Carrier 50HE003-006 User Manual

61

S

SPT reading is available

S

OAT ± SPT

S

Economizer Position is NOT forced

If any of the above conditions are not met, the economizer
submaster reference (ECSR) is set to maximum limit and the

damper moves to minimum position. The operating sequence is

complete. The ECSR is recalculated every 30 seconds.
If an optional power exhaust is installed, as the outdoor-air

damper opens and closes, the power exhaust fans will be
energized and deenergized.
If field-installed accessory CO

2

sensors are connected to

the

PremierLink™ control, a PID-controlled demand ventilation

strategy will begin to operate. As the CO

2

level in the zone

increases above the CO

2

set point, the minimum position of the

damper will be increased proportionally. As the CO

2

level

decreases because of the increase in fresh air, the outdoor-air
damper will be proportionally closed.
Heating -- Unit With Economi$er2, Premierlink Control and
a Room Sensor
Every 40 seconds the controller will calculate the required heat
stages (maximum of 3) to maintain Supply-Air Temperature

(SAT) if the following qualifying conditions are met:

S

Indoor fan has been on for at least 30 seconds.

S

COOL mode is not active.

S

OCCUPIED, TEMP. COMPENSATED START or
HEAT mode is active.

S

SAT reading is available.

S

Fire shutdown mode is not active.

If all of the above conditions are met, the number of heat stages is

calculated; otherwise the required number of heat stages will be

set to 0.
If the PremierLink controller determines that heat stages are

required, the economizer damper will be moved to minimum
position if occupied and closed if unoccupied.
Staging should be as follows:
If Heating PID STAGES=2

S

HEAT STAGES=1 (50% capacity) will energize HS1

S

HEAT STAGES=2 (100% capacity) will energize HS2

If Heating PID STAGES=3 and AUXOUT = HS3

S

HEAT STAGES=1 (33% capacity) will energize HS1

S

HEAT STAGES=2 (66% capacity) will energize HS2

S

HEAT STAGES=3 (100% capacity) will energize HS3

Units With Humidi-Mizer™ Adaptive

Dehumidification System
Normal Design Operation
When the rooftop operates under the normal sequence of

operation, the compressors will cycle to maintain indoor
conditions. (See Fig. 51.)
The Humidi-MiZer adaptive dehumidification system includes a

factory-installed Motormaster® low ambient control to keep the

head and suction pressure high, allowing normal design cooling

mode operation down to 0° F.
Subcooling Mode
When subcooling mode is initiated, this will energize (close) the
liquid line solenoid valve (LLSV) forcing the hot liquid

refrigerant to enter into the subcooling coil. (See Fig. 52.)
As the hot liquid refrigerant passes through the subcooling/ reheat
dehumidification coil, it is exposed to the cold supply airflow

coming through the evaporator coil. The liquid is further

subcooled to a temperature approaching the evaporator
leaving-air temperature. The liquid then enters a thermostatic

expansion valve (TXV) where the liquid drops to a lower
pressure. The TXV does not have a pressure drop great enough to

change the liquid to a 2-phase fluid, so the liquid then enters the

Acutrol™ device at the evaporator coil.
The liquid enters the evaporator coil at a temperature lower than

in standard cooling operation. This lower temperature increases
the latent capacity of the rooftop unit. The refrigerant passes

through the evaporator and is turned into a vapor. The air passing

over the evaporator coil will become colder than during normal
operation. However, as this same air passes over the subcooling

coil, it will be slightly warmed, partially reheating the air.
Subcooling mode operates only when the outside air

temperature is warmer than 40_F. A factory-installed temperature

switch located in the condenser section will lock out subcooling
mode when the outside temperature is cooler than 40_F.
The scroll compressors are equipped with crankcase heaters to
provide protection for the compressors due to the additional

refrigerant charge required by the subcooling/reheat coil.
When in subcooling mode, there is a slight decrease in system

total gross capacity (5% less), a lower gross sensible capacity

(20% less), and a greatly increased latent capacity (up to 40%
more).

C06135

Fig. 51

--- Humidi--MiZer Normal

Design Cooling Operation

C06136

Fig. 52

--- Humidi--MiZer Subcooling

Mode Operation

50H

E,

H

J