ATS Yes / Displayed at ATS Yes / Displayed at GeneratorBattery charger failed Yes Yes NoGround fault indication Yes (480V & 1000A) No NoNFPA 110 signaling Yes / Optional annunciator Yes / Optional annunciator NoSignsAt service Yes / Type and location Yes / Type and location Yes / Type and locationAt neutral to ground bonding Yes (if remote) Yes (if remote) Yes (if remote)Wiring kept independent Yes Yes NoFire protection (ref 700-9d) Yes (1000 persons or 75' building)No NoMaximum power outage 10 sec 60 sec N/ARetransfer delay 15 min setting 15 min setting NoAutomatic starting Yes Yes NoOn-site fuel requirements See NFPA 110 See NFPA 110 NoneBattery charger Yes Yes NoGround fault Indication only No No

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Generator Sizing Guide 15Electrical Formulas, Weights and MeasuresExplanation Of Scientific NotationScientific Notation is simply a way of expressing very large orvery small numbers in a more compact format. Any number canbe expressed as a number between 1–10, multiplied by apower of 10 (indicating the correct position of the decimal pointin the original number). Numbers greater than 10 have positivepowers of 10, and numbers less than 1 have negative powersof 10.Example: 186,000 = 1.86 x 105 0.000524 = 5.24 x 10-4Useful Conversions / Equivalents1 BTU................................Raises 1 lb of water 1 °F1 GRAM CALORIE ...........Raises 1 g of water 1 °C1 CIRCULAR MIL..............Equals 0.7854 Square mil1 SQ. MIL..........................Equals 1.27 cir. mils1 MIL.................................Equals 0.001 inTo determine circular mil of a conductor:ROUND CONDUCTOR ...CM = (Diameter in mils)2BUS BAR .........................CM = Width (mils) x Thickness (mils)0.7854NOTES: 1 Millimeter = 39.37 Mils1 Cir. Millimeter = 1550 Cir. Mils1 Sq. Millimeter = 1974 Cir. MilsTo Find Known Values Single-phase Three-phaseKilowatts (kW) Volts, Current, Power FactorE X I1000E x I x 1.73 x PF1000KVA Volts, CurrentE x I1000E x I x 1.731000Amperes kW, Volts, Power FactorkW x 1000EkW x 1000E x 1.73 x PFWatts Volts, Amps, Power Factor Volts x Amps E x I x 1.73 x PFNo. of Rotor Poles Frequency, Rpm2 x 60 x FrequencyRPM2 x 60 x FrequencyRPMFrequency Rpm, No. of Rotor PolesRPM x Poles2 x 60RPM x Poles2 x 60Rpm Frequency, No. of Rotor Poles2 x 60 x FrequencyRotor Poles2 x 60 x FrequencyRotor PoleskW (required for Motor) Motor Horsepower, EfficiencyHP x 0.746EfficiencyHP x 0.746EfficiencyResistance Volts, AmperesEIEIVolts Ohm, Amperes I x R I x RAmperes Ohms, VoltsERERE = Volts I = Amperes R = Resistance (Ohms) PF = Power FactorMETRIC DESIGNATOR AND TRADE SIZESMETRIC DESIGNATOR 12 16 21 27 35 41 53 63 78 91 103 129 1553/8 1/2 3/4 1 1-1/4 1-1/2 2 2-1/2 3 3-1/2 4 5 6TRADE SIZESTable 19. U.S. Weights & Measures / Metric Equivalent ChartIn Ft Yd Mi Mm Cm M Km1 Inch = 1 0.0833 0.0278 1.578x10-525.4 2.54 0.0254 2.54x10-51 Foot = 12 1 0.333 1.894x10-1304.8 30.48 0.3048 3.048x10-41 Yard = 36 3 1 5.6818x10-4914.4 91.44 0.9144 9.144x10-41 Mile = 63360 5280 1760 1 1,609,344 160,934.40 1609.344 1.6093441 mm = 0.03937 0.0032808 1.0936x10-36.2137x10-71 0.1 0.001 0.0000011 cm = 0.3937 0.0328084 0.0109361 6.2137x10-610 1 0.01 0.000011 m = 39.37 3.28084 1.09361 6.2137x10-41000 100 1 0.0011 km = 39370 3280.84 1,093.61 0.62137 1.000.000 100,000 1,000 1In = Inches Ft = Foot Yd = Yard Mi = Mile Mm = Millimeter Cm = Centimeter M = Meter Km = Kilometer

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16 Generator Sizing GuideU.S. Weights And MeasuresLinear Measure= 1 INCH = 2.540 CENTIMETERS12 INCHES = 1 FOOT = 3.048 DECIMETERS3 FEET = 1 YARD = 9.144 DECIMETERS5.5 YARDS = 1 ROD = 5.029 METERS40 RODS = 1 FURLONG = 2.018 HECTOMETERS8 FURLONGS = 1 MILE = 1.609 KILOMETERSMile Measurements1 STATUTE MILE = 5,280 FEET1 SCOTS MILE = 5,952 FEET1 IRISH MILE = 6,720 FEET1 RUSSIAN VERST = 3,504 FEET1 ITALIAN MILE = 4,401 FEET1 SPANISH MILE = 15,084 FEETOther Linear Measurements1 HAND = 4 INCHES 1 LINK = 7.92 INCHES1 SPAN = 9 INCHES 1 FATHOM = 6 FEET1 CHAIN = 22 YARDS 1 FURLONG = 10 CHAINS1 CABLE = 608 FEETSquare Measure144 SQUARE INCHES = 1 SQUARE FOOT9 SQUARE FEET = 1 SQUARE YARD30 1/4 SQUARE YARDS = 1 SQUARE ROD40 RODS = 1 ROOD4 ROODS = 1 ACRE640 ACRES = 1 SQUARE MILE1 SQUARE MILE = 1 SECTION36 SECTIONS = 1 TOWNSHIPCubic Or Solid Measure1 CUBIC FOOT = 1728 CUBIC INCHES1 CUBIC YARD = 27 CUBIC FEET1 CUBIC FOOT = 7.48 GALLONS1 GALLON (WATER) = 8.34 LBS.1 GALLON (U.S.) = 231 CUBIC INCHES OF WATER1 GALLON (IMPERIAL) = 277 1/4 CUBIC INCHES OF WATERMetric SystemPrefixesA. MEGA = 1,000,000 E. DECI = 0.1B. KILO = 1,000 F. CENTI = 0.01C. HECTO = 100 G. MILLI = 0.001D. DEKA = 10 H. MICRO = 0.000001Linear Measure(THE UNIT IS THE METER = 39.37 INCHES)8 FURLONGS = 1 MILE = 1.609 KILOMETERS1 CENTIMETER = 10 MILLIMETERS = 0.3937011 INCH1 DECIMETER = 10 CENTIMETERS = 3.9370113 INCHES1 METER = 10 DECIMETERS = 1.0936143 YARDS= 3.2808429 FEET1 DEKAMETER = 10 METERS = 10.936143 YARDS1 HECTOMETER = 10 DEKAMETERS = 109.36143 YARDS1 KILOMETER = 10 HECTOMETERS = 0.62137 MILE1 MYRIAMETER = 10,000 METERSSquare Measure(THE UNIT IS THE SQUARE METER = 1549.9969 SQUARE INCHES)1 SQ. CENTIMETER = 100 SQ. MILLIMETERS = 0.1550 SQ. INCH1 SQ. DECIMETER = 100 SQ. CENTIMETERS = 15.550 SQ. INCHES1 SQ. METER = 100 SQ. DECIMETERS = 10.7639 SQ. FEET1 SQ. DEKAMETER = 100 SQ. METERS = 119.60 SQ. YARDS1 SQ. HECTOMETER = 100 SQ. DEKAMETERS1 SQ. KILOMETER = 100 SQ. HECTOMETERS(THE UNIT IS THE “ARE” = 100 SQUARE METERS)1 CENTIARE = 10 MILLIARES = 10.7643 SQ. FEET1 DECIARE = 10 CENTIARES = 11.96033 SQ. YARDS1 ARE = 10 DECIARES = 119.6033 SQ. YARDS1 DEKARE = 10 ARES = 0.247110 ACRES1 HEKTARE = 10 DEKARES = 2.471098 ACRES1 SQ. KILOMETER = 100 HEKTARES = 0.38611 SQ. MILECubic Measure(THE UNIT IS THE “STERE” = 61,025.38659 CUBIC INCHES)1 DECISTERE = 10 CENTISTERES = 3.531562 CUBIC FEET1 STERE = 10 DECISTERES = 1.307986 CUBIC YARDS1 DEKASTERE = 10 STERES = 13.07986 CUBIC YARDSCubic Measure(THE UNIT IS THE METER = 39.37 INCHES)1 DECISTERE = 10 CENTISTERES = 3.531562 CU. FEET1 CU. CENTIMETER = 1000 CU. MILLIMETERS = 0.06102 CU. INCH1 CU. DECIMETER = 1000 CU. CENTIMETERS = 61.02374 CU. INCH1 CU. METER = 1000 CU. DECIMETERS = 35.31467 CU. FEET= 1 STERE = 1.30795 CU. 1 CU. CENTIMETER (WATER) = 1 GRAM1000 CU. CENTIMETERS (WATER) = 1 LITER = 1 KILOGRAM1 CU. METER (1000 LITERS) = 1 METRIC TONMeasures Of Weight(THE UNIT IS THE GRAM = 0.035274OUNCES)1 MILLIGRAM = = 0.015432GRAINS1 CENTIGRAM = 10 MILLIGRAMS = 0.15432 GRAINS1 DECIGRAM = 10 CENTIGRAMS = 1.5432 GRAINS1 GRAM = 10 DECIGRAMS = 15.4323 GRAINS1 KILOGRAM = 10 HECTOGRAMS = 2.2046223 POUNDS1 MYRIAGRAM = 10 KILOGRAMS = 22.046223 POUNDS1 QUINTAL = 10 MYRIAGRAMS = 1.986412 CWT.1 METRIC TON = 10 QUINTAL = 2204.622/621849 POUNDS1 GRAM = 0.56438 DRAMS1 DRAM = 1.77186 GRAMS= 27.3438 GRAINSMETRIC TON = 2,204.6223 POUNDSMeasures Of Capacity(THE UNIT IS THE LITER = 1.0567 LIQUID QUARTS)1 CENTILITER = 10 MILLILITERS = 0.338 FLUID OUNCES1 DECILITER = 10 CENTILITERS = = 3.38 FLUID OUNCES1 LITER = 10 DECILITERS = 33.8 FLUID OUNCES1 DEKALITER = 10 LITERS = 0.284 BUSHEL1 HECTOLITER = 10 DEKALITERS = 2.84 BUSHELS1 KILOLITER = 10 HECTOLITERS = 264.2 GALLONSNOTE: KILOMETERS x 5 = MILES or MILES x 8 = KILOMETERS8 5

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Generator Sizing Guide 17Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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18 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method1. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.2. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.3. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)4. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).5. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 19Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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20 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 21Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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22 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 23Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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24 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method6. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.7. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.8. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)9. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).10. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 25Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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26 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 27Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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28 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 29Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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30 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method11. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.12. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.13. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)14. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).15. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 31Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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32 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 33Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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34 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 35Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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36 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method16. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.17. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.18. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)19. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).20. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 37Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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38 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 39Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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40 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 41Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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42 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method21. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.22. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.23. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)24. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).25. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 43Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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44 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 45Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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46 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 47Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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48 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method26. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.27. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.28. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)29. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).30. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 49Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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50 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 51Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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52 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

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Generator Sizing Guide 53Selected Circuit Load CalculatorBefore installation, contact local jurisdiction to verify all requirements are met. Jurisdictions may vary.LOADS: Inspect for heavy building loads such as refrigeration, air conditioning, pumps, or UPS systems.Use the following for sizing and determining generator kW.Recommended Generator Size ____________ See Generator Sizing Instructions on other side of this sheet.Contractor ___________________________________ Email _______________________________________ Phone ______________________________________ Fax _________________________________________Job Name ___________________________________________________________________________________Date ________________________________________ Location _____________________________________ VOLTAGE 120/240 1ø 120/208 3ø 120/240 3ø 277/480 3øTYPE Natural Gas LP Vapor (LPV)ELEC. SERVICE 100 Amp 150 Amp 200 Amp 300 Amp400 Amp 600 Amp Other ________Worksheet 1. Motor LoadsDevice HP RA LRA kW Running (= HP) Starting kW**See Table 430.7(B) for starting kVA per HP for motor loads.Worksheet 2. Non-Motor LoadsTo Calculate kWDevice Amps kW120 V 1ø Amps x 120 / 1000 = kW240 V 1ø Amps x 240 / 1000 = kW208 V 3ø (Amps x 208 x 1.732 x PF) / 1000 = kW240 V 3ø (Amps x 240 x 1.732 x PF) / 1000 = kW480 V 3ø (Amps x 480 x 1.732 x PF) / 1000 = kWInstall Notes:1. See manual for installation recommendations.2. Contact AHJ for local requirements.

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54 Generator Sizing GuideGenerator Sizing InstructionsThere are multiple ways to size a generator. The follow-ing are methods which, when combined with good judg-ment, should result in an appropriately sized generator.Remember to consider load growth, seasonality, andeffects of starting motors.As municipalities and states adopt the new 2020 NECElectrical Code, there may be new sizing requirementswhich the installation technician must follow. Consult withthe local inspection department to verify which codecycle will affect the installation.Never add amps when sizing a generator. Convert ampsto kW and add kW to determine the required generatorsize. Power factors for various motor loads vary widely.Adding amps without correctly accounting for the powerfactor and/or mixing voltages will result in incorrectly siz-ing the generator.When a motor starts, a current surge is created that steploads the generator and causes a voltage dip. Afterselecting a generator, see the generator's surge capabil-ity using Table 5, Table 6, and Table 7. Verify voltage dipis adequate for the application. Most commercial applica-tions should be limited to approximately 15% voltage dip,and residential applications should be limited to a 30%voltage dip.Some applications utilize an uninterruptible power supply(UPS) to back up critical loads. See UPS – GeneratorCompatibility for this load type.Measurement Method 220.87 Exception 2020 NECConnect a recording ammeter or power meter capable ofmeasuring maximum peak kW demand continuouslyover a minimum 30 day period. The maximum kWdemand shall be taken while the building is occupied andshall include the larger of the heating or cooling loads.The peak kW demand shall be multiplied by 125%.Peak kW demand X 125% = Calculated kW demandSize the generator to the next standard size and verifyUPS and motor load compatibility.Determining Existing Loads/Billing History Method 220.87 2020 NECMany customers have a utility rate structure that has apeak demand charge. Using a year's worth of electricbills, size the generator 25% larger than the largest peakdemand. Verify motor and UPS load compatibility. Peak Demand = _______Load Summation Method31. Enter running kW for all motor loads (except thelargest) expected to run during peak load levelsinto the Worksheet 1. See Table 1 and Table 2 fortypical motor load sizes and electrical require-ments.32. Enter kW for all non-motor loads expected to runduring peak load levels into Worksheet 2. SeeTable 3 for typical residential loads and rules ofthumb.33. Add the running motor load kW, non-motor loadkW, and the starting kW of the largest motor load.Select generator: Commercial (add 20 to 25% to total kW)Residential (add 10 to 20% to total kW)34. Verify voltage dip is within acceptable limits bycomparing motor LRA to generator surge capability(see Table 5, Table 6, and Table 7).35. Verify UPS compatibility (see UPS – GeneratorCompatibility).System Capacity – Load CalculationIf the local municipality or state the installation is in hasadopted the 2020 NEC Code, this step may be required.Article 702 of the 2020 NEC includes a new requirementfor sizing (702.4). If no other method for sizing is accept-able, sizing of the generator shall be made in accordancewith Article 220 of the 2020 NEC. Use the system capac-ity estimating sheet as a guide for this process.Smart Management Module 702.4 (B) (2) (a) 2020 NECThe Smart Management Module (SMM) is a contact (50or 100 amp) housed in a NEMA 3R enclosure for indoorand outdoor installation applications. Through the use ofSMM’s in conjunction with any of the 100–600 ampSmart Switches, household or business loads can beintelligently managed, enabling the use of a smaller,more efficient generator system. Up to eight SMM’s canbe used with a single switch.Motor load running total (minus largest motor): (from Worksheet 1) _________________ kW Non-motor load total: (from Worksheet 2) _________________ kW Starting load from largest cycling motor: (from Worksheet 1) _________________ kW Total electrical loads: _________________ kW

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Generator Sizing Guide 55Project LayoutBall Park Estimates (Do not use for final sizing)Estimate based on 60% service size: (Commercial)240 Volts, 1 Ø: ________ Amps x 0.15 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.22 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.25 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.50 = ________ kWEstimate Based On 40% Service Size: (Residential)240 Volts, 1 Ø: ________ Amps x 0.10 = ________ kW208 Volts, 3 Ø: ________ Amps x 0.15 = ________ kW240 Volts, 3 Ø: ________ Amps x 0.17 = ________ kW480 Volts, 3 Ø: ________ Amps x 0.34 = ________ kWEstimate Based On Square FootageAmps to kW Rule of Thumb (assumes 0.8 pf)For 480 volt systems Amps = kW x 1.5For 208 volt systems Amps = kW x 3.5For 240 volt 3 Ø systems Amps = kW x 3For 240 volt 1 Ø systems Amps = kW x 4Fast food, convenience stores, restaurants, grocery storeskW = 50 kW + 10 watts/sq. ft.Other commercial applicationskW = 30 kW + 5 watts/sq. ft.Square footage = ______ Estimated kW = ______

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56 Generator Sizing GuideSystem Capacity – Load CalculatorDirections for 2020 NEC, Article 220, Part IV220.80 Optional Feeder and Service Load Calculations (RESIDENTIAL) NEC REFERENCE SECTION CAN BE USED FOR DWELLING UNITS 220.82 (A)• Served by a single feeder conductor (generator)• 120/240 volt or 208Y/120 volt service• Ampacity of 100 amps or greaterThe calculated load will be the result of adding• 220.82 (B) General Loads, and• 220.82 (C) Heating and Air-Conditioning Load 220.82 (C)GENERAL LOADS 220.82 (B)General Lighting and General-Use Receptacles• Calculate at 3 VA per square foot 220.82 (B) (1)– Use exterior dimensions of the home to calculate square footage - do not include open porches, garages, or unused or unfinished spaces not adaptable for future use.• Add 20-amp small appliance & laundry circuits @ 1500 VA each 220.82 (B) (2)• Calculate the following loads at 100% of nameplate rating 220.82 (B) (3)• Appliances fastened in place, permanently connected or located on a specific circuit 220.82 (B) (3) a– Ranges, wall-mounted ovens, counter-mounted cooking units 220.82 (B) (3) b• Clothes dryers not connected to the laundry branch circuit 220.82 (B) (3) c• Water heaters 220.82 (B) (3) d• Permanently connected motors not included in Heat & Air-Conditioning Load section 220.82 (B) (4)HEATING & AIR-CONDITIONING LOADS 220.82 (C)Include the largest of the following six selections (kVA load) in calculation Air Conditioning and Cooling 220.82 (C) (1)• 100% of nameplate ratingHeat Pumps without Supplemental Electric Heating 220.82 (C) (2)• 100% of nameplate ratingHeat Pumps with Supplemental Electric Heating 220.82 (C) (3)• 100% of nameplate rating of the heat pump compressor*• 65% of nameplate rating of supplemental electric heating equipment– If compressor & supplemental heat cannot run at the same time do not include the compressorElectric Space Heating• Less than four separately controlled units @ 65% of nameplate rating 220.82 (C) (4)• Four or more separately controlled units @ 40% of nameplate rating 220.82 (C) (5)• 40% of nameplate rating if using four or more separately controlled units Electric Thermal Storage (or system where the load is expected to be continuous at nameplate rating 220.82 (C) (6)• 100% of nameplate rating• Systems of this type cannot be calculated under any other section of 220.82 (C).LOAD CALCULATIONSGeneral Lighting Load 3 VA x ft2• Small Appliance & Laundry Circuits + 1500 VA per circuit• General Appliances & Motors (100% rated load) + Total general appliances• Sum of all General Loads = Total General Load (VA)APPLY DEMAND FACTORS– First 10 kVA@ 100% = 10,000 VA– Remainder of General Loads @ 40% (Total VA- 10,000) x 0.40= Calculated General Load (VA)• HEAT / A-C LOAD @ 100% Largest Heat or A-C Load (VA)= TOTAL CALCULATED LOADConverting VA to kW (Single-phase applications with 1.0 power factor only) 1 kVA = 1 kW 220.54

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Generator Sizing Guide 57Worksheet — 2020 NEC, 220 Part IV GENERAL LOADS Qty Rating (Load) Factor Loads (VA)Loads (kW)(VA ÷ 1,000)General Lighting and General Use Receptacles 3 VA/ft² 100%Branch Circuits (1500 VA/ft²)Small Appliance Circuits (20 Amp) 1500 100%Laundry Circuits 1500 100%Fixed Appliances Full Current RatingWell 100%Sump Pump 100%Freezer 100%Microwave (Not counter-top model) 100%Disposal 100%Dishwasher 100%Range 100%Wall-Mounted Oven 100%Counter-Mounted Cooking Surface 100%Water Heater 100%Clothes Dryer 100%Garage Door Opener 100%Septic Grinder 100%Other (list) 100%100%100%100%100%100%100%100%100%Total General Loads VA kWHEAT / A-C LOADA-C / Cooling Equipment 100%Heat Pump• Compressor (if not included as A-C) 100%• Supplemental Electric Heat 65%Electric Space Heating• Less than four separately controlled units 65%• Four or more separately controlled units 40%System With Continuous Nameplate Load 100%Largest Heat / A-C Load (VA) VA kWGeneral Loads• 1st 10 kW of General Loads 100% kW 100% kW• Remaining General Loads (kW) 40% kW 40% kWCalculated General Load (kW) kW kWLargest Heat / A-C Load 100% kW kW kWTotal Calculated Load (Net General Loads + Heat/A-C Load) kW

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58 Generator Sizing GuideNotes__________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________

Generac Generator Sizing Guide

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