oVerify the product version by means of the type code on the nameplate. See chapter Nameplate and chapter Type Code.
oPrior to mounting, inspect the product for visible damage.
Damaged products may cause electric shock or unintended equipment operation.
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ELECTRIC SHOCK OR UNINTENDED EQUIPMENT OPERATION |
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oDo not use damaged products. oKeep foreign objects (such as chips, screws or wire clippings) from getting into the product. |
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Failure to follow these instructions will result in death or serious injury. |
Contact your local Schneider Electric sales office if you detect any damage whatsoever to the products.
Inspecting the Holding Brake (Option)
See chapter Inspecting/Breaking In the Holding Brake.
The shaft extensions are factory-treated with an anti-corrosive. If output components are glued to the shaft, the anti-corrosive must be removed and the shaft cleaned. If required, use a grease removal agent as specified by the glue manufacturer. If the glue manufacturer does not provide information on grease removal, acetone may be used.
oRemove the anti-corrosive. Avoid direct contact of the skin and the sealing parts with the anti-corrosive or the cleaning agent.
The mounting surface must be stable, clean, deburred and low-vibration. Ensure that the mounting surface is itself grounded, and that a potential exists between the motor flange and the mounting surface.
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ELECTRIC SHOCK CAUSED BY INSUFFICIENT GROUNDING |
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oVerify compliance with all local and national electrical code requirements as well as all other applicable regulations with respect to grounding of the entire drive system. oGround the drive system before applying voltage. oDo not use conduits as protective ground conductors; use a protective ground conductor inside the conduit. oThe cross section of the protective ground conductor must comply with the applicable standards. oDo not consider cable shields to be protective ground conductors. |
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Failure to follow these instructions will result in death or serious injury. |
Verify that the mounting surface meets the requirements in terms of dimensions and tolerances in this document.
Conductor Cross Sections According to Method of Installation
The following sections describe the conductor cross sections for two methods of installation:
oMethod of installation B2:
Cables in conduits or cable trunking systems
oMethod of installation E:
Cables on open cable trays
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Cross section in mm2 (AWG) |
Current-carrying capacity with method of installation B2 in A1) |
Current carrying capacity with method of installation E in A1) |
|---|---|---|
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0.75 (18) |
8.5 |
10.4 |
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1 (16) |
10.1 |
12.4 |
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1.5 (14) |
13.1 |
16.1 |
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2.5 (12) |
17.4 |
22 |
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4 (10) |
23 |
30 |
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6 (8) |
30 |
37 |
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10 (6) |
40 |
52 |
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16 (4) |
54 |
70 |
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25 (2) |
70 |
88 |
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1) Values as per IEC 60204-1 for continuous operation, copper conductors and ambient air temperature 40°C (104 °F); see IEC 60204-1 for additional information. |
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Note the derating factors for grouping of cables and correction factors for other ambient conditions (IEC 60204-1).
The conductors must have a sufficiently large cross section so that the upstream fuse can trip.
In the case of longer cables, it may be necessary to use a greater conductor cross section to reduce the energy losses.
