Electrical data ~ 60 hz, Controls, Controls ,12 – Carrier 30GB060 User Manual

Electrical data ~ 60 Hz

30GB

UNIT

COMPRESSORSt

FAN MOTORS*

Volts

MCA

MORA
(Fuse)

ICF

RLA (ea)

LRA (ea)

Total MTA

Total

Fans

(Ph)

FLA (ea)

Fan No.

MTA

(FCB)

Nameplate

Supplied*

Compressor No.

CB

h

O.

Min

Max

1

2

1

2

1

2

1,2

3,4,5,6

208-230

187

254

342

500

846

119

158.5

506

690

166

222

6

(

1

)

4.6

7 7

35

060

460

414

508

155

225

415

53

73

253

345

73

90

6

(

1

)

2.3

3.3

18

575

518

632

128

125

335

45

59

176

276

63

82

6

(

1

)

1.8

2.6

14

NOTE: As shipped, all units are XL (across the line) start.

•Units are suitable for use on electrical systems where voltage

supplied to the unit terminals is not below or above the listed
minimum and maximum limits.

f30GB060 has 2 compressors.
jaOGBOeO has one FOB for all fans.

GENERAL ELECTRICAL NOTES:
1 Unit listings are:

UL — Underwriters Laboratories: 30GB060

2. Electrical data based on unit conforming to ARl Standard 590,

Section 8.1.

Maximum Loading Conditions

(115 F ambient at

-

10

% voltage)

3. All units have single-location power connection to simplify field-

power wiring Main power must be supplied from a field-supplied
fused disconnect. Unit must be properly grounded.

4. Control circuit power must be supplied from a separate source

through a field-supplied fused disconnect. (See Note 9.)

5. Crankcase and cooler heaters are wired into the control circuit

so they are always operable as long as the control circuit power
supply disconnect is on, even if any safety device is open or the
unit CN/CFF switch is off.

6

. Heaters are wired ahead of the control circuit fuse; thus, they are

protected by the overcurrent protective device in the control
circuit power supply.

7. Cn all voltages, 30GB060 has one terminal block, with 3 con­

ductors from the fused disconnect.

8

. Maximum incoming wire size for each terminal block is 500 MCM.

9. Amperage required for control circuit is as follows:

UNIT

30GB

POWER

SUPPLY

CONTROL

CIRCUIT

Power

Amps

208/230-3-60

115-1-60

15

060

460-3-60

115-1-60

15

575-3-60

115-1-60

15

10. Power draw of control circuits includes both crankcase heaters

and cooler heaters Each compressor has a crankcase heater
that draws

200

watts of power

Cooler heaters: 060 - 360 watts — band heaters (360 watts total).

Controls

Microprocessor — Microprocessor controls overall

unit operation. Its central executive routine controls a

number of processes simultaneously. These include

internal timers, reading inputs, A to D conversions, fan

control, display control, diagnostic control, output relay

control, demand limit, capacity control, head pressure

control and temperature reset. Some processes are

updated almost continuously, others every 2 to 3 seconds,

and some every 30 seconds.

The microprocessor routine is started by switching

control circuit ON-OFF circuit breaker switch to ON.

(This switch is also used to reset microprocessor should

any safety trip and also functions as circuit breaker for

electronic processor and relay boards.)

When the switch is closed, a 2-minute initialization

routine is begun. During this time, inputs are checked,

EXV and internal constants are initialized and a 20

appears on display. If display button is pushed during this

period, control goes into a 42-step Quick Test routine,

normally used for a readiness check during start-up, or

for service.

Microprocessor controls capacity of chiller by cycling

compressors and unloaders on and off at a rate to satisfy

actual dynamic load conditions. Control will maintain

leaving water temperature set with dial on display board

through intelligent cycling of compressors. Accuracy will

depend on loop volume, loop flow rate, load, outside air

temperature, number of stages, and particular stage

being cycled off. No adjustment for cooling range or

cooler flow rate is required, because the control auto­

matically compensates for cooling range by measuring

both return water temperature and leaving water

temperature. This is referred to as leaving water tem­

perature control with return water temperature

compensation.

The basic logic for determining when to add or remove

a stage is a time band integration of deviation from set

point plus rate of change of leaving water temperature.

When leaving water temperature is close to set point and

slowly moving closer, logic prevents addition of another

stage. If leaving water temperature is less than 35 F

(1.7 C) for water, or 6°F (21°C) below the set point for

brine units, the unit is shut off until the water tempera­

ture goes 6°F (3.3°C) above the set point, to protect

against freezing.

If l°F/minute (0.6°C/minute) pulldown control has

been selected (factory setting), no additional steps of

capacity will be added as long as difference between

leaving water temperature and set point is greater than

4°F (2.2°C) and rate of change in leaving water tempera­

ture is less than l°F/minute (0.6°C/minute).

If it has been less than 90 seconds since the last capacity

change, compressors will continue to run unless a safety

trips. This prevents rapid cycling and also helps return oil

during short on periods.

Where available (requires accessory unloaders on some

units), 2 sequences are used to obtain circuit lead-lag

operation, which evens out compressor operating hours.

First, as unit turns on, microprocessor functioning as a

random number generator, determines which circuit will

start first. Also, when decreasing from maximum stage,

control will again randomly select which circuit to run

longest.

The control also performs other special functions

when turning on or off. When a circuit is to be turned off,

EXV is closed first and compressor is run for an additional

10 seconds to pump out refrigerant that was in the cooler.

Again, at start-up, if compressor hasn’t run in the last

15 minutes, EXV is held closed for 10 seconds while

11