Lincoln Electric IM718 manual Electrode and Work Cable Connections

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A-6

INSTALLATION

A-6

 

 

 

ELECTRODE AND WORK CABLE CONNECTIONS

Due to the PowerWave AC/DC’s ability to produce either a DC positive, DC negative or AC output the electrode and work connections do not need to be reversed for the different polarities. Additionally no DIP switch changes are required to switch between the different polarities. All of this is controlled internally by the Power Wave AC/DC. The following directions apply to all polarities:

Connect a work lead of sufficient size (Per Table 1) and length between the "work" stud (located beneath the spring loaded output cover on the front of the machine) and the work. For convenience, the work lead can be routed behind the left strain relief (under the spring loaded output cover), along the channels, and out the back of the machine. Be sure the connection to the work makes tight metal-to-metal electrical contact. The work piece connection must be firm and secure. Excessive voltage drops caused by poor work piece connections often result in unsatisfactory welding performance, espe- cially if pulse welding is planned. To avoid interference problems with other equipment and to achieve the best possible operation, route all cables directly to the work and wire feeder. Avoid excessive lengths and do not coil excess cable.

Connect the electrode cable between the wire feeder and the "electrode" stud on the power source (located behind the cover plate on the lower right side). For convenience, the cable can be routed through the oval hole in the rear of the machine before being connected to the output ter- minals. Connect the other end of the electrode cable to the wire drive feed plate. Be sure the connection to the feed plate makes tight metal-to-metal electrical contact. The electrode cable should be sized according to the specifications given in (Table A.1).

Suggested Copper Cable Sizes - 100 Duty Cycle Combined Length of Electrode and Work Cables (Table A.1)

Cable Length (ft (m)

Parallel Cables

Cable Size

0 (0) to 100 (30.4)

1

4/0 (120mm2)

100 (30.4) to 200 (60.8)

2

2/0 (70mm2)

200 (60.8) to 250 (76.2)

2

3/0 (95mm2)

When using inverter type power sources like the Power Wave, use the largest welding (electrode and work) cables that are practical. When pulsing, the pulse current can reach very high levels. Voltage drops can become excessive, leading to poor welding characteristics, if undersized welding cables are used. NOTE: K1796 coaxial welding cable is recommended to reduce the cable inductance in long cable lengths. This is especially important when Pulse welding up to 350 amps.

CABLE INDUCTANCE, AND ITS EFFECTS ON PULSE WELDING

For Pulse Welding processes, cable inductance will cause the welding performance to degrade. For the total welding loop length less than 50 feet, traditional welding cables may be used without any effects on welding performance. For the total welding loop length greater than 50 feet, the K1796 Coaxial Welding Cables are recommended.

The welding loop length is defined as the total of elec- trode cable length (A) + work cable length (B) + work length (C) (See Figure A.3).

 

FIGURE A.3

POWER

 

WAVE

A

 

C

WORK

B

For long work piece lengths, a sliding ground should be considered to keep the total welding loop length less than 50 feet. (See Figure A.4.)

 

FIGURE A.4

 

 

POWER

A

 

A

WAVE

 

 

 

 

 

C

WORK

C

B B

SLIDING GROUND

K1796 COAXIAL CABLE

MEASURE FROM END

OF OUTER JACKET OF

CABLE

FOR A DETAILED CONNECTION DIAGRAM USING K1796 COAXIAL CABLE, SEE PAGE F-4.

CAUTION

When pulsing, the pulse current can reach very high levels. Voltage drops can become excessive, leading to poor welding characteristics, if under- sized welding cables are used.

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POWER WAVE AC/DC

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Contents
Power Wave AC/DC Power Wave AC/DC SafetyElectric Shock can kill Iii Welding Sparks can cause fire or explosionSûreté Pour Soudage a L’Arc Précautions DE SûretéThank You Table of Contents Technical Specifications Power Wave AC/DC K1860-1 InstallationHigh Frequency Protection Machine GroundingLifting StackingInput Connection Input Fuse and Supply Wire ConsiderationsTWO Power Waves Welding with Multiple UNSYN- Chronized Power WavesBest Cable INDUCTANCE, and ITS Effects on Pulse Welding Electrode and Work Cable ConnectionsTable A.2 Voltage SensingElectrode Voltage Sensing Ethernet Connections Control Cable SpecificationsHigh Speed Gear BOX External I/O ConnectorEthernet Board DIP Switch Feed Head Board DIP SwitchControl Board DIP Switch Table A.4 Object InstanceDevicenet MAC ID Table A.5 Bank S3 and S4 MULTI-ARC System Description ARCOperation Safety PrecuationsPower Wave AC/DC Definition of Welding Terms Recommended Processes and Equipment General DescriptionRequired Equipment Welder Operation Case Front ControlsMaking a Weld General Welding Adjustments Welding AdjustmentsWelding Mode Volts / TrimCV Welding 7OPERATIONB-7Figure B.3 Pulse WeldingFactory Installed AccessoriesField Installed Options / Accessories Optional EquipmentPeriodic Maintenance MaintenanceCalibration Specification HOW to USE Troubleshooting Guide TroubleshootingContact your local Lincoln Authorized Field Service FacilityRear of the machine Contact your local Lincoln Authorized Field Service Facility Field Service Facility Possible Areas Recommended SymptomsYour local Lincoln Authorized Before the machine is turned off Using the Status LED to Troubleshoot System ProblemsError Code # Indication Error Codes for the PowerwaveLeft Side of Machine Rectifier G4076-2Table F.5 Devicenet Connector S5 PIN, Lead Connector SetupsTable F.4 RS232 Connector S3 Table F.6 External I/O S7Robotic Set Up, Electrode Positive, CV/Pulse Configuration Connection DiagramDimension Print Power Wave AC/DC Power Wave AC/DC $700.00 Basic CoursePrecaucion Warnung