Control and status, Control signals, Status signals – GE Industrial Solutions CAR2912TE series User Manual

GE

Preliminary Data Sheet

CAR2912TE series front-end

Input: 90Vac to 264Vac; Output: 12Vdc @ 2900W; 3.3 or 5Vdc @ 4A Standby

October 21, 2013

©2013 General Electric Company. All rights reserved.

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Control and Status

Control hierarchy:

Some features, such as output voltage,

can be controlled both through hardware and firmware. For

example, the output voltage is controlled both by a signal pin

(Vprog) and a PMBus command, (OPERATION) .

Unless otherwise noted, the signal pin controls the feature

until the firmware command is executed. However, once the

firmware command has been executed, the signal pin is

ignored. In the above example, the power supply will no

longer ‘listen’ to the Vprog pin if the OPERATION command

has been executed.

In summary, Vprog is utilized for initialized configuration of

the output voltage and to change the output voltage when

PMBus is not used for that function.

Analog controls:

Details of analog controls are provided in

this data sheet under Feature Specifications.

Common ground:

All signals and outputs are referenced to

Output return.

Control Signals

Device address:

Address bits A3, A2, A1, A0 configure the

specific address of the power supply. With these four bits, up

to sixteen (16) modules to be addressed on a single I²C bus.

The pins are pulled HI internal to the power supply. For a logic

LO these pins should be connected to ‘Output Return’. The

least significant bit x (LSB) of the address byte is set to either

write [0] or read [1]. A write command instructs the power

supply. A read command accesses information from the

power supply.

Device

Address

Address Bit Assignments

(Most to Least Significant)

7 6 5 4 3

2

1

0

MCU

C or Dx 1 1 0 A3 A2 A1 A0 R/W

Broadcast

00

0 0 0 0

0

0

0

0

ARA

7

12

0 0 0 1

1

0

0

1

MSB

LSB

Voltage programming (V

prog

):

An analog voltage on this

signal can vary the output voltage ± 10% from 10.8Vdc to

13.2Vdc.

Hardware voltage programming controls the output voltage

until a software margin command is executed. Software

voltage programming permanently overrides the hardware

margin setting and the power supply no longer listens to any

hardware margin settings until power to the controller is

7

Implement if feasible, this is a ‘read’ only address

interrupted, for example if input power or bias power is

recycled.

When bias power is recycled to the controller the controller

restarts into its default configuration, programmed to set the

output as instructed by the V

prog

pin. Again, subsequent

software commanded settings permanently override the

margin setting. As an example of an effective use of

hardware programming prior to the availability of software

based controls is to add a resistor between V

prog

and

Output_return. This is a way of changing the factory set point

of the front-end to whatever voltage level is desired by the

user during initial start-up.

Load share (I

share

):

This is a single wire analog signal that is

generated and acted upon automatically by power supplies

connected in parallel. I

share

pins should be connected to each

other for power supplies, if active current share among the

power supplies is desired. No resistors or capacitors should

get connected to this pin.

Remote ON/OFF:

Controls the presence of the main 12Vdc

output voltage. This is an open collector signal that needs to

be pulled HI externally through a resistor. A logic HI turns ON

the main output.

A turn OFF command either through this signal (ON/OFF) or

firmware commanded would turn OFF the 12V output.

Interlock:

This is a short signal pin that controls the presence

of the 12Vdc main output. This pin should be connected to

‘output return’ on the system side of the output connector.

The short pin ensures that no arcing or contact damage

occurs during the insertion/extraction process.

8V_INT:

Provides the ability to back_bias a front-end that lost

input power thus maintaining the ability to communicate with

a remote controller. This pin should be interconnected among

units in a system.

Status signals

See Feature Specifications for additional information

AC OK:

A TTL compatible status signal representing whether

the input voltage is within the anticipated range. This signal

needs to be pulled HI externally through a resistor.

DC OK:

A TTL compatible status signal representing whether

the output voltage is present. This signal needs to be pulled HI

externally through a resistor.

Over temp warning:

A TTL compatible status signal

representing whether an over temperature exists. This signal

needs to be pulled HI externally through a resistor.

If an over temperature should occur, this signal would pull LO

for approximately 10 seconds prior to shutting down the

power supply. In its default configuration, the unit would