9 local/remote sensing, 10 retaining latches, R. 5.) – KEPCO HSF 300W Series (no suffix) Operator Manuals User Manual

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HSF 300W 050113

3.9

LOCAL/REMOTE SENSING

HSF 300W Power Supplies allow remote error sensing which can compensate up to 0.4 Volts per

load wire. Local/Remote error sensing is configured by means of separate DIP switches mounted

on the RA 19-4C Rack Adapter (see RA 19-4C Rack Adapter Operator Manual). Either local or

remote sensing MUST be used, otherwise the units will not operate.

3.10 RETAINING LATCHES

HSF 300W series power supplies are provided with (2) retention latches located at each side of

the bottom edge of the front panel (see Figure 5). These latches work in conjunction with the RA

19-4C rack adapters to prevent unauthorized or inadvertent module extraction from an operating

power system. The latch is engaged by loosening the cap-head screw approximately 1/2 turn

CCW (use 5/32” hex key) and sliding the latch down to the bottom of the slot, then retightening the

cap-head screw CW until snug. DO NOT OVERTIGHTEN! To release, follow the same procedure,

except lift the latch to the top of the slot. Be sure to move the latch completely up or down to

ensure full engagement and disengagement of the latching mechanism. When the HSF power

supply is not installed in its plug-in rack adapter, it is recommended that the latch be secured in

the open (up) position to prevent damage.

NOTE: Retaining latches must not be used to secure the HSF power supply in the rack

adapter for shipping purposes.

4.

LOAD CONNECTION

Connect the load to (+) and (–) terminals at the rear panel of the Rack Adapter (see RA 19-4C

Instruction Manual for details).

5.

CONNECTING MULTIPLE POWER SUPPLIES

All connections to multiple HSF power supplies must be made via the I/O mating connectors at

rear of the Rack Adapter or by the Rack Adapter DIP switches. These connections, including the

configuration of the two internal HSF DIP switches, are described in the Rack Adapter Instruction

manual, and include:

• Using one power supply to control the output of multiple supplies.

• Using parallel master/slave configurations (for increased current or redundancy) where

the user either predetermines the master or allows the load to determine which is the

master. These configurations also cover the use of the Current Balancing feature of the

HSF power supply.

• Using series configurations (for increased voltage).

• Using open-on-fail or close-on-fail alarm schemes with multiple power supplies.

NOTE: If parallel-connected units are controlled individually, either a minimum load or voltage

set restrictions are required to avoid slave “idle” or slave “oscillating output” conditions

(When the slave is idle, the output is off, no lights are lit, and the alarm is set.) If the

minimum load is maintained, voltage set restrictions are not required.

Minimum Load: The minimum load (Amperes) = N x (I/10) where N = the number of

units in parallel, I = Nominal current rating of individual power supply (Amperes). For

applications requiring no load or lower than minimum load conditions refer to the Volt-

age Set Restrictions specified below. Load effect specifications will not be met when

units are operated in redundant mode with load less than 10% per unit.

Voltage Set Restrictions: To avoid slave “idle” all parallel-connected units’ output

voltage must be set within 1% or 200mV of each other (whichever is lower) and be at

least 80% of their nominal (rated) output voltage (90% for 48V model).