Carrier 33ZCVAVTRM, 33ZCFANTRM, 33ZCSECTRM Secondary Damper Service Configuration Screen, Srndsz

Page 43

Table 12 — Secondary Damper Service Configuration Screen

DESCRIPTION

DEFAULT

POINT NAME

Zone Pressure Control

Dsable

ZPCNTL

Dual Duct Type

0

DDTYPE

Secondary Duct Size

 

 

Inlet Diameter

6.0 in.

SRNDSZ

Inlet Area

0.0 sq. in.

SSQA

Probe Multiplier

2.443

SPMF

Calibration Gain

1.000

CAL_GAIN

Offset

0 cfm

SOFFSET

CW Rotation

Close

DMPDIR

Secondary Duct Size — The Secondary Duct Size setting is used to input the inlet diameter of the terminal, if used with a round inlet. The Inlet Area configuration is used for oval or rectangular inlets. The zone controller will use the larger value for CFM calculations if both values are configured.

Secondary Duct Size

 

(Inlet Diameter): Units

Inches

Range

3.0 to 24.0

Default Value

6.0

Inlet Area — The Inlet Area configuration is used if the termi- nal has an oval or rectangular inlet. The Primary Inlet Size configuration is used for round inlets. The zone controller will use the larger value for CFM calculations if both values are

configured.

 

 

Inlet Area:

Units

Square Inches

 

Range

0.0 to 500.0

 

Default Value

0.0

Probe Multiplier — This configuration is used to input a fac- tor for the velocity pressure probe characteristics installed in the inlet. All averaging probes will have some aerodynamic characteristics which will amplify the pressure difference read at the inlet of the terminal. The default of 2.443 is the correct value to use if the probe is a Carrier probe in a 35 or 45 Series terminal.

The formula for calculating velocity using an Ideal probe is: Velocity = 4005* SQRT (Velocity Pressure)

Most manufactures will provide a probe constant for the probe supplied. For example, Velocity = 2213*SQRT(Velocity Pressure). To calculate the number to input in this decision (Probe Multiplier) use the formula. (4005/2213)2 = 3.3. So you would use 3.3 in place of 2.443 for a probe with a probe con- stant of 2213.

An easy way to determine the probe constant for a probe without documentation is to measure the velocity pressure with a Magnahelic gage. Open the damper and adjust the static pres- sure until you have one inch of velocity pressure on the Magna- helic gage. Measure the total CFM of air being produced. The CFM just measured divided by the inlet area in feet should equal the probe constant for the formula. Velocity = (CFM just measured/inlet area) * SQRT (1.0). Now use the constant that was empirically derived to determine the probe multiplier (4005/(CFM at 1.0 Inch/Inlet area))2 = Probe Multiplier.

Probe Multiplier: Range

0.250 to 9.999

Default Value

2.443

Calibration Gain — Air terminal testing by industry standards is done with straight duct, upstream of the terminal. Since most applications do not get installed in this manner, the actual air- flow from the terminal at balancing may not equal the reading from the zone controller.

The calibration gain is used for the fine tuning adjustments which might need to be made to the airflow calculation.

If the Calibration Gain must be configured manually. It is determined as a percentage up or down that the CFM indicated

will be offset. A number of .95 will cause the maximum air- flow calculated to be reduced to 95% of the value. A Calibra- tion Gain of 1.00 will cause no change. A number of 1.05 would cause readings to become 5% higher.

Any error in reading at minimum airflow is adjusted by cal- culating the Offset configuration value.

Calibration Gain: Range

0.000 to 9.999

Default Value

1.000

Offset — The Offset configuration is included for precision applications where the minimum airflow is critical and not zero. The cfm will be offset by the value entered in the Mini- mum Cfm variable and will zero at the value entered in the Maximum Cfm variable. There will be a linear relationship be- tween the two set points.

Offset:

Units

cfm

 

Range

–250 to 250

 

Default Value

0

Clockwise Rotation — This configuration is used to define what effect a clockwise rotation of the actuator will have on the damper. If the actuator rotates clockwise to closed position, the configuration should be set to Close. If the actuator rotates clockwise to open, the configuration should be set to open. This configuration is used to change the rotation of the actuator so that the damper transducer calibration will work properly. The actuator does not have to be reinstalled nor any switches changed to reverse the action.

Clockwise

 

 

Rotation:

Range

Close/Open

 

Default Value

Close

Maintenance Table Menu Screen — The Mainte- nance Table Menu screen allows the user to select one of 4 available maintenance tables: the Linkage Maintenance Table, the Occupancy Maintenance Table, the Zone Air Balance Table, and the Zone Maintenance Table.

LINKAGE MAINTENANCE TABLE — The Linkage Maintenance table is used to view the zone linkage variables. See Table 13.

Air Source Bus Number — This variable will display the bus number of the air source that the zone controller will be com- municating Linkage to, if this zone is the Linkage Master.

Air Source

 

 

Bus Number:

Range

0 to 239

 

Default Value

0

 

Network Access

None

Air Source Element Number — This variable will display the Element Address of the Air Source that the zone controller will be communicating Linkage to, if this zone is the Linkage Master.

Air Source

 

Element Number: Display Range

1 to 239

Default Value

0

Network Access

None

43

501

Image 43
Contents Installation, Start-Up Configuration Instructions General Typical Carrier Linkage System HF23BJ042 → Zone Controller Physical Details 33ZCFANTRM Shown→ Single Duct Air Terminal Zone Controller → VAV Fan Terminal Zone ControllerZone Controller Damper Configuration Low Low Yel Blu Ora Red Wht Com SPT HF23BJ042 PAT Yel → J Zone Controller Wiring Dual Duct Applications Zone Controller Wiring Dual Duct Applications → Install Sensors Airflow Pickup Installation Space Temperature Sensor Wiring Communication Bus Wiring to Zone Controller Primary Air Temperature Sensor Part Number 33ZCSENPAT Indoor Air Quality CO2 Sensor → Supply Air Temperature Probe Part No Zcsensat LocationsVentilation Rated Based on CO2 Set Point → Indoor Air Quality Sensor WiringColor Code Recommendations Recommended CablesHumidity Sensor Wiring → Remote Occupancy Wiring Communication Bus Wiring → Typical Water Valve and Sensor InstallationInitial Operation and Test Perform the following → Points Display Screen Configuration→ Alarm Limit Configuration Screen Default Value Display range Network Access Read/WritePPM → Linkage Coordinator Configuration Screen = low, 3 = high Occupancy Schedule Information Screen → Set Point Screen Airflow Service Configuration ScreenRange Default Value Rndsz Terminal Service Configuration ScreenClockwise Rotation Range Options Service Configuration Screen Default Value NormalPpm parts per million Srndsz Secondary Damper Service Configuration ScreenCOOLING, Heating → Linkage Maintenance Screen Occupancy Maintenance Screen Commissioning Mode Display Range → Zone Air Balance/Commissioning Table → Zone Maintenance Table Read/Write Page Copyright 1999 Carrier Corporation

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