| INSTALLATION | |||
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ELECTRODE AND WORK |
| For parallel applications with excessive electrode | ||
CONNECTIONS |
| cable lengths, a common bus connection should be | ||
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| used. The common electrode connection serves to | |
General Guidelines |
| minimize voltage drops associated with resistive loss- | ||
| es in the electrode path. It should be made of copper, | |||
The unique switching structure of the Power Wave | and located as close as possible to the power | |||
AC/DC 1000 allows it to produce DC positive, DC | sources. (See "Connection Diagram – Parallel | |||
negative or AC output waveforms without reposition- | Machines") |
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ing the work and electrode leads. Additionally, no DIP |
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switch changes are required to switch between the dif- | Work Connections |
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ferent polarities. All of this is controlled internally by | Connect a work lead of sufficient size and length (Per | |||
the Power Wave AC/DC 1000, and based exclusively | Table 1) between the "work" stud (located beneath the | |||
on the weld mode selection. |
| spring loaded output cover on the top, front of the | ||
The following recommendations apply to all output | machine) and the work piece. For convenience, the | |||
work lead can be routed along the left cable tray, and | ||||
polarities and weld modes: |
| out the back of the machine. Be sure the connection | ||
• Select the appropriate size cables per the | to the work makes tight | |||
tact. |
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"Output Cable Guidelines" below. Excessive volt- |
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age drops caused by undersized welding cables | For parallel and/or multiple arc applications with | |||
and poor connections often result in unsatisfactory | excessive ground path lengths, a common work con- | |||
welding performance. Always use the largest weld- | nection bus should be used. The common work con- | |||
ing cables (electrode and work) that are practical, | nection serves to minimize voltage drops associated | |||
and be sure all connections are clean and tight. | with resistive losses in the ground paths. It should be | |||
Note: Excessive heat in the weld circuit indicates | made out of copper, and located as close as possible | |||
to the power sources (See Common Connection | ||||
| undersized cables and/or bad connections. | Diagram). |
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• Route all cables directly to the work and wire | Common Connection Diagram | |
feeder, avoid excessive lengths and do not coil | ||
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excess cable. Route the electrode and work cables |
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in close proximity to one another to minimize the |
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loop area and therefore the inductance of the weld |
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circuit. |
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•Always weld in a direction away from the work (ground) connection.
TABLE A.1 - Output Cable Guidelines | COMMON CONNECTION | |||
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Total Cable Length |
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| (LOCAT ED CLOSE TO |
ft (m) | Duty Cycle | Number of | Cable Size | POWER SOURCES) |
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Electrode and Work |
| Parallel Cables | Copper |
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Combined |
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| WORK PIECE |
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0 (0) to 250 (76.2) | 80% | 2 | 4/0 (120 mm2) |
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0 (0) to 250 (76.2) | 100% | 3 | 3/0 (95 mm2) |
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Electrode Connections
Connect an electrode cable of sufficient size and length (Per Table A.1) to the "electrode" stud on the power source (located behind the cover plate on the lower left side). For convenience, the cable can be routed down through the two holes in the left cable tray before being connected to the output terminals. Connect the other end of the electrode cable to the wire drive feed plate on the wire feeder. Be sure the connection to the feed plate makes tight
POWER WAVE® AC/DC 1000
