Chapter 5 - installing input power wiring, Hapter, Installing input power wiring – Rockwell Automation GV3000/SE AC Drive 1-20HP, 230VAC Ver. 6.04 Hdwe Ref, Install, Troubleshooting User Manual
Page 43
5-1
I
nstalling Input Power Wiring
C
HAPTER
5
Installing Input Power Wiring
This chapter describes incoming line components and how to install them.
5.1 Installing Transformers and Reactors (Optional)
Input isolation transformers might be needed to help eliminate the following:
•
Damaging line voltage transients from reaching the drive.
•
Line noise from the drive back to the incoming power source.
•
Damaging currents that could develop if a point inside the drive becomes
grounded.
Observe the following guidelines when installing an isolation transformer:
•
A power disconnecting device must be installed between the power line and the
primary of the transformer.
•
If the power disconnecting device is a circuit breaker, the circuit breaker trip
rating must be coordinated with the inrush current (10 to 12 times full load
current) of the transformer.
•
An input isolation transformer rated more than 500 KVA for 230 VAC with less
than 5% impedance should NOT be used directly ahead of the drive without
additional impedance between the drive and the transformer.
ATTENTION: Distribution system capacity above the maximum
recommended system KVA (500 KVA for 230 VAC) requires the use of
an isolation transformer, a line reactor, or other means of adding
similar impedance to the drive power input. Failure to observe these
precautions could result in damage to, or destruction of, the equipment.
ATTENTION: When the AC line is shared directly with other
SCR-rectified drives, an optional snubber resistor braking kit might be
required to alleviate excess DC bus voltage. Failure to observe these
precautions could result in damage to, or destruction of, the equipment.
The GV3000/SE AC line distribution system capacity is 500 KVA, three-phase with
30,000 amps symmetrical fault current capacity with a line impedance of less than
5%. The symmetrical fault current may be increased to 85,000 amps if the appropriate
three-phase AC line reactor is used as shown in table 5.1.
!