PremierLink™
Retrofit Split System
Controller
Installation, Start-Up and
Configuration Instructions
Part Number 33CSPREMLK
Page
CONTENTS
Page
SAFETY CONSIDERATIONS. . . . . . . . . . . . . . . . . . . . . . 1
GENERAL. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1,2
CONFIGURATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28-42
Points Display Screen. . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Thermostat Control Input Screen. . . . . . . . . . . . . . . . 30
Alarm Service Configuration Screen . . . . . . . . . . . . 30
Controller Identification Screen . . . . . . . . . . . . . . . . . 31
Holiday Configuration Screen . . . . . . . . . . . . . . . . . . . 31
Occupancy Configuration Screen . . . . . . . . . . . . . . . 32
Set Point Screen . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Service Configuration Selection Screen. . . . . . . . . 33
PremierLink Configuration Screen . . . . . . . . . . . . . . 37
Occupancy Maintenance Screen . . . . . . . . . . . . . . . . 39
Maintenance Screen . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
INSTALLATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-26
Inspection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
PremierLink Controller Hardware. . . . . . . . . . . . . . . . . 2
Field-Supplied Hardware . . . . . . . . . . . . . . . . . . . . . . . . . 2
• SPACE TEMPERATURE (SPT) SENSOR
• SUPPLY AIR TEMPERATURE (SAT) SENSOR
• INDOOR AIR QUALITY CO2 SENSOR
• OUTDOOR AIR QUALITY CO2 SENSOR
• OUTDOOR AIR TEMPERATURE SENSOR
• OUTDOOR AIR ENTHALPY SWITCH
• RETURN AIR ENTHALPY SENSOR
Mount PremierLink Control. . . . . . . . . . . . . . . . . . . . . . . 2
• LOCATION
SAFETY CONSIDERATIONS
SAFETY NOTE
Air-handling equipment will provide safe and reliable service
when operated within design specifications. The equipment
should be operated and serviced only by authorized person-
nel who have a thorough knowledge of system operation,
safety devices and emergency procedures.
• MOUNTING
PremierLink Controller Inputs and Outputs . . . . . . 3
Control Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Install Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
• SPACE TEMPERATURE (SPT) SENSOR
INSTALLATION
Good judgement should be used in applying any manufac-
turer’s instructions to avoid injury to personnel or damage to
equipment and property.
• SUPPLY AIR TEMPERATURE (SAT) SENSOR
INSTALLATION
• INDOOR AIR QUALITY CO2 SENSOR
INSTALLATION
• OUTDOOR AIR QUALITY CO2 SENSOR
INSTALLATION
Disconnect all power to the unit before performing mainte-
nance or service. Unit may automatically start if power is
not disconnected. Electrical shock and personal injury
could result.
• OUTDOOR AIR TEMPERATURE SENSOR
Connect to CCN Communication Bus . . . . . . . . . . . 18
• COMMUNICATIONS BUS WIRE SPECIFICATIONS
Enthalpy and Differential Enthalpy Control . . . . . . 18
• ENTHALPY SWITCH/RECEIVER
• OUTDOOR AND RETURN AIR ENTHALPY
SENSOR
Economizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
• Q769B
• Q769C
Economizer with Johnson 4 to 20 mA
Actuator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
• DRIVE DIRECTION
• SWITCH SELECTION
• WIRING
Damage to equipment may result. An individual field-
supplied 24-vac power transformer is required for each
PremierLink controller. The transformer must be less than
100 va to meet UL (Underwriters’ Laboratories) Class 2.
GENERAL
The PremierLink Controller is a field retrofit split system
control compatible with the Carrier Comfort Network (CCN).
This control is designed to allow users the access and ability to
change factory-defined settings thus expanding the function of
the standard unit control board. The complete PremierLink
package (part number 33CSPREMLK) consists of a control
circuit board with plastic cover and label, wire harnesses, spade
connectors, wire nuts and 4 mounting screws.
START-UP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26-28
Perform System Check-Out . . . . . . . . . . . . . . . . . . . . . 26
Initial Operation and Test. . . . . . . . . . . . . . . . . . . . . . . . 26
Install Navigator™ Display Module . . . . . . . . . . . . . 26
Password Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Forcing Values and Configuring Items . . . . . . . . . . 28
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
PC 111 Catalog No. 533-80072 Printed in U.S.A. Form 38-54SI Pg 1 11-02 Replaces: 38-52SI
Book 1
4
Tab 3a 2a
*To restore factory default settings, the unit must be in the unpowered state. Move Switch 4 to Position 1 and then restore unit power.
Fig. 1 — PremierLink™ Control Module
PremierLink Controller Inputs and Outputs —
NOTE: When connecting the communication bus cable, a
The PremierLink controller inputs and outputs are shown in
color code system for the entire network is recommended to
Table 1.
simplify installation and checkout. See Table 2 for the
recommended color code.
3. Use 4-connector Molex with red, white and black wires
to connect the communication wires. Verify the color
Disconnect electrical power before wiring the Premier-
codes in Table 2 to ensure the Red (+) wire connects to
Link controller. Electrical shock, personal injury, or
Terminal 1. Connect the White (ground) wire to Terminal
2. Connect the Black (–) wire to Terminal 3.
damage to the PremierLink controller can result.
4. Secure all connections in Step 3 with wire nuts.
Control Wiring — The PremierLink controller can be
5. Insert the plug into the existing 4-pin mating connector
on the base module in the main control box (Terminal
J-2).
connected to either a Carrier-approved thermostat or CCN
compatible temperature sensor.
1. Turn off power to the control box.
2. Strip the ends of the red, white, and black conductors of
the communication bus cable.
6. Restore power.
3
PremierLink Connections
40RM Connections
38AK, AKS, ARZ, ARS
Terminal
Board (TB)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
R
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
Y1
Y2
W1
W2
G
C1 IFC C2
WHT
WHT
C
X
CMP2
CCR
RED
CMP1
FAN
LLSV
RED
C
GRN
BRN
X
CCSV
CCR
LEGEND
CCR — Capacity Control Relay (If Equipped)
CCSV — Capacity Control Valve, Indoor Coil (If Equipped)
IFC
— Indoor-Fan Contactor
LLSV — Liquid Line Solenoid Valve
NOTE: Configure AC to “0”.
Fig. 2A — Typical PremierLink™ Control Wiring — 38AK,AKS,ARZ,ARS007-012 Units
PremierLink Connections
40RM Connections
38AKS
Terminal
Board (TB2)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
10
9
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
C1 IFC C2
WHT
WHT
8
C
X
CMP2
4
3
2
1
CCR
RED
CMP1
FAN
CR2
RED
GRN
BRN
CCSV
CCR
CR2
LEGEND
CCR — Capacity Control Relay (If Equipped)
LLSV
CCSV — Capacity Control Valve, Indoor Coil (If Equipped)
CR2 — Control Relay No. 2 (Liquid Line Solenoid Valve)
IFC
— Indoor-Fan Contactor
LLSV — Liquid Line Solenoid Valve
Fig. 2B — Typical PremierLink Control Wiring — 38AKS013-024 Units
4
PremierLink Connections
40RM Connections
38ARD
Terminal
Board (TB)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
R
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
Y1
Y2
W1
W2
G
C1 IFC C2
CCR
WHT
WHT
C
X
CMP2
RED
CMP1
FAN
LLSV
RED
C
GRN
BRN
X
CCSV
CCR
LEGEND
CCR — Capacity Control Relay (If Equipped)
CCSV — Capacity Control Valve, Indoor Coil (If Equipped)
IFC
— Indoor-Fan Contactor
LLSV — Liquid Line Solenoid Valve
NOTE: Configure AC to “0”.
Fig. 2C — Typical PremierLink™ Control Wiring — 38ARD012 Units
PremierLink Connections
40RM Connections
38AKS
Terminal
Board (TB3)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
R
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
Y1
Y2
W1
W2
G
C1 IFC C2
WHT
WHT
C
X
CMP2
CMP1
FAN
CCR
RED
RED
C
GRN
BRN
X
CCSV
CCR
LEGEND
CCR — Capacity Control Relay (If Equipped)
CCSV — Capacity Control Valve, Indoor Coil (If Equipped)
IFC — Indoor-Fan Contactor
Fig. 2D — Typical PremierLink Control Wiring — 38AKS028-044 Units
5
PremierLink Connections
40RM Connections
38AH
Terminal
Board (TB2)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
C1 IFC C2
WHT
WHT
5
C
X
CMP2
4
3
2
1
RED
CMP1
FAN
RED
GRN
BRN
LEGEND
IFC — Indoor-Fan Contactor
Fig. 2E — Typical PremierLink™ Control Wiring — 38AH024-034 Units
PremierLink Connections
38AH Connections
TB3
1
TB4
1
2
3
4
5
6
7
8
2
3
4
5
6
7
8
ACCESSORY
RELAY
PWR
RED
ORN
IFC
LLS
-B1
PACKAGE
HS3/EXH/RVS
LLS
-A1
CR1
VIO
CR2
BRN
IFR
RED
HS2
HS1
PNK
WHT
BLU
YEL
RED
YEL
RED
1
24V
2
3
4
5
IFR
CR1
CR2
CMP2
RED
CMP1
FAN
RED
GRN
BRN
LEGEND
CR — Control Relay
IFC — Indoor-Fan Contactor
IFR — Indoor-Fan Relay
LLS — Liquid Line Solenoid
TB — Terminal Block
Fig. 2F — Typical PremierLink Control Wiring — 38AH004-104 Units
6
PremierLink Connections
40RMQ Connections
38AQ007
Control
Connections
PWR
R
RED
HS3/EXH/RVS
HS2
ORN
PNK
WHT
BLU
YEL
CR
R
Y1
Y2
W1
W2
G
RED
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
W1
W2
C
RED
CR
HS1
C1 IFC C2
WHT
WHT
O
C
CMP2
X
W
Y
RED
CMP1
FAN
RED
BL
GRN
BRN
LEGEND
CR — Control Relay (Field-Supplied)
IAQ — Indoor-Air Quality
IFC — Indoor-Fan Contactor
NOTES:
1. Configure AC to “1” for heat pump units.
2. Configure AUXOUT to “3’ for reversing valve.
3. Configure PremierLink control for 2-stage heat and single-stage cool.
4. If IAQ is high priority, wire HS2 to W1. If not, wire HS1 to W1.
Fig. 2G — Typical PremierLink™ Control Wiring — 38AQ007 Units
PremierLink Connections
40RM Connections
38AQS008
Terminal
Board (TB)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
CR
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
R
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
Y1
Y2
C1 IFC C2
WHT
WHT
C
X
CMP2
W1
CR
W2
RED
CMP1
FAN
G
C
X
LLSV
RED
GRN
BRN
LEGEND
CR
— Control Relay (Field-Supplied)
IFC — Indoor-Fan Contactor
IAQ — Indoor-Air Quality
LLSV — Liquid LIne Solenoid Valve
NOTES:
1. Configure AC to “1” for heat pump units.
2. Configure AUXOUT to “3” for reversing valve.
3. Configure PremierLink control for 2-stage heat and single-stage cool.
4. When using controller for DCV, if IAQ priority is set to HIGH, the controller will use a stage of heat for temperature tempering.
If priority is set to LOW, no tempering will occur. If IAQ is high priority, wire HS2 to W1. If not, wire HS1 to W1.
Fig. 2H — Typical PremierLink Control Wiring — 38AQS008 and 38ARQ008,012 Units
7
PremierLink Connections
40RMQ Connections
38AQS012-016
Terminal
Board (TB2)
PWR
RED
ORN
R
Y1
Y2
W1
W2
G
HS3/EXH/RVS
40RM, 40RMQ, 40RMS
HEAT ACCESSORY
RED
R
B
HS2
HS1
W1
W2
C
PNK
WHT
BLU
YEL
RED
C1 IFC C2
WHT
WHT
W1
C
X
CMP2
Y1
Y2
G
RED
CMP1
FAN
RED
GRN
BRN
C
LEGEND
IAQ — Indoor-Air Quality
IFC — Indoor-Fan Contactor
NOTES:
1. Configure AC to “1” for heat pump or “0” for air conditioner.
2. When using controller for DCV, if IAQ priority is set to HIGH, the controller will use a stage of heat for temperature tempering.
If priority is set to LOW, no tempering will occur.
3. For air conditioners, use HS1 for IAQ tempering.
4. For heat pumps, use HS2 for IAQ tempering.
Fig. 2I — Typical PremierLink™ Control Wiring — 38AQS012-016 Units
Table 1 — PremierLink Controller Inputs and Outputs
INPUTS
POWER
AI (10K Thermistor)
AI (10K Thermistor)
AI (10K Thermistor)
AI (10K Thermistor)
(4-20 mA)
(4-20 mA)
DI (24 VAC)
DI (24 VAC)
DI (24 VAC)
TERMINAL(S)
J6-7, J6-6
J6-5, J6-6
J6-3, J6-4
J6-1, J6-2
J5-5, J5-6
J5-2, J5-3
J4-11, J4-12
J4-9, J4-10
J4-7, J4-8
J4-5, J4-6
SPACE TEMPERATURE (SPT)
SET POINT ADJUSTMENT (STO)
SUPPLY AIR TEMPERATURE (SAT)
OUTDOOR AIR TEMPERATURE (OAT)
IAQ SENSOR (IAQI)
OUTDOOR AQ SENSOR (OAQ)
REMOTE TIME CLOCK (RMTOCC)
COMPRESSOR LOCKOUT (CMPSAFE)
FIRE SHUTDOWN (FSD)
SUPPLY FAN STATUS (SFS)
NOT USED
DI (24 VAC)
ENTHALPY STATUS (ENTH)
OUTPUTS
ECONOMIZER (ECONPOS)
FAN (SF)
COOL STAGE 1 (CMP1)
COOL STAGE 2 (CMP2)
HEAT STAGE 1 (HS1)
HEAT STAGE 2 (HS2)
HEAT 3/EXHAUST/REVERSING VALVE (HS3/EXH/RVS)
DI (24 VAC)
POWER
4-20 mA
DO Relay (24 VAC, 1A)
DO Relay (24 VAC, 1A)
DO Relay (24 VAC, 1A)
DO Relay (24 VAC, 1A)
DO Relay (24 VAC, 1A)
DO Relay (24 VAC, 1A)
J4-1, J4-2
TERMINAL(S)
J9-1, J9-2
J8-18
J8-15
J8-12
J8-9
J8-6
J8-3
LEGEND
AI — Analog Input
DI — Digital Input
DO — Digital Output
8
Table 2 — Color Code Recommendations
6. Use 20 gage wire to connect the sensor to the controller.
The wire is suitable for distances of up to 500 ft. Use a
three-conductor shielded cable for the sensor and set
point adjustment connections. The standard CCN
communication cable may be used. If the set point adjust-
ment (slidebar) is not required, then an unshielded, 18 or
20 gage, two-conductor, twisted pair cable may be used.
CCN BUS WIRE
COLOR
CCN PLUG PIN
NUMBER
SIGNAL TYPE
+
Ground
–
Red
White
Black
1
2
3
The CCN network service jack requires a separate,
shielded CCN communication cable. Always use sepa-
rate cables for CCN communication and sensor wir-
ing. (Refer to Fig. 5 for wire terminations.)
Install Sensors (See Fig. 3-10) — The PremierLink™
controller can be used with either the T58 Communicating sen-
sor or any combination of CO2 and space temperature sensors.
Refer to the instructions supplied with each sensor for electrical
requirements.
7. Replace the cover by inserting the cover at the top of the
mounting plate first, then swing the cover down over the
lower portion. Rotate the two Allen head screws counter-
clockwise until the cover is secured to the mounting plate
and locked in position.
NOTE: See Table 3 for thermistor resistance vs temperature
values.
Wiring the Space Temperature Sensor — To wire the sensor,
perform the following (see Fig. 3-5):
1. Identify which cable is for the sensor wiring.
NOTE: All sensors are field-installed accessories.
SPACE TEMPERATURE (SPT) SENSOR INSTALLA-
TION — There are three types of SPT sensors available from
Carrier: The 33ZCT55SPT space temperature sensor with
timed override button, the 33ZCT56SPT space temperature
sensor with timed override button and set point adjustment, and
the 33ZCT58SPT T58 communicating room sensor with
timed override button, set point adjustment, and manual fan
control.
The space temperature sensors are used to measure the
building interior temperature. The T58 communicating room
sensors measure and maintain room temperature by communi-
cating with the controller. Sensors should be located on an
interior building wall. The sensor wall plate accommodates the
NEMA (National Electrical Manufacturers Association)
standard 2 x 4 junction box. The sensor can be mounted direct-
ly on the wall surface if acceptable by local codes.
2. Strip back the jacket from the cables for at least 3 inches.
1
Strip /4-in. of insulation from each conductor. Cut the
shield and drain wire from the sensor end of the cable.
3. Connect the sensor cable as follows:
a. Connect one wire from the cable to (BLU) wire on
J6-7 analog connector on the controller. Connect
the other end of the wire to the left terminal on the
SEN terminal block of the sensor.
b. Connect another wire from the cable to (BRN)
J6-6 analog connector on the controller. Connect
the other end of the wire to the remaining open ter-
minal on the SEN terminal block.
c. On 33ZCT56SPT thermostats, connect the remain-
ing wire to the (BLK) STO on J6-5 connector on
the controller. Connect the other end of the wire to
the SET terminal on the sensor.
d. In the control box, install a no. 10 ring type crimp
lug on the shield drain wire. Install this lug under
the mounting screw of the PremierLink controller.
e. On 33ZCT56SPT thermostats install a jumper
between the two center terminals (right SEN and
left SET). See Fig. 4.
f. Refer to Fig. 5 for 33ZCT58SPT thermostat wir-
ing. Once the T58 sensor is powered up, all of the
graphic icons on the LCD (liquid crystal display)
display will be energized for a few seconds. The
graphical icons will then turn off and the T58 sen-
sor will energize the three-digit numeric display.
The value “58” will be displayed for two seconds.
After 2 seconds, the LCD will display the default
space temperature value.
Do not mount the sensor in drafty locations such as near air
conditioning or heating ducts, over heat sources such as base-
board heaters, radiators, or directly above wall-mounted light-
ing dimmers. Do not mount the sensor near a window which
may be opened, near a wall corner, or a door. Sensors mounted
in these areas will have inaccurate and erratic sensor readings.
The sensor should be mounted approximately 5 ft from the
floor, in an area representing the average temperature in the
space. Allow at least 4 ft between the sensor and any corner
and mount the sensor at least 2 ft from an open doorway. The
SPT sensor wires are to be connected to terminals in the unit
main control board.
Install the sensor as follows:
1. Locate the two Allen type screws at the bottom of the
sensor.
2. Turn the two screws clockwise to release the cover from
the sensor wall mounting plate.
3. Lift the cover from the bottom and then release it from
the top fasteners.
4. Feed the wires from the electrical box through the open-
ing in the center of the sensor mounting plate.
5. Using two no. 6-32 x 1 mounting screws (provided with
the sensor), secure the sensor to the electrical box.
NOTE: See Fig. 6 for space temperature sensor averaging.
NOTE: Sensor may also be mounted directly on the
wall using 2 plastic anchors and 2 sheet metal screws
(field-supplied).
9
Table 3 — Thermistor Resistance vs Temperature
Values for Space Temperature Sensor,
Supply Air Temperature Sensor, and
Outdoor Air Temperature Sensor
TEMP
(C)
TEMP
(F)
RESISTANCE
(Ohms)
–40
–35
–30
–25
–20
–15
–10
–5
–40
–31
–22
–13
–4
335,651
242,195
176,683
130,243
96,974
72,895
55,298
42,315
32,651
25,395
19,903
15,714
12,494
10,000
8,056
1
2
6
4
5
3
RED(+)
WHT(GND)
CCN COM
BLK(-)
5
14
SET
SEN
23
SW1
0
32
BLK
(T56)
5
41
10
50
BRN (GND)
BLU (SPT)
SENSOR WIRING
15
59
20
68
25
77
30
86
JUMPER
TERMINALS
AS SHOWN
35
95
6,530
40
104
113
122
131
140
149
158
5,325
45
4,367
50
3,601
55
2,985
60
2,487
65
2,082
70
1,752
Cool
Warm
Fig. 4 — Space Temperature Sensor
Typical Wiring (33ZCT56SPT)
SUPPLY AIR TEMPERATURE (SAT) SENSOR INSTAL-
LATION — The 33ZCSENSAT supply air temperature sensor
is required for controller operation. The sensor consists of a
thermistor encased within a stainless steel probe. The SAT
sensor probe is 6-in. nominal length with 114 in. of unshielded,
2-conductor 18 AWG twisted-pair cables. The sensor tempera-
ture range is –40 to 245 F with a nominal resistance of
10,000 ohms at 77 F. The sensor measures accuracy of ±0.36 F.
The SAT sensor is supplied with a gasket and 2 self-drilling
mounting screws.
NOTE: The sensor must be mounted in the discharge of the
unit, downstream of the cooling coil and heat exchanger. Be
sure the probe tip does not come in contact with any of the
unit surfaces. See Fig. 11 for mounting location.
1
2
6
4
5
3
RED(+)
WHT(GND)
CCN COM
BLK(-)
SEN
SW1
Do not run sensor or relay wires in the same conduit or race-
way with Class 1 AC service wiring. Do not abrade, cut, or
nick the outer jacket of the cable. Do not pull or draw cable
with a force that may harm the physical or electrical properties.
Avoid splices in any control wiring.
BRN (GND)
BLU (SPT)
SENSOR WIRING
Perform the following steps to connect the SAT sensor to
the PremierLink™ controller:
1. Locate the opening in the control box. Pass the sensor
probe through the hole.
2. Drill or punch a 1/2-in. hole in the supply air duct.
3. Use two field-supplied, self-drilling screws to secure the
sensor probe to the duct.
4. Connect the sensor leads to the PremierLink controller’s
wiring harness J6-3,4 board at the terminals labeled SAT
(ORN) and GND (BRN).
Fig. 3 — Space Temperature Sensor
Typical Wiring (33ZCT55SPT)
10
(American Wire Gage) twisted-pair cables (unshielded) to con-
nect the separate isolated 24 vac power source to the sensor and
to connect the sensor to the control board terminals. To connect
the sensor to the control, identify the positive (4 to 20 mA) and
ground (SIG COM) terminals on the sensor. Connect the
4-20 mA terminal to terminal IAQ (RED) and connect the
SIG COM terminal to terminal GND (BRN).
FIELD WIRING
T58 SENSOR
VAC
J4-3 (24 VAC)
24 VAC
COM
J6-6 SDT (COM)
OUTDOOR AIR QUALITY CO2 SENSOR INSTALLA-
TION (OAQ) — The Outdoor Air CO2 sensor is designed to
monitor carbon dioxide (CO2) levels in the air and interface
with the ventilation damper in an HVAC system. The OAQ
sensor is packaged with an outdoor cover. See Fig. 12 and 13.
The outdoor air CO2 sensor must be placed in an area that is
representative of the entire conditioned space. A mounting
height of 6 feet is recommended. For installation where it is not
necessary to reach the control, it may be mounted higher on the
wall or on the ceiling, provided the location represents a good
sampling of air.
Wiring the Outdoor Air CO2 Sensor — Power requirements
are 18 to 36 vac RMS 50/60 Hz; 18 to 42 vdc polarity protected/
dependent; and 70 mA average, 100 mA peak at 24 vdc. All
system wiring must be in compliance with all applicable local
and national codes. A dedicated power supply is required for
this sensor. A two-wire cable is required to wire the dedicated
power supply for the sensor. The two wires should be connected
to the power supply and terminals 1 and 2. To connect the sen-
sor to the control, identify the positive (4 to 20 mA) and ground
(SIG COM) terminals on the sensor. Connect the 4 to 20 mA
terminal OAQ (BLU) terminal J5-2. Connect the SIG COM ter-
minal to terminal GND (BRN) terminal J5-3. See Fig. 12.
OUTDOOR AIR TEMPERATURE SENSOR (Fig. 14-17) —
The OAT sensor must be located properly. The sensor must be
installed immediately upstream from outdoor air damper
where it will accurately sense the temperature of the outdoor
air entering the mixing box. See Fig. 14 and 15. For applica-
tions without economizer, the sensor may be located in the out-
door air duct near the outdoor air intake (Fig. 15) or on the
exterior of the building. The thermistor has a range of –40 to
245 F and a resistance of 10,000 ohms at 77 F.
CCN-
GND
BLACK (-)
WHITE (GND)
RED (+)
CCN
COM
CCN+
BLACK (-)
WHITE (GND)
RED (+)
J2
(COM)
Fig. 5 — T58 Communicating Sensor
Typical Wiring (33ZCT58SPT)
Perform the following steps if state or local code requires
the use of conduit, or if your installation requires a cable length
of more than 8 ft:
1. Secure the probe to the duct with two field-supplied self-
drilling screws.
2. If you are extending cable length beyond 8 ft, use plenum
rated, 20 AWG, twisted pair wire.
3. Connect the sensor leads to the PremierLink™ control-
ler’s wiring harness terminal board at the terminals la-
beled SAT (ORN) and GND (BRN).
4. Neatly bundle and secure excess wire.
INDOOR AIR QUALITY CO2 SENSOR INSTALLATION
(IAQ) — The indoor air quality sensor accessory monitors
carbon dioxide (CO2) levels. This information is used to moni-
tor IAQ levels. Three types of sensors are provided. The wall
sensor can be used to monitor the conditioned air space.
Sensors use infrared technology to measure the levels of CO2
present in the air. The wall sensor is available with or without
an LCD readout to display the CO2 level in ppm.
The CO2 sensors are all factory set for a range of 0 to
2000 ppm and a linear mA output of 4 to 20. Refer to the
instructions supplied with the CO2 sensor for electrical require-
ments and terminal locations.
To accurately monitor the quality of the air in the condi-
tioned air space, locate the sensor near a return air grille (if
present) so it senses the concentration of CO2 leaving the
space. The sensor should be mounted in a location to avoid
direct breath contact.
Do not mount the IAQ sensor in drafty areas such as near
supply ducts, open windows, fans, or over heat sources. Allow
at least 3 ft between the sensor and any corner. Avoid mounting
the sensor where it is influenced by the supply air; the sensor
gives inaccurate readings if the supply air is blown directly onto
the sensor or if the supply air does not have a chance to mix
with the room air before it is drawn into the return airstream.
Do not mount the sensor in direct sunlight. Inaccurate read-
ings may result. Do not mount the sensor near the exhaust from
air-handling units or compressors, near leakage drafts of indoor
air, or near shrubbery or trees, or under direct water runoff.
If the sensor is to be mounted in the outdoor air duct, a field-
supplied 2 x 4-in. by 11/2-in. deep electrical box is required.
Remove the cover and enter the knockout from the rear of the
box. Install the sensor through the opening so that the sensor
leads are inside the electrical box. Secure the sensor to the elec-
1
trical box using a field-supplied /2-in. conduit nut. Drill a
13/16-in. hole in the outdoor air duct about a foot upstream of
1
the outdoor air damper. Apply a /4-in. bead of silicone type
sealer around the opening and install the sensor through the
hole. Secure the electrical box to the duct using 2 field-
supplied, No. 10 sheet metal screws. See Fig. 17.
If the sensor is installed outdoors, a field-supplied 1/2-in. LB
type conduit body, gasket, cover, and 1/2-in. EMT compression
connector are required. Install the OAT sensor into the opening
1
at the end of the LB conduit body. Install the /2-in. EMT
connector into the rear opening. Tighten each securely to
prevent water leakage into the assembly. Mount the assembly
1
Wiring the Indoor Air Quality Sensor — To wire the sensors
after they are mounted in the conditioned air space or outdoor
location, see Fig. 7 and 8 and the instructions shipped with the
sensors. For each sensor, use two 2-conductor 18 AWG
onto the /2-in. EMT conduit and secure by tightening the
compression connector nut. After the sensor wiring is complet-
ed, secure the gasket and cover in place using the screws
provided with the cover. See Fig. 16.
11
RED
BLK
RED
BLK
J6
6
RED
BLK
RED
BLK
RED
BLK
7
SENSOR 1
SENSOR 2
SENSOR 3
SENSOR 4
SPACE TEMPERATURE AVERAGING — 4 SENSOR APPLICATION
J6
6
RED
BLK
RED
RED
BLK
BLK
7
SENSOR 3
SENSOR 1
SENSOR 2
RED
BLK
RED
BLK
SENSOR 6
SENSOR 4
SENSOR 5
RED
BLK
RED
BLK
LEGEND
Factory Wiring
Field Wiring
SENSOR 8
SENSOR 9
SENSOR 7
SPACE TEMPERATURE AVERAGING — 9 SENSOR APPLICATION
Fig. 6 — Space Temperature Averaging
12
13
14
15
16
Fig. 13 — Outdoor Air Quality Sensor Cover
Fig. 14 — Outdoor Air Temperature Sensor
(P/N HH79NZ017)
Fig. 11 — Typical Mounting Location for
Supply Air Temperature (SAT) Sensor
On Split System Units
+ 0-10VDC
-
SIG COM (J5-3)
4-20mA (J5-2)
+
ALARM
NC
COM RELAY
}
NO CONTACTS
24 VAC
OR
24 VDC
H G
+
-
2 1
5 4 3 2 1
8 7 6
Fig. 15 — OAT Sensor Location
in Outside Air Duct
Fig. 12 — Outdoor Air Quality (CO2) Sensor
(33ZCSENCO2) — Typical Wiring Diagram
17
At any baud (9600, 19200, 38400 baud), the number of con-
trollers is limited to 239 devices maximum. Bus length may not
exceed 4000 ft, with no more than 60 total devices on any
1000-ft section. Optically isolated RS-485 repeaters are
required every 1000 ft.
NOTE: Carrier device default is 9600 baud.
COMMUNICATION BUS WIRE SPECIFICATIONS —
The CCN Communication Bus wiring is field-supplied and
field-installed. It consists of shielded three-conductor cable
with drain (ground) wire. The cable selected must be identical
to the CCN Communication Bus wire used for the entire net-
work. See Table 4 for recommended cable.
Table 4 — Recommended Cables
MANUFACTURER
Alpha
CABLE PART NO.
2413 or 5463
A22503
American
Belden
Fig. 16 — Outdoor Air Temperature Sensor
Installation — Located in Building Wall
8772
Columbia
02525
NOTE: Conductors and drain wire must be at least 20 AWG
(American Wire Gage), stranded, and tinned copper. Individual
conductors must be insulated with PVC, PVC/nylon, vinyl,
Teflon, or polyethylene. An aluminum/polyester 100% foil
shield and an outer jacket of PVC, PVC/nylon, chrome vinyl,
or Teflon with a minimum operating temperature range of
–20 C to 60 C is required.
2 x 4 x 1.5 IN. ELECTRICAL BOX
(FIELD SUPPLIED)
1/4" BEAD
SILICONE
SEALER
The communication bus shields must be tied together at
each system element. If the communication bus is entirely
within one building, the resulting continuous shield must be
connected to ground at only one single point. If the communi-
cation bus cable exits from one building and enters another
building, the shields must be connected to the grounds at a
lightning suppressor in each building (one point only).
1.125"
DIA.
HOLE
OAT SENSOR
OA
DUCT
Enthalpy and Differential Enthalpy Control
(Fig. 18-23) — There are two options for field-supplied
enthalpy and differential enthalpy control: the enthalpy switch/
receiver option, and the outdoor and return air sensor option.
Either option can be used to indicate when the outdoor air is
suitable for free cooling.
1/2" CONDUIT NUT
2 #10 DRILL/TAP
SCREWS
(FIELD SUPPLIED)
OUTSIDE AIR DUCT
ENTHALPY SWITCH/RECEIVER — The accessory en-
thalpy switch/receiver (33CSENTHSW) senses temperature
and humidity of the air surrounding the device and calculates
the enthalpy when used without an enthalpy sensor. The relay
is energized when enthalpy is high and deenergized when
enthalpy is low (based on ASHRAE 90.1 criteria). If an acces-
sory enthalpy sensor (33CSENTSEN) is attached to the return
air sensor input, then differential enthalpy is calculated. The
relay is energized when the enthalpy detected by the return air
enthalpy sensor is less than the enthalpy at the enthalpy switch/
receiver. The relay is deenergized when the enthalpy detected
by the return air enthalpy sensor is greater than the enthalpy at
the enthalpy switch/receiver (differential enthalpy control). See
Fig. 18 and 19.
DUCT MOUNTED (EXPLODED VIEW)
LEGEND
Outdoor Enthalpy Control Installation (Fig. 20) — Outdoor
enthalpy control requires only an enthalpy switch/receiver
(33CSENTHSW). The enthalpy switch/receiver is mounted in
the outdoor air inlet and calculates outdoor air enthalpy. The
enthalpy switch/receiver energizes the relay output when the
outdoor enthalpy is above 28 BTU/lb OR dry bulb temperature
is above 75 F and is deenergized when the outdoor enthalpy is
below 27 BTU/lb AND dry bulb temperature is below 74.5 F.
The relay output is wired to the unit economizer which will
open or close depending on the output of the switch.
OA — Outdoor Air
OAT — Outdoor Air Temperature
Fig. 17 — Outdoor Air Temperature Sensor
Installation — Located in Outdoor Air Duct
Connect to CCN Communication Bus — The
PremierLink™ controller connects to the bus in a daisy chain
arrangement. Negative pins on each component must be
connected to respective negative pins and likewise positive pins
on each component must be connected to respective positive
pins. The controller signal pins must be wired to the signal
ground pins. Wiring connections for CCN must be made at the
3-pin plug.
NOTE: The enthalpy calculation is done using an average alti-
tude of 1000 ft above sea level.
18
Mounting — Mount the enthalpy switch/receiver in a location
where the outdoor air can be sampled (such as the outdoor air
intake). The enthalpy switch/receiver is not a NEMA 4 enclo-
sure and should be mounted in a location that is not exposed to
outdoor elements such as rain or snow. Use two field-supplied
no. 8 x 3/4-in. TEK screws. Insert the screws through the holes
in the sides of the enthalpy switch/receiver.
Wiring — Carrier recommends the use of 18 to 22 AWG
twisted pair or shielded cable for all wiring. All connections
must be made with 1/4-in. female spade connectors.
A 24 vac transformer is required to power the enthalpy
switch/receiver; as shown in Fig. 20, the PremierLink™ board
provides 24 vac. Connect the GND and 24 VAC terminals on
the enthalpy switch/receiver to the terminals on the transform-
er. On some applications, the power from the economizer har-
ness can be used to power the enthalpy switch/receiver. To
power the enthalpy switch/receiver from the economizer har-
ness, connect power of the enthaply switch/receiver to the red
and brown wires (1 and 4) on the economizer harness.
For connection to split systems units with PremierLink con-
trol, connect the LOW Enthalpy terminal on the enthalpy
switch/receiver to J4 — pin 2 of the PremierLink control on the
unit. The switch can be powered through the PremierLink con-
trol board if desired. Wire the 24 VAC terminal on the enthalpy
switch/receiver to J4 — pin 1 on the PremierLink control. Wire
the GND terminal on the enthalpy switch/receiver to J1 —
pin 2 on the PremierLink control. The HI Enthalpy terminal is
not used. See Fig. 20.
Fig. 18 — Enthalpy Switch/Receiver Dimensions
(33CSENTHSW)
Differential Enthalpy Control Installation (Fig. 21) — Dif-
ferential enthalpy control requires both an enthalpy switch/
receiver (33CSENTHSW) and an enthalpy sensor
(33CSENTSEN). The enthalpy switch/receiver is mounted in
the outdoor air inlet and calculates outdoor air enthalpy. The
enthalpy sensor is mounted in the return airstream and calcu-
lates the enthalpy of the indoor air.
The enthalpy switch/receiver energizes the HI Enthalpy re-
lay output when the outdoor enthalpy is greater than the indoor
enthalpy. The LOW Enthalpy terminal is energized when the
outdoor enthalpy is lower than the indoor enthalpy. The relay
output is wired to the unit economizer which will open or close
depending on the output of the switch.
NOTE: The enthalpy calculation is done using an average alti-
tude of 1000 ft above sea level.
Mounting — Mount the enthalpy switch/receiver in a location
where the outdoor air can be sampled (such as the outdoor air
intake). The enthalpy switch/receiver is not a NEMA 4 enclo-
sure and should be mounted in a location that is not exposed to
outdoor elements such as rain, snow, or direct sunlight. Use
two field-supplied no. 8 x 3/4-in. TEK screws. Insert the screws
through the holes in the sides of the enthalpy switch/receiver.
Mount the enthalpy sensor in a location where the indoor air
can be sampled (such as the return air duct). The enthalpy
sensor is not a NEMA 4 enclosure and should be mounted in a
location that is not exposed to outdoor elements such as rain or
snow. Use two field-supplied no. 8 x 3/4-in. TEK screws. Insert
the screws through the holes in the sides of the enthalpy sensor.
Fig. 19 — Enthalpy Sensor Dimensions
Wiring — Carrier recommends the use of 18 to 22 AWG
twisted pair or shielded cable for all wiring. All connections
must be made with 1/4-in. female spade connectors.
(33CSENTSEN)
The PremierLink board provides 24 vac to power the
enthalpy switch/receiver. Connect the GND and 24 VAC
terminals on the enthalpy switch/receiver to the terminals on
the transformer. On some applications, the power from the
economizer harness can be used to power the enthalpy switch/
receiver. To power the enthalpy switch/receiver from the econ-
omizer harness, connect power of the enthaply switch/receiver
to the red and brown wires (1 and 4) on the economizer
harness.
Connect the LOW Enthalpy terminal on the enthalpy
switch/receiver to J4 — pin 2 of the PremierLink control on the
unit. The switch can be powered through the PremierLink con-
trol board if desired. Wire the 24 VAC terminal on the enthalpy
switch/receiver to J4 — pin 1 on the PremierLink control. Wire
the GND terminal on the enthalpy switch/receiver to J1 — pin
2 on the PremierLink control. The HI Enthalpy terminal is not
used. See Fig. 20.
19
*Used with Differential Enthalpy Control only.
Fig. 20 — Typical Wiring Schematic — Carrier Rooftop Unit with PremierLink™ Controls
Connect the 4-20 mA In terminal on the enthalpy switch/
receiver to the 4-20 mA Out terminal on the return air enthalpy
sensor. Connect the 24-36 VDC Out terminal on the enthalpy
switch/receiver to the 24-36 VDC In terminal on the return air
enthalpy sensor. See Fig. 21.
Enthalpy Switch/Reciever Jumper Settings — There are two
jumpers. One jumper determines the mode of the enthalpy
switch/receiver. The other jumper is not used. To access the
jumpers, remove the 4 screws holding the cover on the
enthalpy switch/receiver and then remove the cover. The fac-
tory settings for the jumpers are M1 and OFF.
The mode jumper should be set to M2 for differential en-
thalpy control. The factory test jumper should remain on OFF
or the enthalpy switch/receiver will not calculate enthalpy.
Enthalpy Sensor Jumper Settings — There are two jumpers.
One jumper determines the mode of the enthalpy sensor. The
other jumper is not used. To access the jumpers, remove the 4
screws holding the cover on the enthalpy sensor and then
remove the cover. The factory settings for the jumpers are M3
and OFF.
OUTDOOR AND RETURN AIR ENTHALPY SEN-
SORS — The differential enthalpy control is supplied as a
field-installed accessory to be used with the Economizer damp-
er control option. The differential enthalpy control provides
two enthalpy sensors for sensing the outdoor air and return air
conditions, and a differential enthalpy controller.
NOTE: The differential enthalpy control must be set to the “D”
setting for differential enthalpy control to work properly.
The differential enthalpy control senses the outdoor and
return air sensors and provides a dry contact switch input to the
PremierLink Controller. Locate the controller in place of an
existing economizer controller or near the actuator. The mount-
ing plate may not be needed if existing bracket is used.
A closed contact indicates that outside air is preferred to the
return air. An open contact indicates that the economizer
should remain at minimum position.
The solid-state return air enthalpy sensor senses and com-
bines the temperature and humidity levels of outdoor and re-
turn air. The sensors provide information for comparison of
outdoor temperature and humidity to return air temperature and
humidity in order to determine the most economical mixture of
air.
The mode jumper should be set to M3 for 4 to 20 mA
output. The factory test jumper should remain on OFF or the
enthalpy sensor will not calculate enthalpy.
20
120 VAC LINE VOLTAGE
24 VAC
SECONDARY
24 VAC OUTPUT FROM N/C CONTACT WHEN THE
OUTDOOR ENTHALPY IS LESS THAN THE
INDOOR ENTHALPY
(ENABLE ECONOMIZER)
24 VAC OUTPUT FROM N/O CONTACT WHEN THE
OUTDOOR ENTHALPY IS GREATER THAN THE
OUTDOOR ENTHALPY
(ENABLE ENERGY RECYCLER)
24-36
VDC
OUT
24-36 4-20
VDC mA
IN OUT
HI
4-20
mA
IN
LOW GND 24
ENTHALPY
VAC
33CSENTHSW
33CSENTSEN
JUMPER SETTINGS FOR 33CSENTHSW
JUMPER SETTINGS FOR 33CSENTSEN
LEGEND
N/C — Normally Closed
N/O — Normally Open
Fig. 21 — Differential Enthalpy Control Wiring
Wiring Enthalpy Sensors — To wire the enthalpy sensor, per-
form the following (see Fig. 24 and 25):
NOTE: To mount outdoor air sensor remotely, remove it from
back of enthalpy control and follow steps 3 and 6.
1. Use a 2-conductor, 18 or 20 AWG, twisted pair cable to
connect the return air enthalpy sensor to the differential
enthalpy control. Use a 4-conductor, 18 or 20 AWG cable
to connect the enthalpy control to the PremierLink con-
troller and power transformer.
2. At the differential enthalpy control remove the factory-
installed resistor from the SR and (+) terminals.
5. At the return air enthalpy sensor, strip 3 in. of jacket from
1
the cable and remove /2 in. of insulation from each
conductor.
6. Connect the RED wire to (+) spade connector on the
sensor. Connect the BLK wire to (S) spade connector on
the sensor. Use wire nuts or closed-end crimp-type con-
nectors to fasten the connections securely. See Fig. 22.
Economizer — The PremierLink™ controller will inter-
face with the 40RM economizer. Economizers will contain a
Honeywell actuator (Honeywell part number M7415).
An adapter (Honeywell part number Q769B or Q769C is
preferred) must be used to enable the 4 to 20 mA signal from
the PremierLink controller to control the position of the econo-
mizer. Refer to Honeywell Q769B and Q769C accessory in-
stallation instructions for wiring details.
3. Connect the RED wire from the 2-conductor cable which
originates from the return air enthalpy sensor to the
SR (+) terminal. Connect the BLK wire to the SR (–)
terminal.
4. Connect the following 4 wires from the 4-wire conduc-
tive cable to the differential enthalpy controller:
a. Connect the RED wire to the 24 vac terminal
(TR1) on enthalpy control and to pin 1 on 12-pin
harness.
Disconnect power supply before making wiring connec-
tions to prevent electrical shock and equipment damage.
b. Connect the BRN wire to the 24 vac GND terminal
(TR) on enthalpy sensor and to pin 4 on 12-pin
harness.
c. Connect the ORN wire to J4-2 on PremierLink
controller and to terminal 3 on enthalpy sensor.
d. Connect the RED wire to J4-1 on PremierLink
controller and to terminal 2 on enthalpy sensor.
To avoid permanent damage to the PremierLink 4 to
20 mA connection, a signal loop isolator must be installed
when using the Q769B adapter.
21
Q769B — Because the Honeywell adapter is designed for a
negative 4 to 20 mA input instead of a positive signal, the
Q769B adapter requires a separate transformer and a current
loop isolator to perform properly. Connecting the adapter
directly to the PremierLink controller could cause the 4 to
20 mA output on the controller to be permanently dam-
aged. This condition is followed by a constant 36 vdc output
from the PremierLink™ economizer output (J-9).
HH57AC077
ENTHALPY
CONTROL
BRACKET
The Q769B adapter is supplied with female quick-connect
terminal that fits over the male quick-connect P1 and P on the
actuator.
To connect the Q769B adapter to the actuator, follow these
steps and refer to Fig. 26:
HH57AC078 ENTHALPY
SENSOR (USED WITH
ENTHALPY CONTROL
FOR DIFFERENTIAL
C7400A1004
ENTHALPY OPERATION)
+
1. Remove power from unit.
2. Remove the logic module from the actuator and discard.
3. Mount the adapter on the actuator by gently pushing the
adapter onto the P1 and P terminals on actuator.
NOTE: Be sure the plus (+) terminal on the adapter con-
nects to P1 on the actuator and the minus (–) terminal on
the adapter connects to P terminal on the actuator. See
Fig. 26.
MOUNTING PLATE
4. Using field-supplied wire, connect the plus (+) terminal
on the adapter to the plus (+) terminal on the loop isolator.
Connect the minus (–) terminal on the adapter to the
minus (–) terminal on the loop isolator.
Fig. 22 — Differential Enthalpy Control,
Sensor and Mounting Plate (33AMKITENT006)
5. Using the transformer supplied with the 40RM econo-
mizer, connect 24 vac to actuator terminals TR and TR1.
6. Connect the plus (+) terminal from the loop isolator to
J9-1 terminal on the PremierLink Controller. Connect the
minus (–) terminal from the loop isolator to J9-2 terminal
on the PremierLink Controller.
7. Restore power to unit.
Q769C — The Q769C adapter incorporates a female quick-
connect terminal that attaches to P1 and P male quick-connects
on the actuator.
IMPORTANT: It is recommended that the Q769C adapter
be used with a field-supplied 500-ohm resistor across the
terminals. Using the Q769C with actuator requires a sepa-
rate, field-supplied transformer because the actuator with
Q769C is a positive ground device. The PremierLink con-
trol is a negative ground device. The positive P1 terminal
on the Q769C goes to ground. See Fig. 27.
To connect the Q769C adapter to the actuator, follow the steps
below and refer to Fig. 27:
1. Remove power from unit.
Fig. 23 — Location of Differential Enthalpy
Controller and Return Air Enthalpy Sensor
(40RM Unit Shown)
2. Remove the logic module from the actuator and discard.
3. Mount the adapter onto the actuator by gently pushing the
adapter onto terminals P1 and P of actuator.
4. NOTE: Be sure the plus (+) terminal on the adapter
connects to P1 on the actuator and the minus (–) terminal
on the adapter connects to P terminal on the actuator.
See Fig. 27.
5. Using the transformer supplied with the 40RM econo-
mizer, connect 24 vac to actuator terminals TR and TR1.
6. Connect 500-ohm resistor (field supplied) to the plus (+)
and minus (–) terminals on adapter.
BRN
RED
B
TR
SO
TR1
BLK
C
D
A
RED
+
S
(RETURN AIR
ENTHALPY
SENSOR)
+
3
1
SR
2
+
GRAY
GRAY
WIRE HARNESS
IN UNIT
LED
NOTES:
7. Connect the plus (+) terminal from the adapter to J9-1
terminal on the PremierLink Controller. Connect the
minus (–) terminal from the adapter to J9-2 terminal on
the PremierLink Controller.
1. Remove factory-installed jumper across SR and + before con-
necting wires from return air sensor.
2. Switches shown in high outdoor air enthalpy state. Terminals 2
and 3 close on low outdoor air enthalpy relative to indoor air
enthalpy.
3. Remove sensor mounted on back of control and locate in out-
side airstream.
8. Restore power to unit.
Fig. 24 — Outside and Return Air Sensor Wiring
Connections for Differential Enthalpy Control
22
23
1
NOTE: To change the factory setting, use a /8-in. (3-mm)
flat-blade screwdriver to position the mode switch to the alter-
nate setting.
TR
24 VAC
24 VAC
TR1
TRANSFORMER
Table 5 — Actuator Drive Direction Settings
POSITION OF
T
SENSOR
SWITCH 3 AND THE DRIVE DIRECTION DRIVE DIRECTION
DIRECTION OF
SPRING RETURN
DRIVE
WITH A MINIMUM WITH A MAXIMUM
T1
PREMIERLINK
CONTROL
J9
INPUT SIGNAL
INPUT SIGNAL
Q769B
ADAPTER
DA/CCW
RA/CCW
DA/CW
CCW
CW
CW
CW
CCW
CCW
CW
+
-
-
+
P1
P
MIN.
POS
2
1
LOOP
ISOLATOR
RA/CW
CCW
LEGEND
+
-
-
M7415
ACTUATOR
CCW — Counterclockwise
CW — Clockwise
DA — Direct Action
RA — Reverse Action
+
Table 6 — Mode Selection Information
Fig. 26 — PremierLink™ Control Wiring to
Q769B Adapter and Actuator
MODE
SWITCHES
5
FACTORY
SETTINGS
SWITCH FUNCTIONS
VDC or mA
VDC
0 to 10 VDC (0 to 20 mA or
2 to 10 VDC (4 to 20 mA)
4
3
0 to 10
DA
Direct Acting (DA) or
Reverse Acting (RA)
TR
24 VAC
24 VAC
TR1
2
1
FIXED or AUTO
— or 6 to 9 VDC
FIXED
—
TRANSFORMER
(SEPARATE,
NOTE: The 6 to 9 VDC setting of Switch 1 overrides switch 4.
FIELD-SUPPLIED)
T
SENSOR
WIRING (See Fig. 29-30B) — The wires for power and
signal transmission from PremierLink to economizer are field-
supplied. To connect the Economizer Johnson Actuator to
PremierLink controller, connect the pink wire on actuator to
purple wire on PremierLink J9-1. See Fig. 30A.
For the Belimo Actuator, connect the white wire on the ac-
tuator to J9-1 on the PremierLink controller. See Fig. 30B.
T1
PREMIERLINK
CONTROL
J9
Q769C
ADAPTER
+
-
-
+
P1
P
500 OHM
RESISTOR
MIN.
POS
2
1
NOTE: To retrofit PremierLink Controller to older 4 to 20 mA
actuator, connect the red wire on the actuator wire harness to
the purple wire on the PremierLink J9-1. Connect the yellow
and white wires from the actuator wire harness to the 24-volt
AC transformer on equipment. See Fig. 29.
M7415
ACTUATOR
Fig. 27 — PremierLink Control Wiring to
Q769C Adapter and Actuator
IMPORTANT: Make sure the common side is grounded
for both the PremierLink power and the actuator power.
This is especially important if separate transformers are
used.
Economizer with Johnson 4 to 20 mA Actua-
tor — The PremierLink Controller can be connected to an
economizer that uses a Johnson 4 to 20 mA actuator.
DRIVE DIRECTION — The actuator drive direction is
dependent upon the position of Switch 3 and the spring return
direction. See Table 5. The actuator is factory set for Direct
Acting (DA) operation with Switch 3 in the DA position. An
increasing control signal drives the actuator away from the
spring return position in DA mode. The actuator should be
installed in the DA mode so damper will close automatically
on power shut down.
MOVE TO LEFT
FOR 4-20mA CONTROL
WITH PREMIERLINK
CONTROLLER
If Reverse Acting (RA) operation is desired, move Switch 3
to the RA position. An increasing control signal drives the
actuator toward the spring return position in RA mode.
mA
2-10
RA
VDC
0-10
DA
SWITCH SELECTION — The type of input control signal is
determined by the position of Switch 5. With Switch 5 in the
VDC position (factory setting), the signal is DC voltage. With
Switch 5 min the mA position, the input signal changes to
current input. See Fig. 28 and Table 6. The switch should be set
to mA for use with PremierLink controller.
AUTO
6-9
FIXED
—
Fig. 28 — Position of Actuator Mode Switches
(Factory Default)
24
WIRE HARNESS
FROM ACTUATOR
(5)
(4)
(3)
(2)
(1)
Gray
Output 20 VDC at 25 mA
White/Red Feedback 0 (2)-10 or 6-9 VDC
Red
Yellow
White
J9-1
Input 0 (2)-10 or 6-9 VDC, 0 (4)-20 mA
24 VAC/VDC
COM
TO 24V
TRANSFORMER
Fig. 29 — PremierLink™ Controller Wiring to
Johnson Actuator With Wire Harness
(M9206-GGC-2)
ECONOMIZER
12-PIN HARNESS
ACTUATOR
50TJ400812
M9206-GGC-2
RED
1
24 VAC
2
3
BRN
4
TRANSFORMER
GROUND
5
6
7
8
9
10
11
4-20mA TO
J9-1 ON
PNK
12
PREMIERLINK
CONTROLLER
PL6
12-PIN
FEMALE
8
7
6
5
12
11
10
9
4
3
2
1
MOLEX
CONNECTOR
CONNECTOR CABLE
Fig. 30A — PremierLink Control Wiring to Johnson Actuator Economizer Harness
25
BLACK
BLUE
TRANSFORMER
GROUND
4
3
5
2
500 OHM
RESISTOR
8
VIOLET
PINK
6
NOTE 1
NOTE 2
7
RUN
RED
24 VAC
1
WIRES FOR
OAT SENSOR
10
11
9
50HJ540573
ACTUATOR
ASSEMBLY
4-20 mA TO J9 ON
PREMIERLINK
BOARD
WHITE
DIRECT DRIVE
ACTUATOR
4-20 mA SIGNAL
12
ECONOMISER2 PLUG
NOTES:
1. Switch on actuator must be in run position for economizer to operate.
2. 50HJ540573 actuator consists of the 50HJ540567 actuator and a harness with 500-ohm resistor.
Fig. 30B — PremierLink™ Control Wiring to Belimo-Style Actuator EconoMi$er2 Harness
START-UP
Initial Operation and Test — Perform the following
procedure:
1. Apply 24 vac power to the control.
2. Connect the Service Tool to the phone jack service port of
the controller.
3. Using the Service Tool, upload the controller from
address 0, 31 at 9600 baud rate. The address may be set at
this time. Make sure that Service Tool is connected to
only one unit when changing the address.
The unit must be electrically grounded in accordance with
local codes and NEC ANSI/NFPA 70 (American National
Standards Institute/National Fire Protection Association).
Use the Carrier network communication software to start up
and configure the PremierLink™ controller.
MEMORY RESET — DIP switch 4 causes a non-volatile
(E-squared) memory reset to factory defaults after the switch
has been moved from position 0 to position 1 and the power
has been restored. To enable the feature again, the switch must
be put back to the 0 position and power must be restored; this
prevents subsequent resets to factory defaults if the switch is
left at position 1.
Changes can be made using the ComfortWORKS® soft-
ware, ComfortVIEW™ software, or Network Service Tool.
The Network Service Tool is a portable interface device that
allows the user to change system set-up and set points from a
zone sensor or terminal control module. During start-up, the
Carrier software can also be used to verify communication
with PremierLink controller.
To cause a reset of the non-volatile memory (to factory
defaults), turn the controller power off if it is on, move the
switch from position 1 to position 0, and then apply power to
the controller for a minimum of 5 seconds. At this point, no
action occurs, but the controller is now ready for the memory
to reset. Remove power to the controller again and move the
switch from position 0 to position 1. This time, when power is
applied, the memory will reset to factory defaults. The control-
ler address will return to bus 0 element 31, indicating that
memory reset occurred.
NOTE: All set-up and set point configurations are factory-
set and field-adjustable.
For specific operating instructions, refer to the literature
provided with user interface software.
Perform System Check-Out
1. Check correctness and tightness of all power and
communication connections.
2. At the unit, check fan and system controls for proper
operation.
Install Navigator™ Display Module — The Navi-
gator is a portable display module that conforms to NEMA 4
specifications for outdoor use in temperatures ranging from
–22 F (–30 C) to 158 F (70 C). The Navigator can be used
to configure and perform service diagnostics on machines
equipped with the PremierLink Controller. See Fig. 31.
The Navigator keypad contains eleven menu LEDs and one
Alarm Status LED, all of which are red. The Navigator is capa-
ble of displaying four 24-character lines of information on a
backlit liquid crystal display. The Navigator has four functional
3. At the unit, check electrical system and connections of
any optional electric heat.
NOTE: If optional electric heat is installed, Heat Type
must be changed to “1” (electric heat) from default of “0”
(gas heat).
4. Check to be sure the area around the unit is clear of
construction dirt and debris.
5. Check that final filters are installed in the unit. Dust and
debris can adversely affect system operation.
6. Verify that the PremierLink controls are properly
connected to the CCN bus.
26
The Navigator will upload the appropriate display tables
from PremierLink™ controller. A ‘Communication failure’
message will be displayed if any errors are encountered. Check
the wiring at the connector. After successful upload of informa-
tion, the Navigator begins its default display. All items in the
Run Status menu are displayed one at a time in this mode. An
example of the display in the default mode is:
C
o m fo r
t
T
L
N
A
i n k
V
I
G
A
O
R
TIME
EWT
12. 58
LW
54. 6
44. 1
T
°
SETP
F
°
F
44. 0
°
F
M
O D E
Alarm Status
Ru
n
S
tatus
S
ervice
T
est
T
em
p
eratu
re
SAT 54.2 °F
s
P
ressure
s
S
etpoints
Inp
uts
Ou
SUPPLY AIR TEMPERATURE
tputs
C
on
figuration
Ti
m
e
C
lock
perating
E
S
C
O
M
od
es
A
larm
s
The different levels of modes can be accessed with the
Navigator. See the base unit controls and troubleshooting guide
for more information.
ENTER
Pressing any key while in the default display mode will
cause the Navigator to enter its manual mode. In this mode, all
sub-modes and items within the eleven top level configuration
modes, denoted on the display screen, can be accessed. The
Navigator automatically returns to the default display mode af-
Fig. 31 — Navigator™ Module in Display Mode
ter 60 minutes of no keypad activity. Pressing the
ESCAPE
and
ENTER
keys simultaneously while the unit displays “Select
keys which are the up arrow ( ), down arrow ( ),
a menu item” will also log the device out and return it to its de-
fault display mode.
and
keys.
ESCAPE
ENTER
INSTALLATION — The Navigator display module is intend-
ed to be a mobile device, so there are no holes in the device for
permanent mounting. The module has a magnetic mount that is
strong enough to hold the device in place on any clean, dry
metal surface.
To enter LEN (local equipment network) mode:
1. Remove power by removing connection to J1.
NAVIGATING THROUGH MENU STRUCTURES — The
arrow keys are used to scroll up and down to select sub-modes
within a mode or items within a sub-mode. See the base unit
troubleshooting guide for menu structure. The
key is
ENTER
used to select a menu item or to accept data entry. The
key is used to exit to the next highest mode or to
ESCAPE
cancel data entry. The sub-mode and item displays will wrap
around with the last and first items separated by a line of dashes
on the display. The ‘>’ symbol is the pointer and is located at
the left side of the display.
2. Remove connection to J2 (to avoid communication prob-
lems with equipment).
3. Position DIP switch to 0 (ON) position.
4. Restore power by reconnecting J1.
5. Plug in Navigator.
Press the
key to display “Select a menu item” on
ESCAPE
the screen. This is the top level and the arrow keys are used to
move the red LED to the one of the 11 desired modes. Pressing
Controller is now in LEN mode and will support the
Navigator device.
To return CCN mode:
will display the sub-modes within a top level mode.
ENTER
1. Remove power to controller by removing connection
to J1.
2. Remove connection to J2 (to avoid communication
problems with equipment).
3. Position DIP switch to 1 (OFF) position.
4. Reconnect J2.
5. Restore power by reconnecting J1.
Once in a sub-mode, use the arrow keys to move the pointer
(‘>’) to the desired sub-mode. Up to four sub-modes will be
displayed on the Navigator at one time. Continue pressing the
arrow keys as needed to find the desired sub-mode.
As an example, Press the
key to display “Select
ESCAPE
a menu item” on the screen. Press the down arrow until the red
LED is lit for the Setpoints menu. Press the key to
ENTER
Controller is now in CCN mode at the previously config-
ured address and baud rate.
display the first four sub-modes in the Setpoints menu:
>SETP
OATL
NTLO
UHDB
The Navigator module is powered through the PremierLink
controller. The Navigator has a modular telephone style (RJ14)
connector and should be connected to terminal block TB3 in
the control box. This device is intended for use on the LEN
communications bus only. Do NOT connect to the Navigator
while in CCN mode. Communication problems may occur.
OPERATION — To use the Navigator, plug the RJ14 connec-
tor into the RJ14 port. On power up, the Navigator displays:
PremierLink
Navigator
By
Carrier
27
To access the sub-mode to change the Unoccupied OAT
Lockout Setpoint, press the down arrow to scroll down until
the Navigator™ module display reads:
OUTDOOR AIR TEMPERATURE — Temperature of the
air leaving the unit downstream of any cool or heat sources,
measured by a 10K thermistor (Type III). This sensor is
required for proper function of the heating, cooling, and the
economizer.
SETP
OATL
>NTLO
UHDB
Outdoor Air
Temperature:
Display Units:
Default Value:
Degrees F (Degrees C)
0.0
Display Range: –40.0 to 245.0
Network Access: Read/Write
To view an expansion of the sub-mode, press the
ENTER
keys simultaneously and the Navigator will
and
ESCAPE
display:
>NTLO
CONTROL SET POINT — This point displays the current
controlling set point when a heat or cool mode is active. If there
is not an active heat or cool set point, the set point of the last
mode is displayed. Upon reset or start-up, the proper cooling
set point is displayed, depending on occupancy. In the thermo-
stat mode, this point is not used for equipment control.
UNOCC. OAT LOCKOUT
TEMP
The Navigator will remain in the expanded display mode
Control Set Point: Display Units:
Default Value:
Degrees F (Degrees C)
Unoccupied Cool
Setpoint
until the
key is pressed. Use the arrow keys to view
ESCAPE
expansions for any of the other sub-modes within the Setpoint
mode.
Display Range: 35 to 110
Network Access: Read Only
Password Protection — If an area is entered that is
password protected or an item is selected for change that is
password protected, the Navigator will display:
Enter Password
1111 (default password)
The first digit of the password will be flashing. Hold either
of the arrow keys down to change the value of the first digit (if
COOLING PERCENT TOTAL CAPACITY — The Cooling
Percent Total Capacity point is used to display the current
Cooling Capacity. When cooling is enabled, the percent of
cooling being delivered is determined by the following formula
for the number of compressor stages confirmed:
% Output Capacity = (# of active stages/Total stages) * 100.
Cooling Percent
necessary) and press
ENTER
the remaining three digits.
to accept. Repeat the process for
Total Capacity: Display Units:
Default Value:
% output capacity
0
Display Range: 0 to 100
The message “Invalid Password” is displayed if the pass-
word is not correct. The password can not be disabled from the
Navigator, nor can it be changed.
Network Access: Read Only
HEATING PERCENT TOTAL CAPACITY — The Heating
Percent Total Capacity point is used to display the current
Heating Capacity.
When heat is enabled, the percent of heat being delivered is
determined by the following formula for electric heat:
Forcing Values and Configuring Items — Cer-
tain items are allowed to be forced and other items are user-
configurable. Both of these changes can be made using the
Navigator.
% Output Capacity = (# of active stages/Total stages) * 100
Heating Percent
CONFIGURATION
Total Capacity: Display Units:
Default Value:
% output capacity
0
The following sections describe the computer configuration
screens which are used to configure the PremierLink™ con-
troller. The screens shown may be displayed differently when
using different Carrier software.
Display Range: 0 to 100
Network Access: Read Only
ECONOMIZER ACTIVE — The Economizer Active point
displays the status of the economizer for free cooling. When
the outdoor conditions match the desired indoor conditions, the
economizer will be enabled for outdoor air assisted cooling.
Points Display Screen — The Points Display screen is
used to monitor and change the PremierLink controller set
points. See Table 7.
SPACE TEMPERATURE — This point displays the space
temperature from the 10K thermistor (Type III) located in the
space.
Economizer
Active:
Display Units:
Default Value:
Discrete ASCII
No
Display Range: No/Yes
Space
Temperature:
Network Access: Read Only
Display Units:
Default Value:
Degrees F (Degrees C)
–40.0
SUPPLY FAN RELAY — This point displays the command-
ed state of the Supply Fan Relay.
Supply Fan
Relay:
Display Range: –40.0 to 245.0
Network Access: Read/Write
Display Units:
Default Value:
Display Range: Off/On
Network Access: Read/Write
Discrete ASCII
Off
SUPPLY AIR TEMPERATURE — The Supply Air Temper-
ature point displays the temperature of the air leaving the unit,
downstream of any cool or heat sources. Temperature is mea-
sured by a 10K thermistor (Type III). This sensor is required
for proper function of the heating, cooling, and the economizer.
Supply Air
Temperature:
Display Units:
Default Value:
Degrees F (Degrees C)
0.0
Display Range: –40.0 to 245.0
Network Access: Read/Write
28
Table 7 — Points Display
DESCRIPTION
VALUE
72.2
67.1
48.8
0.0
0
0
Yes
On
On
26.2
20
Clean
Off
UNITS
dF
dF
dF
dF
STATUS
FORCE
NAME
SPT
SAT
Space Temperature
Supply Air Temperature
Outdoor Air Temperature
Control Setpoint
Cooling % Total Capacity
Heating % Total Capacity
Economizer Active
Supply Fan Relay
Supply Fan Status
Economizer Position
Current Min Damper Pos
Filter Status
OAT
CLSP
CCAP
HCAP
ECOS
SF
%
%
SFS
%
%
ECONPOS
IQMP
FLTS
RMTOCC
HS1
Remote Occupied Mode
Heat Stage 1
Off
Heat Stage 2
Off
HS2
Heat 3/Exhaust/Rev Valve
Enthalpy
Indoor Air Quality
Indoor Air Quality Setpt
Outdoor Air Quality
Fire Shutdown
Off
H3_EX_RV
ENTH
IAQI
IAQS
OAQ
Low
367.9
1050.0
0.0
Normal
0.0
Sensor failure
FSD
STO
SPT Offset
^F
Compressor 1
Compressor 2
Compressor Safety
Off
Off
Off
CMP1
CMP2
CMPSAFE
NOTE: Bold values indicate points that can be forced through communications.
SUPPLY FAN STATUS — This point displays the Supply
Fan status if controller is configured to receive input from the
Supply Fan. Otherwise this point will display the output state
of the Supply Fan Relay. This mode can only be used when the
controller is in sensor control mode.
FILTER STATUS — The filter status point will be shown as
“CLEAN” until the run time of the fan exceeds the configured
Filter Timer Hours. When the user-configured Filter Timer
Hours has been exceeded, the Filter Status will display
“DIRTY” and a CCN alarm will be generated. Forcing the
point to “CLEAN” will clear the alarm condition and will reset
the timer. (Setting the configured filter timer value to zero will
provide the same function.) The value of the timer is stored in
EEPROM to protect it in the event of a power failure. This is
done periodically every 24 hours. The filter timer function only
operates if the configured filter timer value (FLTTMR) is a
non-zero number.
Supply Fan
Status:
Display Units:
Default Value:
Discrete ASCII
Off
Display Range: Off/On
Network Access: Read Only
ECONOMIZER DAMPER POSITION — This point dis-
plays the current commanded damper position of the
economizer 4 to 20 mA on the J-9 connector. The 4 to 20 mA
signal is scaled linearly over the range of 0 to 100% of the Sup-
ply Fan Relay.
Filter Status:
Display Units:
Default Value:
Discrete ASCII
Clean
Display Range: Clean/Dirty
Network Access: Read/Write
Economizer
Position:
REMOTE OCCUPIED MODE — This point displays the
status of the remote time clock input. This input is only avail-
able when the controller is being used in sensor control mode.
When the Remote Start point is on, and the zone controller is
not controlled by a Linkage Thermostat, the controller will
function in an occupied mode. When the Remote Start point is
off, the controller will revert to its own occupancy schedule.
Display Units: % Open
Default Value:
0
Display Range: 0 to 100
Network Access: Read/Write
CURRENT MINIMUM DAMPER POSITION — This point
displays the current minimum damper position if an Indoor Air
Quality routine is not active. If an Indoor Air Quality sensor is
installed and the differential air quality set point has been
exceeded, this point will display the current calculated mini-
mum position deemed necessary to maintain the air quality in
the space.
Remote
Occupied Mode: Display Units: Discrete ASCII
Default Value:
Off
Display Range: Off/On
Network Access: Read/Write
Current Minimum
HEAT STAGE 1 — The Heat Stage 1 point provides the state
of the Heating 1 output.
Damper Position: Display Units: % Open
Default Value:
0
Display Range: 0 to 100
Network Access: Read Only
Heating Stage 1: Display Units:
Default Value:
Discrete ASCII
Off
Display Range: Off/On
Network Access: Read Only
29
HEAT STAGE 2 — The Heat Stage 2 point provides the state
of the Heating 2 output.
FIRE SHUTDOWN — While in sensor control mode, this
point can be used to receive a signal from a smoke detector or
fire panel to shut down the Supply Fan, all heating and cooling
stages, and to close the economizer.
Heating Stage 2: Display Units:
Default Value:
Discrete ASCII
Off
Display Range: Off/On
Fire Shutdown: Display Units: Discrete ASCII
Network Access: Read Only
Default Value:
Normal
Display Range: Normal/Alarm
Network Access: Read/Write
HEAT STAGE 3, EXHAUST FAN, OR REVERSING
VALVE — This point displays the commanded state of auxil-
iary output. This output can be configured to control a third
stage of heat, an exhaust fan or a reversing valve on some heat
pump units.
SPT OFFSET — This point displays the value of the Space
Temperature offset calculated from the input of a T56 sensor
slide bar.
In the exhaust fan mode with continuous exhaust con-
figured, this point may control a bank of lights or another
indicator that should remain ON whenever the controller is in
the occupied mode.
SPT Offset:
Display Units:
Delta Degrees F
(Delta Degrees C)
0.0
Default Value:
Display Range: –15 to 15
Network Access: Read/Write
Heat 3, Exhaust,
Rev Valve:
Display Units:
Default Value:
Discrete ASCII
Off
COMPRESSOR 1 — This point displays the commanded
state of the compressor 1 output.
Compressor 1:
Display Range: Off/On
Display Units: Discrete ASCII
Network Access: Read Only
Default Value:
Off
ENTHALPY — This point displays the current status of an
outdoor air or differential enthalpy input. This point may be
broadcast to other controllers or received from a controller
which supports global broadcast of the ENTH variable.
Display Range: Off/On
Network Access: Read Only
COMPRESSOR 2 — This point displays the commanded
state of the compressor 2 output.
Compressor 2:
Enthalpy:
Display Units:
Default Value:
Discrete ASCII
High
Display Units: Discrete ASCII
Range:
Default Value:
Off/On
Off
Display Range: High/Low
Network Access: Read/Write
Network Access: Read Only
INDOOR AIR QUALITY (IAQ) — The Air Quality point
displays the indoor air quality reading from a CO2 sensor
installed in the space. The CO2 sensor maintains differential
indoor air quality for demand control ventilation per ASHRAE
Standard 62-1999. The controller can be configured to generate
an alarm when the control is in occupied mode and the CO2
level exceeds the high or low limit set.
COMPRESSOR SAFETY — When the controller is in
sensor mode, this point can be used to monitor the status of the
compressor trouble output supplied with some equipment.
When the input is detected, the controller will energize all
available stages to satisfy the demand and issue a compressor
trouble alert on the communications network.
Compressor
Indoor Air
Safety:
Display Units: Discrete ASCII
Display Range: Off/On
Quality (ppm):
Display Units:
Default Value:
Display Range: 0 to 5000
Network Access: Read/Write
None shown (parts per
million implied)
0
Default Value:
Off
Network Access: Read Only
Thermostat Control Input Screen — The Thermo-
stat Control Input Display is used to display the input status of
equipment requests from the thermostat (TSTAT). See Table 8.
INDOOR AIR QUALITY SET POINT — This point dis-
plays the current Indoor Air Quality set point. The set point is
determined by the configured Indoor Air Quality differential
and the current outdoor air quality value. If an outdoor air
quality value is not received, the controller will assume a
default outdoor level of 400 ppm and calculate the set point
using that value.
Alarm Service Configuration Screen — The Alarm
Service Configuration is used to configure the alarms used on
the PremierLink™ controller. See Table 9.
ALARM ROUTING CONTROL — The Alarm Routing
Control indicates which CCN system software or devices will
receive and process alarms sent by the PremierLink controller.
This decision consists of eight digits which can be set to zero or
one. A setting of one indicates alarms should be sent to this
device. A setting of zero disables alarm processing for that
device. Currently the corresponding digits are configured for
the following devices: first digit is for user interface software
(ComfortWORKS®, ComfortVIEW™, etc.); second digit is
for Autodial Gateway or Telink; fourth digit is for Alarm Print-
er Interface Module, DataLINK™ module; digits 3 and 5
through 8 are unused.
Indoor Air Quality
Set Point:
Display Units:
Default Value:
Display Range: 0 to 5000
Network Access: Read Only
None shown (parts per
million implied)
0
OUTDOOR AIR QUALITY — This point displays the read-
ing from an outdoor air quality sensor. This point supports
global broadcast of outdoor air quality on a network.
Outdoor Air Quality
Set Point:
Display Units:
None shown (parts per
million implied)
0
Alarm Routing
Control:
Range:
Default Value:
00000000 to 1111111
00000000
Default Value:
Display Range: 0 to 5000
Network Access: Read/Write
30
Table 8 — Thermostat Control Input Display
DESCRIPTION
VALUE
On
UNITS
STATUS
FORCE
NAME
Y1
Y2
W1
W2
G
Y1 - Call for Cool 1
Y2 - Call for Cool 2
W1 - Call for Heat 1
W2 - Call for Heat 2
G - Call for Fan
On
Off
Off
On
ALARM RE-ALARM TIME — This decision is used to con-
figure the number of minutes that will elapse between
re-alarms. A re-alarm occurs when the condition that caused
the initial alarm continues to persist for the number of minutes
specified. Re-alarming continues to occur at the specified
interval until the alarm condition no longer exists.
Table 9 — Alarm Service Configuration
DESCRIPTION
Alarm Control
VALUE
UNITS
NAME
Alarm Routing Control
Realarm Time
Control Temp Hysteresis
Supply Air Temperature
Low Limit
00000000
ALRMCNT
REALARM
SPTHYS
0
5.0
min
^F
Re-Alarm Time: Display Units: Minutes
Display Range: 0 to 1440
Default Value:
0 (Disabled)
45.0
150.0
dF
dF
LOWLIM
HIGHLIM
High Limit
CONTROL TEMPERATURE HYSTERESIS — This con-
figuration defines the range above the high set point and below
the low set point the space temperature must exceed for an
alarm condition to exist during occupied hours.
IAQ High Alert Limit
Low Limit
High Limit
0.0
1200.0
LOWLIM
HIGHLIM
For example, if the current setpoint is 75 F and the hystere-
sis value is 5° F, an alarm will be generated if space tempera-
ture exceeds the low limit of 70 F or the high limit of 80 F.
Controller Identification Screen — The controller
identification screen contains reference information used to
identify the PremierLink™ controller. See Table 10.
DESCRIPTION — The Description point displays the type of
device.
LOCATION — The Location point shows the location of the
device.
SOFTWARE PART NUMBER — The Software Part Num-
ber indicates the part number of the software being used.
MODEL NUMBER — The Model Number indicates the
model number of the device being used.
SERIAL NUMBER — The Serial Number indicates the serial
number of the device being used.
REFERENCE NUMBER — The Reference Number indi-
cates the version of the software being used.
Control
Temperature
Hysteresis:
Display Units:
Delta Degrees F
(Delta Degrees C)
1.0 to 100.0
5.0
Range:
Default Value:
SUPPLY AIR TEMPERATURE — HIGH LIMIT — The
Supply Air Temperature High Limit alarm is used to monitor
the value of the supply air temperature within a specified range.
If the supply air temperature becomes too high, an alarm condi-
tion will exist.
Supply Air
Temperature
High Limit:
Display Units:
Display Range: –40.0 to 245.0
Default Value: 150.0
Degrees F (Degrees C)
Table 10 — Controller Identification
DESCRIPTION
Description:
Location:
Software Part Number: CESR131269-04*
Model Number:
Serial Number:
VALUE UNITS NAME
Rooftop Control
DevDesc
SUPPLY AIR TEMPERATURE — LOW LIMIT — The
Supply Air Temperature Low Limit alarm is used to monitor
the value of the supply air temperature within a specified range.
If the supply air temperature becomes too low, an alarm condi-
tion will exist.
Location
PartNum
ModelNum
SerialNo
RefNum
Supply Air
Reference Number:
Version 1.3
Temperature
Low Limit:
Display Units: Degrees F (Degrees C)
Display Range: –40.0 to 245.0
Default Value: 45.0
*Software part number CESR131269-03 is version 1.2.
Holiday Configuration Screen — The Holiday Con-
figuration screen is used by the PremierLink controller to store
configuration fields for up to twelve holidays. See Table 11.
START MONTH — The Start Month field is used to config-
ure the month that the holiday will start. The numbers 1
through 12 are used to indicate which month is specified.
INDOOR AIR QUALITY ALERT LIMIT — The Indoor-
Air Quality Alert Limit alarm defines the allowable CO2 levels
during occupied periods. If the CO2 levels become too low or
too high during occupied periods, an alarm condition will exist.
Indoor Air Quality
Low Limit:
Display Units: PPM (implied)
Display Range: 0.0 to 5000.0
Default Value: 0.0
Start Month:
Range:
Default Value:
1 to 12
1 (January)
START DAY — The Start Day field is used to determine
which day the holiday will start.
Start Day:
Indoor Air Quality
High Limit:
Display Units: PPM (implied)
Display Range: 0.0 to 5000.0
Default Value: 1200.0
Range:
Default Value:
1 to 31
1
31
DURATION — The Duration field indicates how long the
holiday will last (in days).
OCCUPIED FROM — This field is used to configure the
hour and minute, in military time, that the mode for the
PremierLink controller will switch to occupied.
Duration:
Range:
Default Value:
0 to 365
0
Occupied From: Units:
Range:
Hours:Minutes
00:00 to 24:00
(Minutes 00 to 59)
00:00
As an example, if a Holiday is configured for Month 2,
Day 5, Duration 2, then the Holiday will start February 5 and
end February 7.
Default Value:
OCCUPIED TO — This field is used to configure the hour
and minute, in military time, that the mode for the PremierLink
controller switches from occupied to unoccupied.
Table 11 — Holiday Configuration
DESCRIPTION
Start Month
Start Day
VALUE
UNITS
NAME
MONTH
DAY
Occupied To:
Units:
Range:
Hours:Minutes
00:00 to 24:00
(Minutes 00 to 59)
24:00
1
1
0
Duration
DURATION
Default Value:
Table 12 — Occupancy Configuration
Occupancy Configuration Screen — The Occu-
pancy Configuration Screen is used to configure the occupancy
schedule for the PremierLink™ controller. See Table 12.
DESCRIPTION
VALUE
0
UNITS
NAME
Manual Override Hours
Period 1: Day of Week
Period 1: Occupied from
Period 1: Occupied to
Period 2: Day of Week
Period 2: Occupied from
Period 2: Occupied to
Period 3: Day of Week
Period 3: Occupied from
Period 3: Occupied to
Period 4: Day of Week
Period 4: Occupied from
Period 4: Occupied to
Period 5: Day of Week
Period 5: Occupied from
Period 5: Occupied to
Period 6: Day of Week
Period 6: Occupied from
Period 6: Occupied to
Period 7: Day of Week
Period 7: Occupied from
Period 7: Occupied to
Period 8: Day of Week
Period 8: Occupied from
Period 8: Occupied to
hours
OVRD
MANUAL OVERRIDE HOURS — The Manual Override
Hours point is used to command a timed override by entering
the number of hours the override will be in effect. If the occu-
pancy schedule is occupied when this number is downloaded,
the current occupancy period will be extended by the number
of hours downloaded.
If the current occupancy period is unoccupied when the
occupancy override is initiated, the mode will change to occu-
pied for the duration of the number of hours downloaded. If the
occupancy override is due to end after the start of the next
occupancy period, the mode will transition from occupancy
override to occupied without becoming unoccupied and the
occupancy override timer will be reset.
11111111
00:00
24:00
00000000
00:00
24:00
00000000
00:00
24:00
00000000
00:00
24:00
00000000
00:00
24:00
00000000
00:00
24:00
00000000
00:00
24:00
00000000
00:00
DOW1
OCC1
UNOCC1
DOW2
OCC2
UNOCC2
DOW3
OCC3
UNOCC3
DOW4
OCC4
UNOCC4
DOW5
OCC5
UNOCC5
DOW6
OCC6
UNOCC6
DOW7
OCC7
UNOCC7
DOW8
OCC8
An active occupancy override or a pending occupancy
override may be canceled by downloading a zero to this
configuration. Once a number other than zero has been down-
loaded to this configuration, any subsequent downloads of any
value other than zero will be ignored by the controller.
Manual Override
Hours:
Units:
Hours
0 to 4
0
Range:
Default Value:
OCCUPANCY SCHEDULE — For flexibility of scheduling,
the occupancy programming is broken into eight separate peri-
ods. For each period the schedule contains the following fields:
Day of Week, Occupied From, and Occupied To.
24:00
UNOCC8
DAY OF WEEK — The Day of Week configuration consists
of eight fields corresponding to the seven days of the week and
a holiday field in the following order: Monday, Tuesday,
Wednesday, Thursday, Friday, Saturday, Sunday, Holiday.
Set Point Screen — The Set Point screen is used to con-
figure the occupied and unoccupied set points. See Table 13.
OCCUPIED LOW — The Occupied Low set point describes
the low temperature limit of the space during Occupied mode.
It is displayed as:
M T W Th Fr Sa Su Hol
Occupied Low: Units:
Range:
Degrees F (Degrees C)
40.0 to 90.0
70.0
Default Value:
0
0 0 0 0
0
0
0
If a 1 is configured in the corresponding place for a certain
day of the week, the related “Occupied from” and “Occupied
to” times for that period will take effect on that day of the
week. If a 1 is placed in the holiday field, the related times will
take effect on a day configured as a holiday. A zero means the
schedule period will not apply to that day.
OCCUPIED HIGH — The Occupied High set point describes
the high temperature limit of the space during Occupied mode.
Occupied High: Units:
Range:
Degrees F (Degrees C)
45.0 to 99.9
74.0
Default Value:
UNOCCUPIED LOW — The Unoccupied Low set point
describes the low temperature limit of the space during
Unoccupied mode.
Day of week:
Range:
0 or 1
Default Values: 11111111 for period 1,
00000000 for the rest of
the periods
Unoccupied Low: Units:
Range:
Degrees F (Degrees C)
40.0 to 90.0
75.0
Default Value:
32
UNOCCUPIED HIGH — The Unoccupied High set point de-
scribes the high temperature limit of the space during Unoccu-
pied mode.
IAQ Pre-Occupancy Purge Algorithm shall use this value
whenever Outdoor Air Temperature is above or at Unoccupied
OAT Lockout Temperature, and also OAT is above Occupied
Cool Set Point or Enthalpy is High. Whenever OAT>=NTLO
and OAT<=OCSP and Enthalpy is Low, the Purge algorithm
will set Purge Minimum Damper Position to 100%.
Unoccupied High: Units:
Range:
Degrees F (Degrees C)
45.0 to 99.9
90.0
Default Value:
High Temperature
Minimum
Position:
HIGH OAT LIMIT FOR IAQ PRE-OCCUPANCY
PURGE — The High OAT unit for IAQ Pre-Occupancy Purge
function determines the Economizer Damper position used for
IAQ Pre-Occupancy Purge.
Units:
Percent
0 to 100
35.0
Range:
Default Value:
High OAT
Limit:
Units:
Degrees F (Degrees C)
55.0 to 75.0
65.0
POWER EXHAUST SET POINT — The Power Exhaust Set
Point describes the minimum damper position that the Econo-
mizer Damper must be before the power exhaust fan will be
energized.
Range:
Default Value:
UNOCCUPIED OAT LOCKOUT TEMPERATURE —
The Unoccupied OAT Lockout Temperature describes the low-
est Outdoor Air Temperature allowed for Unoccupied Free
Cooling operation. This function is also used by IAQ Pre-
Occupancy Purge control to determine the minimum damper
position for IAQ Purge.
Power Exhaust
Set Point:
Units:
Percent
0 to 100
50.0
Range:
Default Value:
Unoccupied
OAT Lockout:
Table 13 — Set Point Configuration
Units:
Degrees F (Degrees C)
40.0 to 70.0
50.0
DESCRIPTION
VALUE
UNITS
NAME
Range:
Setpoints
Default Value:
Occupied Low Setpoint
Occupied High Setpoint
Unoccupied Low Setpoint
Unoccupied High Setpoint
Hi OAT Limit for
IAQ Pre-Occ Purge
Unocc. OAT Lockout TEMP
Unocc. Heating Deadband
Unocc. Cooling Deadband
Low Temp. Min. Position
Hi Temp. Min. Position
70.0
74.0
69.0
75.0
dF
dF
dF
dF
dF
OHSP
OCSP
UHSP
UCSP
OATL
UNOCCUPIED HEATING DEADBAND — The Unoccu-
pied Heating Deadband describes the space temperature value
which has to be achieved while unoccupied Heating before the
unoccupied Heating mode will turn off.
65.0
Unoccupied
Heating
Deadband:
50.0
1.0
1.0
10
35
50
dF
^F
^F
%
%
%
NTLO
UHDB
UCDB
LTMP
HTMP
PES
Units:
Degrees F (Degrees C)
0.0 to 10.0
1.0
Range:
Default Value:
UNOCCUPIED COOLING DEADBAND — The Unoccu-
pied Cooling Deadband describes the space temperature value
which has to be achieved while unoccupied Cooling before the
unoccupied Cooling mode will turn off.
Power Exhaust Setpoint
Service Configuration Selection Screen — The
Service Configuration Selection screen is used to configure
the service set points of the PremierLink™ controller. See
Table 14.
COOLING PID — The PremierLink controller reads the
space temperature sensor and compares the temperature to he
current high set point. If it exceeds the set point, and cooling is
configured and available, the controller then calculates the re-
quired supply air temperature to satisfy the given conditions.
The Cooling PID (Proportional/Integral/Derivative) in-
cludes the following set points: Proportional Gain, Integral
Gain, Derivative Gain, and Starting Value.
Proportional Gain: Range:
Default Value:
Unoccupied
Cooling
Deadband:
Units:
Delta Degrees F
(Delta Degrees C)
0.0 to 10.0
Range:
Default Value:
1.0
LOW TEMPERATURE MINIMUM POSITION — The Low
Temperature Minimum Position describes the low temperature
limit for Low Outdoor Air Temperature conditions.
IAQ Pre-Occupancy Purge Algorithm will use this value
whenever Outdoor Air Temperature is below Unoccupied OAT
Lockout Temperature.
0.0 to 40.0
6.0
0.0 to 10.0
3.0
0.0 to 20.0
5.0
Degrees F
40.0 to 90.0
70.0
Low Temperature
Minimum
Position:
Integral Gain:
Derivative Gain:
Starting Value:
Range:
Units:
Percent
0 to 100
10.0
Default Value:
Range:
Range:
Default Value:
Units:
Range:
Default Value:
Default Value:
HIGH TEMPERATURE MINIMUM POSITION — The High
Temperature Minimum Position specifies the value for Purge
Minimum Damper Position for High Outdoor Air temperature
conditions.
33
Also, the cooling is controlled so that the supply air tempera-
ture does not fall below 50 F when cooling is active.
If number of stages is set to 1, then the SAT CMP2 LOCK-
OUT TEMP will be used as the low supply air set point.
Table 14 — Service Configuration Selection
DESCRIPTION
VALUE UNITS NAME
Cooling PID
Proportional Gain
Integral Gain
6.0
3.0
KP
KI
Number of Stages: Range:
Default Value:
1 to 3
2
Derivative Gain
5.0
KD
The Time Guards must be set to Enable for output to a
compressor, and set to Disable for output to a valve or
compressor unloader.
Starting Value
70.0 dF
STARTVAL
Staged Cooling
Total Number of Stages
Stage 1 Time Guard
Stage 2 Time Guard
Stage 3 Time Guard
Heating PID
2
STAGES
TG1
TG2
Stage 1
Time Guard:
Enable
Enable
Disable
Range:
Default Value:
Disable/Enable
Enable
TG3
Stage 2
Time Guard:
Range:
Default Value:
Disable/Enable
Enable
Proportional Gain
Integral Gain
Derivative Gain
6.0
3.0
5.0
KP
KI
KD
Stage 3
Time Guard:
Range:
Default Value:
Disable/Enable
Disable
Starting Value
75.0 dF
STARTVAL
Staged Heating
HEATING PID — The PremierLink™ controller determines
if a heating demand exists in the space. The controller reads the
space temperature sensor and compares the temperature to the
current low set point (including any calculated offset value
from a T56 or T57 sensor) during occupied periods. If it is
below the set point, and heating is configured and available, it
then calculates the required supply air temperature to satisfy
the given conditions. The calculated value (heating submaster
reference) is compared to the actual supply-air temperature and
the output is then adjusted to satisfy conditions by using a
Proportional/Integral/Derivative (PID) loop.
Total Number of Stages
Stage 1 Time Guard
Stage 2 Time Guard
Stage 3 Time Guard
IAQ PID
Proportional Gain
Integral Gain
Derivative Gain
2
Enable
Enable
Enable
STAGES
TG1
TG2
TG3
0.1
0.0
0.0
0.0
KP
KI
KD
STARTVAL
Starting Value
Economizer PID
%
The Heating PID includes the following set points: Propor-
tional Gain, Integral Gain, Derivative Gain, and Starting Value.
Proportional Gain
Integral Gain
Derivative Gain
-4.0
-2.0
-3.0
70.0 dF
-5.5
60
0
25 ^F
20
100
On
45.0 dF
55.0 dF
50.0 dF
Off
KP
KI
KD
STARTVAL
ESG
Proportional Gain: Range:
Default Value:
–100.0 to 100.0
6.0
Starting Value
Submaster Gain Limit
Submaster Center Value
Damper Movement Band
OAT Temp Band
Integral Gain:
Derivative Gain:
Starting Value:
Range:
–5.0 to 5.0
3.0
–20.0 to 20.0
5.0
Degrees F
40.0 to 120.0
75.0
Default Value:
%
%
CTRVAL
ECONBAND
TEMPBAND
MDP
LOWMDP
DXCTLO
DXLOCK
SATL01
SATL02
TGO
MODPE
SFSENABL
LIMT
RATTRIM
SATTRIM
Range:
Default Value:
Units:
Range:
Default Value:
Minimum Damper Position
Low Temp MDP Override
DX Cooling Lockout
DX Cooling Lockout Temp
SAT CMP1 Lockout Temp
SAT CMP2 Lockout Temp
Time Guard Override
Continuous Power Exhaust
Supply Fan Status Enable
Max Offset Adjustment
Space Temp Trim
Supply Air Temp Trim
%
%
STAGED HEATING — The Staged Heating function is used
for two-position valves or for electric heat (1 or 2 stages). The
staging function uses the heating submaster reference value
from the PID and compares it to the supply air temperature to
calculate the required number of output stages to energize.
Disable
Disable
2.0 ^F
Number of Stages: Range:
Default Value:
1 to 3
2
0.0 ^F
0.0 ^F
Stage 1
Time Guard:
Range:
Default Value:
Disable/Enable
Enable
Stage 2
STAGED COOLING — The staging function is used for DX
cooling (1 or 2 stages). The staging function uses the cooling
submaster reference from the PID and compares the value to
the supply air temperature to calculate the required number of
output stages to energize.
Time Guard delays are provided to allow for up to 2 stages
of compression. Also, a DX Lockout will prevent operation
of the DX cooling if the outdoor air temperature is below this
value.
The cooling algorithm controls the valve or stages of DX
cooling to prevent the space temperature from exceeding the
current cooling set point (which includes any calculated offset
value from a T56 sensor slide bar during occupied periods).
Time Guard:
Range:
Disable/Enable
Enable
Default Value:
Stage 3
Time Guard:
Range:
Default Value:
Disable/Enable
Enable
IAQ PID — The proportional gain affects the response of PID
calculations for staged control. The gain is also used for two-
position control to establish the hysteresis between on and off.
A larger gain speeds response time or reduces the hysteresis,
while a smaller gain requires a larger error to generate the same
response to changes in Indoor Air Quality. Enter the desired
proportional gain for the Indoor Air Quality control algorithm.
34
The integral gain affects the PID calculation; an increase
will make the IAQ submaster reference change greater as the
error in indoor air quality increases. The integral gain should be
selected to eliminate proportional droop without overshoot.
Enter the desired integral gain for the Indoor Air Quality con-
trol algorithm.
SUBMASTER CENTER VALUE — The Submaster Center
Value is used to define the submaster loop center value which
defines the starting point of the loop. This value typically repre-
sents the midpoint of the range of the device being controlled.
Submaster Center
Value Reference:
Units:
Percent
0 to 100
60
Range:
The Derivative Gain is typically not required for Indoor Air
Quality operation and should be left at the default value.
Default Value:
The Starting Value is used to establish the starting value for
the IAQ PID calculation.
The IAQ PID includes the following set points: Proportion-
al Gain, Integral Gain, Derivative Gain, and Starting Value.
DAMPER MOVEMENT BAND — The Damper Movement
Band is used to define what the minimum desired range of
change in economizer damper position that is required before
the controller will attempt to open/close the economizer.
Damper Movement
Reference:
Proportional Gain:Range:
Default Value:
Range:
Default Value:
Derivative Gain: Range:
Default Value:
–100.0 to 40.0
1.0
–5.0 to 5.0
0.5
–20.0 to 20.0
0.0
Units:
Percent
0 to 5
0
Range:
Integral Gain:
Default Value:
OAT TEMP BAND — The OAT Temp Band is used to slow
the response of the economizer damper based on the value of
OAT. In other words, the colder OAT gets the slower the rate of
change in the economizer.
Starting Value:
Units:
Percent
0.0 to 100.0
0.0
Range:
OAT Temp
Reference:
Default Value:
Range:
0 to 40 Delta
Degrees F
ECONOMIZER PID — The proportional gain determines the
response of the PID temperature control loop; a larger gain
increases the amount of damper movement while a smaller
gain requires a larger error to achieve the same results.
The integral gain affects the response of a PID calculation;
an increase in gain will compensate more quickly for propor-
tional control droop. Too large of an integral gain will cause
excessive damper positioning and instability. Enter the desired
integral gain for the damper control algorithm.
The economizer derivative gain has been tested for ideal
operation in sensor mode and should be left at the default value.
NOTE: In thermostat mode, the modulation may appear to
regularly change. However, it will precisely control leaving-air
temperature.
The economizer Starting Value is used to establish the start-
ing value for the damper PID calculation. The value entered is
determined by the mass of the zone. Typically a value of 10%,
the default, will be adequate for most applications. For higher
mass areas, such as a stone lobby, the value may be increased
to 20 to 25%.
The Economizer PID includes the following set points:
Proportional Gain, Integral Gain, Derivative Gain, and Starting
Value.
(Delta Degrees C)
25.0
Default Value:
MINIMUM DAMPER POSITION — The minimum damper
position (MDP) specifies user configured occupied minimum
economizer damper position. The control selects the greatest
value between MDP and IAQ calculated Minimum Position.
The resulting value is the Final Minimum Damper Position
IQMP for Occupied mode.
Economizer Damper is limited to IQMP in Occupied mode,
or whenever Supply Fan is ON in units with Thermostat
control.
Minimum Damper
Position:
Units:
Percent
0 to 100
20.0
Range:
Default Value:
LOW TEMP MINIMUM DAMPER POSITION OVER-
RIDE — The Low Temperature Minimum Damper Position
(MDP) specifies the value for purge minimum damper position
for low outdoor air temperature conditions.
The IAQ Pre-Occupancy Purge Algorithm shall use this
value for the minimum damper position whenever Outdoor Air
Temperature is below Unoccupied OAT Lockout Temperature.
Proportional Gain: Range:
Default Value:
Range:
–100.0 to 100.0
–4.0
–5.0 to 5.0
–2.0
–20.0 to 20.0
–3.0
Degrees F
(Degrees C)
48.0 to 120.0
70.0
The Low Temperature MDP must be lower than the config-
ured Minimum Damper Position.
Integral Gain:
Derivative Gain:
Starting Value:
Default Value:
Range:
Default Value:
Units:
Low Temperature
MDP Override:
Units:
Percent
0 to 100
100
Range:
Default Value:
DX COOLING LOCKOUT — The DX (Direct Expansion)
Cooling Lockout function Enables/Disables Low Ambient DX
Cooling Lockout option.
Range:
Default Value:
For Version 1.2 — When DX Cooling Lockout is enabled,
Cooling control will compare OAT against the DX Cooling
Lockout Temperature. Whenever OAT <= the DX Cooling
Lockout Temperature and current DX stages are 0, the control
will set Cooling Submaster Reference (CCSR) to 150 F. That
will prevent the unit from staging up.
If the OAT sensor is not installed (OAT point reads –40 F
and “Sensor Failure”), the cooling stages ARE locked out if
DXCTLO is On.
SUBMASTER GAIN LIMIT — The Submaster Gain Limit
is used to define the submaster gain limit that is multiplied by
the Submaster Error and added to the Submaster Center Value
to produce the output value that will be sent to the device. The
sign of the submaster gain limit determines the direction in
which the output will be driven in response to a given error.
The gain is expressed in percent change in output per
degree of error.
Submaster Gain
Limit Reference:
Range:
–20.0 to 20.0
–5.5
Default Value:
35
The DXCTLO should be turned OFF (to ignore the
DXLOCK setpoint) in applications where there is either no
OAT sensor (local or broadcast) or the OAT sensor has failed.
TIME GUARD OVERRIDE — The Time Guard Override
function will reset the Time Guard. Whenever this option is
changed from OFF to ON, the control will evaluate the amount
of time left in Compressor Time Guards.
If the time in a Time Guard is more than 30 seconds, it will
be replaced with 30 seconds.
NOTE: Changing this decision from OFF to ON will only
result in one-time Time Guards override.
To perform the override again, the override must be
changed from OFF to ON again.
For Version 1.3 — If there is a valid OAT sensor reading and
DXCTLO is set to “OFF”, compressor cooling will NOT be
allowed. Please note that this functionality was NOT by design,
and was an unintended consequence of the update to 1.3. This
will be changed in a future version of PremierLink™ control.
Users that do NOT require the cooling lockout function have
instinctively set DXCTLO to Off; unfortunately, this will dis-
able cooling if a valid OAT reading is present. If a valid OAT
sensor reading is present, DXCTLO must be set to On, or
compressor cooling will NOT be allowed.
If the OAT sensor is not installed (OAT point reads –40 F
and “Sensor Failure”), the cooling stages are NOT locked out
regardless of the setting of DXCTLO.
If there is a valid OAT sensor reading, and DXCTLO is
“ON”, cooling will be allowed when the OAT value is above
the DXLOCK setpoint.
Time Guard
Override:
Range:
Default Value:
On/Off
Off
CONTINUOUS POWER EXHAUST — The Continuous
Power Exhaust function defines the operation of the Power
Exhaust Fan.
If disabled, the Power Exhaust Fan will operate during
economizer purge cycles when the economizer damper posi-
tion is above the configured minimum value. If enabled, the
Power Exhaust Fan will follow the supply fan's operation.
Cooling will NOT be allowed when the OAT value is
below the DXLOCK setpoint and DXCTLO is “ON”.
Continuous
Power
To ensure that cooling will occur when there is no OAT
sensor installed, be sure to short the OAT sensor leads together.
Exhaust:
Range:
Default Value:
Disable/Enable
Disable
DX Cooling
Lockout:
Range:
Default Value:
On/Off
On
SUPPLY FAN STATUS ENABLE — The Supply Fan Status
Enable function is enabled when an actual sensor input is used
to determine that the supply fan is on. This will prevent certain
algorithms to run if the controller does not see that the supply
fan is functioning properly.
DX COOLING LOCKOUT TEMPERATURE — The DX
Cooling Lockout Temperature specifies Low Ambient DX
Cooling Lockout Temperature that is compared against OAT to
determine if the unit can stage up or not.
If this decision is disabled, the Supply Fan Status will fol-
low the state of the Supply Fan Relay in order to allow the
algorithms to run that depend on the Supply Fan Status to be
ON before executing.
DX Cooling
Lockout Temp: Units:
Range:
Degrees F (Degrees C)
40.0 to 60.0
45.0
Default Value:
Supply Fan
Status Enable:
SAT CMP1 LOCKOUT TEMP — The SAT CMP1 Lockout
Temperature displays the low supply temperature set point for
compressor no. 1 supply air during cooling. If compressor no. 1
is on during Cooling mode, the economizer will assist the cool-
ing and work to maintain a discharge air temperature slightly
above lockout temperature set point. If the economizer is at
minimum and the supply air temperature goes below Lockout
Temperature set point, the compressor will cycle to maintain
the supply air set point. The minimum on and off times will
still be in effect.
Range:
Default Value:
Disable/Enable
Disable
MAXIMUM OFFSET ADJUSTMENT — Maximum Offset
Adjustment value determines the degree in which the occupied
heating and cooling set points can be adjusted by the setpoint
adjustment slide bar on the space temperature sensor.
Max Offset
Adjustment:
Units:
Delta Degrees F
(Delta Degrees C)
0.0 to 15.0
Range:
Default Value:
SAT CMP1
Lockout Temp: Units:
Range:
2.0
Degrees F (Degrees C)
50.0 to 65.0
55.0
SPACE TEMPERATURE TRIM — The Space Temperature
Trim configuration is used to calibrate the temperature display
for a sensor that does not appear to be reading correctly.
Default Value:
SAT CMP2 LOCKOUT TEMP — The SAT CMP2 Lockout
Temperature displays the low supply temperature set point for
compressor no. 2 supply air during cooling. If compressor no. 2
is on during Cooling mode, the economizer will assist the cool-
ing and work to maintain a discharge air temperature slightly
above lockout temperature set point. If the economizer is at
minimum and the supply air temperature goes below Lockout
Temperature set point, the compressor will cycle to maintain
the supply air set point. The minimum on and off times and
stage-up and down timers will still be in effect.
NOTE: If the staged cooling number of stages value is con-
figured to 1, then the SAT CMP2 is used for the low supply
air set point.
SAT CMP2
Lockout Temp: Units:
Range:
Space Temperature
Trim:
Units:
Delta Degrees F
(Delta Degrees C)
–9.9 to 9.9
Range:
Default Value:
0.0
SUPPLY AIR TEMPERATURE TRIM — The Supply Air
Temperature Trim configuration is used to calibrate the temper-
ature display for a sensor that does not appear to be reading
correctly.
Supply Air
Temperature
Trim:
Units:
Delta Degrees F
(Delta Degrees C)
–9.9 to 9.9
Degrees F (Degrees C)
45.0 to 55.0
50.0
Range:
Default Value:
0.0
Default Value:
36
PremierLink™ Configuration Screen — The
PremierLink Configuration screen allows the user to configure
all functions. See Table 15.
OPERATING MODE — The Operating Mode function
determines the operating mode of the PremierLink controller.
There are two operating modes from which to choose: TSTAT
and CCN Sensor.
The TSTAT mode allows PremierLink controller to operate
as a stand-alone thermostat control by monitoring Y1 (cooling
stage 1), Y2 (cooling stage 2), W1 (heating stage 1), W2 (heat-
ing stage 2), and G (indoor fan) inputs.
Table 15 — PremierLink Control Configuration
DESCRIPTION
VALUE UNITS NAME
Operating Mode: 0=TSTAT,
1=CCN Sensor
Heat Type: 0=Gas,
1=Electric Heat
Unit Type: 0=AC Unit,
1=Heat Pump
Auxiliary Output
1
0
0
0
TSTATCFG
HEATTYPE
AC
AUXOUT
0=None
1=Exhaust Fan
The CCN mode allows the controller to integrate into a
Carrier Comfort Network.
2=Heat Stage
3=Reversing Valve
Operating Mode: Range:
0 for TSTAT
1 for CCN
Unoccupied Free Cool
Demand Limiting
Disable
Disable
NTEN
DLEN
LSGP
OATBC
GSBC
Default Value:
*Default value for Version 1.1 and 1.2 is 0 (TSTAT).
1 (CCN Sensor*)
Loadshed Group Number
CCN Broadcast OAT, ENTH,OAQ
Global Schedule Broadcast
Broadcast Acknowledge
Schedule Number
1
0
No
No
64
HEAT TYPE — The Heat Type mode determines the type of
heat equipment the controller uses. There are two choices: gas
or electric.
BCACK
SCHEDNUM
Timed Override Hours
Linkage Thermostat
Cool Strt Bias(min/deg)
Heat Strt Bias(min/deg)
Filter Timer hrs* 100
IAQ Priority Level
IAQ Pre-Occupancy Purge
IAQ Purge Duration
IAQ Delta Setpoint
IAQ Maximum Damper Pos.
Indoor AQ Low Ref.
Indoor AQ High Ref.
Outdoor AQ Low Ref.
Outdoor AQ High Ref.
Outdoor AQ Lockout Point
Service Password
0 hours TIMOVRID
Heat Type:
Range:
0 for Gas (not used)
1 for Electric Heat
0 (Gas)
Default Value:
10 min
10 min
15
KCOOL
KHEAT
FIL_TIMR
IAQP
IAQPURGE
IQPD
IMPORTANT: When used with split system units, Heat
Type must be set to 1 (electric heat).
Low
Disable
5 min
650
50 %
0.0
2000.0
0.0
2000.0
0
1111
Disable
Off
UNIT TYPE — The Unit Type mode determines the type of
heating/cooling equipment the controller is attached to. There
are two choices: AC or Heat Pump.
The AC mode is primarily used for units using the compres-
sors for cooling only.
The Heat Pump mode is primarily used for units using a
heat pump (for example, compressors for heating and cooling).
Unit Type:
IAQD
IAQMAXP
IIAQREFL
IIAQREFH
OIAQREFL
OIAQREFH
OIAQLOCK
PASSWORD
PASS_EBL
DISPUNIT
Range:
0 for AC
1 for Heat Pump
0 (AC)
Default Value:
Password Enable
Metric Display
AUXILIARY OUTPUT — The Auxiliary Output function is
used to define the specific use of the Auxiliary Output on the
controller board.
The output will be energized or deenergized by the appro-
priate algorithm that uses that specific output.
LOADSHED GROUP NUMBER — The Loadshed Group
Number function defines the Loadshed table number (LDSH-
DxxS, where xx is the configured loadshed group number) that
the controller will respond to when a broadcast for Redline/
Loadshed has been detected on the CCN bus.
Auxiliary Output is displayed as one of the following:
0 = None
1 = Exhaust Fan
Auxiliary Output:
2 = Heat Stage
3 = Reversing Valve
Range:
Default Value:
Unoccupied
Free Cool:
Range:
1 to 16
1
0 to 3
0
Default Value:
CCN, BROADCAST OAT, ENTHALPY, OAQ — Config-
ures the controller to CCN broadcast any or all of the point
values for Outside Air Temperature (OAT), Enthalpy (ENTH),
and Outdoor Air Quality (OAQ).
Example: To broadcast OAQ and ENTH but not OAT, the cor-
responding bitmap is 110; the binary equivalent of the decimal
number 6. The configuration decision would then be set to a 6.
UNOCCUPIED FREE COOL — The Unoccupied Free Cool
function is used during unoccupied periods to pre-cool the
space using outside air when outside conditions are suitable.
Unoccupied
Free Cool:
Range:
Disable/Enable
Disable
Default Value:
DEMAND LIMITING — The Demand Limiting function is
used to limit operating capacity of the unit to prevent system
overloads. Both Heating and Cooling capacity is limited.
When Demand Limit option is enabled, the control will re-
spond to the Loadshed Controller commands, such as Redline
Alert, Shed, Unshed, and Redline Cancel.
CCN Broadcast, OAT, Enthalpy,
OAQ Allowable Entries:
0 — None
5 — OAT and OAQ
6 — ENTH and OAQ
7 — OAT, ENTH and OAQ
1 — OAT Only
2 — ENTH Only
3 — OAT and ENTH
4 — OAQ Only
Demand
Limiting:
Range:
Default Value:
Disable/Enable
Disable
Default Value:
0 (disabled, no broadcasts performed)
37
GLOBAL SCHEDULE BROADCAST — The Global Sched-
ule Broadcast setting configures the controller to broadcast or
receive a global schedule. If set to Yes, the controller will act as
a global schedule master and its schedule will be broadcast to
the CCN. If set to No, the controller will not broadcast a global
schedule and it will receive the configured schedule number.
comfort conditions. The controller will temper cold air OAT
<55 F to prevent cold blow.
Indoor Air Quality
Priority Level:
Range:
Default Value:
High/Low
Low
INDOOR AIR QUALITY PREOCCUPANCY PURGE —
The Indoor Air Quality Preoccupancy Purge brings in fresh
outdoor air before the Occupied mode begins. The IAQ Pre-
Occupancy Purge is used to lower carbon dioxide levels below
the IAQ set point before Occupied mode starts.
The Purge is started two hours before the occupied time and
lasts for the specified duration.
Global Schedule
Master:
Range:
Default Value:
No/Yes
No
BROADCAST ACKNOWLEDGER — The Broadcast Ac-
knowledger setting configures the controller to recognize
broadcast messages that appear on its CCN bus.
NOTE: For proper CCN bus operation, there should be only
one device per CCN bus that is configured as the Broadcast
Acknowledger.
Indoor Air Quality
Preoccupancy
Purge:
Range:
Disable/Enable
Disable
Default Value:
Acknowledger: Range:
Default Value:
No/Yes
No
INDOOR AIR QUALITY PURGE DURATION — The
Indoor Air Quality Purge Duration specifies the duration of
IAQ Pre-Occupancy purge. The Purge is started two hours
before the occupied time and lasts for the specified duration.
Indoor Air Quality
SCHEDULE NUMBER — The Schedule Number deter-
mines which Global Occupancy Schedule that the controller
will follow. A value of 64 disables global occupancy from
CCN and will decide Occupancy from its local schedule. A
value between 65 and 99 will allow the controller to follow the
global occupancy schedule of the number broadcast over CCN.
Purge Duration:
Display Units:
Display Range: 0 to 60
Default Value:
Minutes
5
Occupancy Schedule
INDOOR AIR QUALITY DELTA SET POINT — The
Indoor Air Quality Delta Set Point specifies the highest Indoor
Air Quality level (measured in ppm) allowed within the space
whenever unit is in Occupied mode (or Supply Fan On for
units with Thermostat control) and Indoor Air Quality sensor is
installed.
Number
Range:
64 to 99
64
Default Value:
TIMED OVERRIDE HOURS — The Timed Override Hours
function is used to configure a timed override duration by
entering the number of hours the override will be in effect.
Pressing the override button on a space temperature sensor will
cause an override.
Indoor Air Quality
Delta Set Point:
Display Units: PPM (parts per million)
Display Range: 1 to 5000
Default Value:
Timed Override
Hours:
650
Range:
Default Value:
0 to 4
0
INDOOR AIR QUALITY MAXIMUM DAMPER POSI-
TION — This point displays upper limit of the Indoor Air
Quality minimum damper position calculated by the IAQ
control.
For example, IAQ is calculating 100% Minimum Damper
Position, but this decision is set to 50%, IAQ Minimum Damp-
er Position will be clamped to 50%.
NOTE: When IAQ priority is set to HIGH, this value must
reflect the maximum outdoor air percent that the equipment
can heat or cool at worst conditions.
LINKAGE THERMOSTAT — The Linkage Thermostat start
time biases allow the installer to configure the time per degree
the space should take to recover in the Heat and Cool modes
for optimum start with a Linkage Thermostat. These numbers
will be used to calculate the Start Bias time.
Cool Start Bias: Units:
Range:
Minutes/Degree
0 to 60
10
Default Value:
Heat Start Bias Units:
Range:
Minutes/Degree
0 to 60
10
Indoor Air Quality
Maximum Damper
Position:
Default Value:
Display Units:
Display Range: 0 to 100
Default Value: 50
% Open
FILTER TIMER HOURS — The Filter Timer Hours config-
uration determines when the filter status will display a “Dirty”
alarm. When the Filter Timer Hours is configured to a value
other than zero and fan run time exceeds the value configured,
the filter status will display “Dirty” and a CCN alarm will be
generated. Setting the configured Filter Timer Hours value to
zero will disable the alarm condition. The value of the timer is
stored in EEPROM to protect it in the event of a power failure.
The value is stored every 24 hours.
INDOOR AIR QUALITY SENSOR — The Indoor Air Qual-
ity sensor defines the value in parts per million (ppm) which
correlate to the low and high voltage readings from the sensor.
Low Reference specifies Low Point of the Indoor IAQ
Sensor Range in ppm.
Low Reference: Units:
Range:
PPM (parts per million)
0 to 5000
0
Filter Timer
Hours:
Default Value:
Range:
0 to 99
High Reference specifies High Point of the Indoor IAQ
Sensor Range in ppm.
Default Value: 15 (where 15*100=1500)
INDOOR AIR QUALITY PRIORITY LEVEL — The Indoor
Air Quality Priority Level, when set to Low, ensures that com-
fort is not being compromised by bringing in too much outdoor
air to maintain IAQ set point. When an override condition
takes place, IAQ control is disabled, and Economizer Mini-
mum Position is set to the user configured value MDP. When
set to High, IAQ control is always active regardless of indoor
High Reference: Units:
Range:
PPM (parts per million)
0 to 5000
Default Value:
2000
OUTDOOR AIR QUALITY SENSOR — The Outdoor Air
Quality sensor defines the value in parts per million (ppm)
which correlate to the low and high voltage readings from the
sensor.
38
Low Reference specifies Low Point of the Outdoor IAQ
Sensor Range in ppm.
OVERRIDE DURATION — The Override Duration point
displays the number of minutes remaining for an occupancy
override which is in effect. If the override duration value down-
loaded is in hours, the value will be converted to minutes. If the
occupancy schedule is occupied when override is initiated, the
current occupancy period will be extended by the number of
hours/minutes requested.
If the current occupancy period is unoccupied when the oc-
cupancy override is initiated, the mode will change to occupied
for the duration of the number of hours/minutes downloaded. If
the occupancy override is due to end after the start of the next
occupancy period, the mode will transition from occupancy
override to occupied without becoming unoccupied, and the
occupancy override timer will be reset.
Low Reference: Units:
Range:
PPM (parts per million)
0 to 5000
0
Default Value:
High Reference specifies High Point of the Outdoor IAQ
Sensor Range in ppm.
High Reference: Units:
Range:
PPM (parts per million)
0 to 5000
2000
Default Value:
OUTDOOR AIR QUALITY LOCKOUT POINT — When
set to non-zero value, the IAQ algorithm will compare Outdoor
IAQ reading against this decision and disable IAQ control
whenever the value of OAQ exceeds this configured value.
Override
Duration:
Display Units:
Display Range: 0 to 240
Default Value:
Network Access: None
Minutes
Outdoor Air
Quality Lockout
Point:
0
Range:
Default Value:
0 to 5000
0
OCCUPIED START TIME — The Occupied Start Time
point shows the time that the current occupied mode began. If
the current mode is unoccupied or the controller is following a
global schedule, the value displayed by this point will remain at
default.
SERVICE PASSWORD — The Service Password function
defines the password needed to access the controller via the
Navigator interface.
Service Password: Range:
Default Value:
0000 to 9999
1111
Occupied
Start Time:
Display Range: 00:00 to 24:00
Default Value: 00:00
Network Access: None
PASSWORD ENABLE — The Password Enable function is
used to require a password to be entered when attempting
to access the controller via the Navigator™ display module
interface.
UNOCCUPIED START TIME — The Unoccupied Start
Time point shows the time that the current occupied mode will
end. This will also be the beginning of the next unoccupied
mode. If the current mode is unoccupied or the controller is
following a global schedule, the value displayed by this point
will remain at default.
Password
Enable:
Range:
Default Value:
Enable/Disable
Disable
METRIC DISPLAY — The Metric Display function is used
to toggle the display for the Navigator between US and Metric
units.
Unoccupied
Start Time:
Display Range: 00:00 to 24:00
Default Value: 00:00
Network Access: None
Metric Display: Range:
Default Value:
On/Off
Off
Occupancy Maintenance Screen — The Occupan-
cy Maintenance screen is used to check the occupied schedule.
Information concerning the current occupied period is dis-
played. See Table 16.
MODE — The Mode point displays the current occupied
mode for the controller. If the controller is following its own
local schedule this is the result of the local schedule status. If
the controller is configured to follow a global schedule, this
point displays the mode last received from a global schedule
broadcast.
NEXT OCCUPIED DAY — The Next Occupied Day point
displays the day of week when the next occupied period will
begin. This point is used with the Next Occupied Time so the
user will know when the next occupied period will occur. If the
controller is following a global schedule this point will remain
at default.
Next Occupied
Day:
Display Range: MON, TUE, WED,
THU, FRI, SAT, SUN
Default Value:
No display (Blank)
Mode:
Display Range: 0 to 1
Default Value:
Network Access: None
Network Access: None
0
NEXT OCCUPIED TIME — The Next Occupied Time point
displays the time day when the next occupied period will
begin. This point is used with the Next Occupied Day so the
user will know when the next occupied period will occur. If the
PremierLink™ controller is following a global schedule this
point will remain at default.
CURRENT OCCUPIED PERIOD — If the controller is con-
figured to determine occupancy locally, the Current Occupied
Period point is used to display the current period determining
occupancy.
Current Occupied
Period:
Next Occupied
Time:
Display Range: 1 to 8
Default Value:
Network Access: None
Display Range: 00:00 to 24:00
Default Value: 00:00
Network Access: None
0
OVERRIDE IN PROGRESS — The Override in Progress
point is used to display if an occupancy override is in progress.
The point will display “Yes” if an override is in progress, or
“No” if there is no override.
Override In
Progress:
Display Range: Yes/No
Default Value: No
Network Access: None
39
NEXT UNOCCUPIED DAY — The Next Unoccupied Day
point displays the day of week when the next unoccupied peri-
od will begin. This point is used with the Next Unoccupied
Time so the user will know when the next unoccupied period
will occur. If the controller is following a global schedule this
point will remain at default.
Thermostat
Control:
Display Range:
Default Value:
Network Access:
No/Yes
Yes
Read Only
OCCUPIED — The Occupied point indicates whether or not
the controller is operating in the Occupied mode.
Occupied:
Next Unoccupied
Day:
Display Range:
Default Value:
Network Access:
No/Yes
No
Read/Write
Display Range: MON, TUE, WED,
THU, FRI, SAT, SUN
Default Value:
No display (Blank)
Network Access: None
TIMED OVERRIDE IN EFFECT — The Timed Override In
Effect point shows if a timed override is currently in effect.
Timed Override
in Effect:
NEXT UNOCCUPIED TIME — The Next Unoccupied Time
point displays the time day when the next unoccupied period
will begin. This point is used with the Next Unoccupied Day
so the user will know when the next unoccupied period will
occur. If the controller is following a global schedule this point
will remain at default.
Display Range:
Default Value:
Network Access:
No/Yes
No
Read Only
START BIAS TIME — The Start Bias Time, in minutes, is
calculated during the unoccupied period by the controller as
needed to bring the temperature up or down to the set point un-
der the optimum start routine. The start time bias for heat and
cool are configurable. This value will be reported to the Link-
age Thermostat if it is used. It cannot be used with Global
Scheduling.
Next Unoccupied
Time:
Display Range: 00:00 to 24:00
Default Value: 00:00
Network Access: None
LAST UNOCCUPIED DAY — The Last Unoccupied Day
point displays the day of week when the controller last changed
from occupied to the Unoccupied mode. This point is used in
conjunction with the Last Unoccupied Time to know the last
time and day when the controller became unoccupied. If the
controller is following a global schedule this point will remain
at default.
Start Bias Time: Display Units:
Display Range:
minutes
0 to 180
0
Default Value:
Network Access:
Read only
HEAT — The Heat point shows if there is a demand for heat in
the space. The space temperature must be below the Occupied
Low or Unoccupied Low set point.
NOTE: When a control mode ends, “NO” mode must be com-
pleted before opposite mode can begin.
Last Unoccupied
Day:
Display Range: MON, TUE, WED,
THU, FRI, SAT, SUN
Default Value:
No display (Blank)
Network Access: None
Heat:
Display Range:
Default Value:
Network Access:
No/Yes
No
LAST UNOCCUPIED TIME — The Last Unoccupied Time
point displays the time of day when the controller last changed
from occupied to the Unoccupied mode. This point is read in
conjunction with the Last Unoccupied Day to know the last
time and day when the controller became unoccupied. If the
controller is following a global schedule this point will remain
at default.
None
COOL — The Cool point shows if there is a demand for cool-
ing in the space. The space temperature must be above the Oc-
cupied High or Unoccupied High set point.
NOTE: When a control mode ends, “NO” mode must be com-
pleted before opposite mode can begin.
Last Unoccupied
Time
Display Range: 00:00 to 24:00
Cool:
Display Range:
Default Value:
Network Access:
No/Yes
No
None
Default Value:
00:00
Network Access: None
IAQ CONTROL — Indicates weather or not IAQ control is
active in the controller. IAQ control of the minimum damper
position is active whenever the configured parameters for the
IAQ PID calculate a minimum position greater than the config-
ured economizer minimum position.
Table 16 — Occupancy Maintenance
DESCRIPTION
VALUE
UNITS
NAME
Mode
0
0
No
MODE
PERIOD
Current Occupied Period
Override in Progress
Override Duration
IAQ Control:
Display Range: No/Yes
Default Value: No
Network Access: Read Only
OVERLAST
OVERDURA
OCCSTART
UNSTART
NXTOCCD
NXTOCCT
NXTUNOD
NXTUNOT
PRVUNOD
PRVUNOT
0
min
Occupied Start Time
Unoccupied Start Time
Next Occupied Day
Next Occupied Time
Next Unoccupied Day
Next Unoccupied Time
Last Unoccupied Day
Last Unoccupied Time
00:00
00:00
DEMAND LIMIT — Indicates that a command has been
received to limit capacity or reduce capacity of the heating or
cooling.
00:00
00:00
00:00
Demand Limit: Display Range: No/Yes
Default value:
No
Network Access: Read Only
TEMP COMPENSATED START — Indicates that the con-
troller has started the equipment prior to occupancy in order to
be at the occupied set points at the start of occupancy.
Maintenance Screen — The Maintenance Screen is
used to service the PremierLink™ controller. See Table 17.
Temp
THERMOSTAT CONTROL — Indicates the result of the
configuration decision to control in the thermostat or sensor
mode.
Compensated
Start:
Display Range:
Default Value:
Network Access:
No/Yes
No
Read Only
40
IAQ PRE-OCCUPANCY PURGE — Indicates that the pre-
occupancy purge mode is currently active.
IAQ
ECONOMIZER SUBMASTER GAIN — Displays the cur-
rent Submaster gain multiplier in use to calculate the econo-
mizer damper position. At temperatures below 45 F this
number will decrease to slow the rate of movement of the
economizer damper.
Economizer
Submaster Gain: Display Range: –20 to 20
Pre-occupancy
Purge:
Display Range:
Default Value:
Network Access:
No/Yes
No
Read Only
Default Value:
–5.5
UNOCCUPIED FREE COOLING — Indicates that unoccu-
pied free cooling is in effect.
Network Access: Read Only
COMPRESSOR STARTS — Displays the total number of
compressor starts.
Unoccupied Free
Cooling:
Display Range:
Default Value:
Network Access:
No/Yes
No
Read Only
Compressor
Starts:
Default Value:
0
Network Access: Read Only
FIRE SHUTDOWN — Indicates in a sensor mode that the
Fire shutdown input has been sensed. This will cause the
supply fan and heating and cooling to be turned off also.
COMPRESSOR 1 RUN TIME — Displays the number of
run hours of compressor no. 1.
Fire Shutdown: Display Range:
Default Value:
No/Yes
No
NOTE: The clock must be set for run times to accumulate.
Compressor 1
Network Access:
Read/Write
Run Time:
Display Units:
Default Value:
Hours
0
LINKAGE CONTROL — Indicates if the controller is
receiving linkage communication.
Network Access: Read Only
COMPRESSOR 2 RUN TIME — Displays the number of
run hours of compressor 2.
NOTE: The clock must be set for run times to accumulate.
Compressor 2
Linkage Control: Display Range:
Default Value:
No/Yes
No
Network Access:
Read/Write
FIELD/STARTUP TEST — This point is used to enable field
test of the controller. When forced to Yes, the controller will
perform a test of all outputs and reset to “NO” at end of test.
The test may be aborted at any time by forcing value to NO.
Run Time:
Display Units:
Default Value:
Hours
0
Network Access: Read Only
SUPPLY FAN RUN TIME — Displays the number of run
hours of the supply fan.
NOTE: The clock must be set for run times to accumulate.
This is not the same timer used for the filter status. A sepa-
rate timer is used to keep track of the run hours since the last
filter change.
Field/Startup
Test:
Display Range:
Default Value:
Network Access:
No/Yes
No
Read/Write
HEAT SUBMASTER REFERENCE — When in sensor
mode, the Heat Submaster Reference point displays the supply
air temperature calculated by the heating PID loop. This value
is compared to the actual supply air temperature to determine
the number of required stages. When in the thermostat mode,
the value displayed is zero.
Supply Fan
Run Time:
Display Units:
Default Value:
Hours
0
Network Access: Read Only
Heat Submaster
Reference:
LINKAGE THERMOSTAT — The following Linkage Ther-
mostat points display the standard values received from a
Linkage Thermostat (if one is being used to provide space
temperature, set point and occupancy information).
Display Units:
Display Range: 40.0 to 150.0
Default Value: 40
Network Access: Read Only
Degrees F (Degrees C)
Linkage
COOL SUBMASTER REFERENCE — The Cool Submas-
ter Reference point displays the supply air temperature calcu-
lated by the cooling PID loop when in sensor mode. This value
is compared to the actual supply air temperature to determine
the number of required stages. When in the thermostat mode,
the value displayed is zero.
Status:
Display Range: 0 to 3
Default Value:
Network Access: None
2
The Supervisory Element displays the address of the device
sending the linkage supervisory table to the PremierLink™
controller.
Supervisory
Element:
Cool Submaster
Reference:
Display Units:
Display Range: 40.0 to 150.0
Default Value: 150
Network Access: Read Only
Degrees F (Degrees C)
Default Value:
0
Network Access: Read Only
The Supervisory Bus displays the bus number of the device
sending the linkage supervisory table to the PremierLink
controller.
ECONOMIZER SUBMASTER REFERENCE — This point
displays the supply air temperature determined by the
Economizer PID calculation.
Supervisory Bus: Default Value:
0
Network Access: Read Only
Economizer
Submaster
Reference:
The Supervisory Block displays the block or table
number of the linkage table occurrence in the supervisory
device. Some linkage supervisory devices may contain
more than one linkage table for different air sources.
Supervisory
Block:
Display Units:
Display Range:
Default Value:
Degrees F (Degrees C)
48 to 120
120
Network Access: Read Only
Default Value:
0
Network Access: Read Only
41
The Average Occupied Heat Set Point displays the
Occupied Heat set point from the Linkage Thermostat.
The Average Zone Temperature displays the space tempera-
ture from the Linkage Thermostat.
Average Occupied
Average Zone
Temperature:
Heat Set Point: Display Units:
Degrees F (Degrees C)
0.0
Display Units:
Display Range: 0.0 to 99.9
Default Value: 0.0
Network Access: None
Degrees F (Degrees C)
Display Range: 0.0 to 99.9
Default Value:
Network Access: None
The Average Occupied Cool Set Point displays the Occu-
pied Cool set point from the Linkage Thermostat.
The Average Occupied Zone Temperature displays the
space temperature from the Linkage Thermostat during occu-
pied periods.
Average Occupied
Cool Set Point: Display Units:
Degrees F (Degrees C)
0.0
Average Occupied
Display Range: 0.0 to 99.9
Zone Temperature: Display Units:
Degrees F (Degrees C)
0.0
Default Value:
Network Access: None
Display Range: 0.0 to 99.9
Default Value:
Network Access: None
The Average Unoccupied Heat Set Point displays the Unoc-
cupied heat set point from the Linkage Thermostat.
The Occupancy Status point displays a 1 if occupancy is re-
ported by the Linkage Thermostat. The Occupancy Status
point displays a 0 if occupancy is not reported by the Linkage
Thermostat.
Average Unoccupied
Heat Set Point: Display Units:
Degrees F (Degrees C)
0.0
Display Range: 0.0 to 99.9
Default Value:
Occupancy
Status:
Network Access: None
Display Range: 0, 1
Default Value:
Network Access: None
0
The Average Unoccupied Cool Set Point displays the Unoc-
cupied cool set point from the Linkage Thermostat.
Average Unoccupied
Cool Set Point: Display Units:
Degrees F (Degrees C)
0.0
Display Range: 0.0 to 99.9
Default Value:
Network Access: None
Table 17 — Maintenance
DESCRIPTION
Thermostat Control
Occupied
Timed Override in Effect
Start Bias Time
VALUE
No
UNITS
STATUS
FORCE
NAME
TSTAT
OCCUP
TIMOV
STRTBIAS
HEAT
Yes
No
0
min
Heat
No
Cool
No
COOL
IAQ Control
No
IAQCL
Demand Limit
No
No
No
No
DEMLT
TCSTR
IQPRG
NTFCL
FIRES
Temp Compensated Start
IAQ Pre-Occupancy Purge
Unoccupied Free Cool
Fire Shutdown
No
Linkage Control
Field/Startup Test
No
No
DAVCL
FIELD
Heat Submaster Ref
Cool Submaster Ref
Economizer Submaster Ref
Economizer Submastr Gain
Compressor Starts
Compressor 1 Runtime
Compressor 2 Runtime
Supply Fan Runtime
Linkage Thermostat
Linkage Status
40.0
150.0
120.0
0.00
0.00
0.00
0.00
17.00
dF
dF
dF
SHSR
CCSR
ECONSR
ECONGN
CMPST
CM1RT
CM2RT
FANRT
HOURS
HOURS
HOURS
2
0
0
LINKSTAT
SUPE-ADR
SUPE-BUS
BLOCKNUM
OCLOSTPT
OCHISTPT
UNLOSTPT
UNHISTPT
AZT
Supervisory Element
Supervisory Bus
Supervisory Block
Average Occ Heat Setpt
Average Occ Cool Setpt
Average Unoc Heat Setpt
Average Unoc Cool Setpt
Average Zone Temp
Average Occ Zone Temp
Occupancy Status(1=occ)
0
0.0
0.0
0.0
0.0
0.0
0.0
1
dF
dF
dF
dF
dF
dF
AOZT
OCCSTAT
NOTE: Bold values indicate points that can be forced through communications.
42
Copyright 2002 Carrier Corporation
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
PC 111 Catalog No. 533-80072 Printed in U.S.A. Form 38-54SI Pg 44 11-02 Replaces: 38-52SI
Book 1
4
Tab 3a 2a
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