Lincoln Electric SVM103-A service manual Table B.3 Generator Power Applications

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B-8

OPERATION

TABLE B.3

GENERATOR POWER APPLICATIONS

 

Suggested Power Applications

Running Watts

*Start-up Watts

 

 

*Air Compressor - 3/4 HP

1,250

3,100 - 5,000

 

 

*Airless Sprayer - 1/3 HP

600

1,500 - 2,400

 

 

Chain Saw 1,200

 

 

 

 

Circular Saw

1,200

 

 

 

Coffee Maker

1,000

 

 

 

*Deep Freezer

500

750 - 2,000

 

 

*Electric Motor - 1 HP

1,000

2,500 - 4,000

 

 

Electric Range (1 element)

1,500

 

 

 

Electric Skillet

1,250

 

 

 

*Furnace Fan - 1/3 HP

1,200

3,000 - 4,800

 

 

Portable Grinder (4 1/2”)

600

 

 

 

Portable Grinder (7”)

2,000

 

 

 

Halogen Work Light

500

 

 

 

Hand Drill - 1/4”

500

 

 

 

Hand Drill - 3/8”

700

 

 

 

1500 Watt Heater

1,750

 

 

 

Hedge Trimmer

450

 

 

 

Light Bulb 100

 

 

 

 

Reciprocating Saw

900

 

 

 

Radial Arm Saw

2,600

 

 

 

Radio 50

 

 

 

 

*Refrigerator/Freezer (small)

600

1,500 - 2,400

 

 

Slow Cooker

200

 

 

 

*Submersible Pump - 1 HP

1,000

2,500 - 4,000

 

 

*Sump Pump

600

1,500 - 2,400

 

 

Toaster 1,100

 

 

 

 

Weed Trimmer

500

 

 

 

Lincoln 100 or 125 Amp Wire Feeder/Welder

4,000

 

 

 

 

 

 

 

NOTES:

Wattages listed are approximate. Check your equipment for actual wattage.

Equipment with unusually high *START-UP WATTS are listed. For start-up of other equipment listed in the table, multiply RUNNING WATTS by 2.

Multiple loads can be used as long as the total load does not exceed 4,000 watts. Be sure to start the largest loads first. For example, a 1 HP motor needs approximately 1,000 watts while running but may require 2,500 watts to start. Some inductive motors may require as much as 4 times running watts to start.

POWER-ARC 4000

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Contents POWER-ARC TM4000 POWER-ARC SafetyElectric Shock can kill Iii Welding Sparks can cause fire or explosionPrécautions DE Sûreté Master Table of Contents for ALL Sections Table of Contents Installation Section Technical Specifications POWER-ARC InstallationStoring Safety PrecautionsLocation and Ventilation PRE-OPERATION Engine Service Cable Size and Length Power ARCElectrical Output Connections Welding Cable ConnectionsPlugs and HAND-HELD Equipment Auxiliary Power ReceptaclesCable Installation Machine GroundingCircuit Breakers Premises WiringType Common Electrical Devices Possible Concerns Table A.2 Electrical Device USE with the POWER-ARCTable of Contents Operation Section General Description Safety InstructionsOperation Operating InstructionsWelding Capability Operational Features and ControlsDesign Features Advantages Recommended ApplicationsGENERATOR/WELDER Controls Controls and SettingsGasoline Engine Controls Figure B.2 Gasoline Engine ControlsStarting the Engine Engine OperationBefore Starting the Engine BREAK-IN Period Stopping the EngineRunning the Engine General Information To USE the Generator AS AN Auxiliary Power SupplyGenerator Operation Table B.3 Generator Power Applications After YOU Finish the Weld To USE the POWER-ARC 4000 for WeldingWelding Operation Stick Welding Material Thickness Electrode Type Size SettingWelding Guidelines ARC Welding CircuitCorrect WAY to Strike AN ARC 12/95 POWER-ARCFour Factors of Successful Welding ElectrodeCorrect Welding Speed Correct ARC LengthTable of Contents Accessories Briggs and Stratton Accessories OPTIONS/ACCESSORIESLincoln Electric Accessories Table of Contents Maintenance Engine Maintenance Routine and Periodic MaintenanceFigure D.2 Clean Rotating SCREEN/FINGER GUARD/DEBRIS Guard Figure D.4 SET Spark Plug GAP Part Part Number Table D.2 Engine Maintenance PartsGENERATOR/WELDER Maintenance Figure D.6. Major Component Locations Table of Contents Theory of Operation Section ENGINE, EXCITATION, Rotor and Stator Theory of OperationFigure E.3 Field Excitation and Auxiliary Power Rotor Field Feedback and Auxiliary PowerWeld Winding and Reactor Auxiliary Power Overcurrent ProtectionTable of Contents Trouble Shooting & Repair Section HOW to USE Troubleshooting Guide Troubleshooting & RepairOutput Problems Troubleshooting GuideOr contact your local Lincoln Local Lincoln Electric Authorized Troubleshooting & Repair Troubleshooting & Repair Engine Problems Engine Problems Welding Problems Materials Needed Rotor Voltage TestTest Description Ground Stud Lead 200A Connection Output Panel Test ProcedureRotor Resistance Test Rings SlipCable TIE Brushes Figure F.3 Brushes Retained with Cable TIEEngine Throttle Adjustment Test Oscilloscope Method MarkStrobe-tach Method Frequency Counter MethodNUT Figure F.5 Location of Engine Throttle Adjustment NUTHigh Idle no Load Scope SettingsNormal Open Circuit Weld Voltage Waveform Normal Open Circuit Voltage Waveform 115 VAC Supply Machine Loaded to 125 Amps AT 23 VAC Typical Weld Output WaveformMachine Loaded Description Brush Removal and ReplacementFigure F.6 Brushes Retained with Cable TIE ProcedureProcedure Rheostat Removal and Replacement Figure F.7 Rheostat Removal Capacitor AND/OR Diode Bridge Removal Replacement Procedure Capacitor Removal and Replacement Capacitor AND/OR Diode Bridge Removal and ReplacementProcedure Diode Bridge Removal and Replacement Instructions STATOR/ROTOR Removal and ReplacementTerminals Stator Removal ProcedureTIE Wrap OutputFigure F.10 Stator END Bracket Support and THRU-BOLTS Thru Bolts Support Nuts POWER-ARCRotor THRU-BOLT Rotor Removal ProcedureReassembly Procedure Rotor Feeler GaugeWELDER/GENERATOR OUTPUT1 Auxiliary Power Receptacle OUTPUT1Retest After Repair Engine OutputPOWER-ARC Section G Table of ContentsElectrical Diagrams POWER-ARC Electrical DiagramPOWER-ARC POWER-ARC