Bryant 551B installation instructions

Page 19

Exhaust Set Point Adjustment

The exhaust set point will determine when the exhaust fan runs based on damper position (if accessory power exhaust is installed). The set point is modified with the Exhaust Fan Set Point (EXH SET) potentiometer. See Fig. 30. The set point represents the damper position above which the exhaust fans will be turned on. When there is a call for exhaust, the EconoMi$er IV controller provides a 45 ± 15 second delay before exhaust fan activation to allow the dampers to open. This delay allows the damper to reach the appropriate position to avoid unnecessary fan overload.

Minimum Position Control

There is a minimum damper position potentiometer on the EconoMi$er IV controller. See Fig. 30. The minimum damper position maintains the minimum airflow into the building during the occupied period.

When using demand ventilation, the minimum damper posi- tion represents the minimum ventilation position for VOC (volatile organic compound) ventilation requirements. The maximum demand ventilation position is used for fully occu- pied ventilation.

When demand ventilation control is not being used, the min- imum position potentiometer should be used to set the occu- pied ventilation position. The maximum demand ventilation position should be turned fully clockwise.

Adjust the minimum position potentiometer to allow the minimum amount of outdoor air, as required by local codes, to enter the building. Make minimum position adjustments with at least 10 F temperature difference between the out- door and return-air temperatures.

To determine the minimum position setting, perform the following procedure:

1.Calculate the appropriate mixed-air temperature using the following formula:

(TO x

OA ) + (TR x

RA ) = TM

 

100

100

TO = Outdoor-Air Temperature OA = Percent of Outdoor Air TR = Return-Air Temperature RA = Percent of Return Air TM = Mixed-Air Temperature

As an example, if local codes require 10% outdoor air during occupied conditions, outdoor-air temperature is 60 F, and return-air temperature is 75 F.

(60 x .10) + (75 x .90) = 73.5 F

2.Disconnect the supply air sensor from terminals T and T1.

3.Ensure that the factory-installed jumper is in place across terminals P and P1. If remote damper posi- tioning is being used, make sure that the terminals are wired according to Fig. 25 and that the minimum position potentiometer is turned fully clockwise.

4.Connect 24 vac across terminals TR and TR1.

5.Carefully adjust the minimum position potentiometer until the measured mixed-air temperature matches the calculated value.

6.Reconnect the supply-air sensor to terminals T and T1.

Remote control of the EconoMi$er IV damper is desirable when requiring additional temporary ventilation. If a field-supplied remote potentiometer (Honeywell part num- ber S963B1128) is wired to the EconoMi$er IV controller, the minimum position of the damper can be controlled from a remote location.

To control the minimum damper position remotely, remove the factory-installed jumper on the P and P1 terminals on the EconoMi$er IV controller. Wire the field-supplied poten- tiometer to the P and P1 terminals on the EconoMi$er IV controller. See Fig. 34.

Damper Movement

Damper movement from full open to full closed (or vice versa) takes 21/2 minutes.

Thermostats

The EconoMi$er IV control works with conventional thermo- stats that have a Y1 (cool stage 1), Y2 (cool stage 2), W1 (heat stage 1), W2 (heat stage 2), and G (fan). The EconoMi$er IV control does not support space temperature sensors. Connections are made at the thermostat terminal connection board located in the main control box.

Occupancy Control

The factory default configuration for the EconoMi$er IV con- trol is occupied mode. Occupied status is provided by the black jumper from terminal TR to terminal N. When unoccu- pied mode is desired, install a field-supplied timeclock func- tion in place of the jumper between TR and N. See Fig. 25. When the timeclock contacts are closed, the EconoMi$er IV control will be in occupied mode. When the timeclock con- tacts are open (removing the 24-v signal from terminal N), the EconoMi$er IV will be in unoccupied mode.

Demand Controlled Ventilation (DCV)

When using the EconoMi$er IV for demand controlled venti- lation, there are some equipment selection criteria which should be considered. When selecting the heat capacity and cool capacity of the equipment, the maximum ventilation rate must be evaluated for design conditions. The maximum damper position must be calculated to provide the desired fresh air.

Typically the maximum ventilation rate will be about 5 to 10% more than the typical cfm required per person, using normal outside air design criteria.

A proportional anticipatory strategy should be taken with the following conditions: a zone with a large area, varied occupancy, and equipment that cannot exceed the required ventilation rate at design conditions. Exceeding the required ventilation rate means the equipment can condition air at a maximum ventilation rate that is greater than the required ventilation rate for maximum occupancy. A proportional- anticipatory strategy will cause the fresh air supplied to increase as the room CO2 level increases even though the CO2 set point has not been reached. By the time the CO2 level reaches the set point, the damper will be at maximum ventilation and should maintain the set point.

In order to have the CO2 sensor control the economizer damper in this manner, first determine the damper voltage output for minimum or base ventilation. Base ventilation is the ventilation required to remove contaminants during unoccupied periods. The following equation may be used to determine the percent of outside-air entering the building for a given damper position. For best results there should be at least a 10 degree difference in outside and return-air temperatures.

(TO x

OA ) + (TR x

RA ) = TM

 

100

100

TO = Outdoor-Air Temperature

OA = Percent of Outdoor Air

TR = Return-Air Temperature

RA = Percent of Return Air

TM = Mixed-Air Temperature

19

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Contents Provide Unit Support ContentsSafety Considerations InstallationIV. RIG and Place Unit III. Install Condensate Drain Line and External TrapPositioning Roof Curb Details Operating WeightBase Unit Dimensions Unit 551B Physical DataNEC Field Power SupplyMake Electrical Connections IFCFLA MCA Mocp LRA Hacr Electrical DataVoltage Comp no Electric Heater †Used to determine minimum disconnect per NEC Electric Heater UsagePerfect Humidity Dehumidification System Field Control WiringHeat Anticipator Settings VI. Adjust FACTORY-INSTALLED Options A. Disconnect SwitchAccessory Field-Installed Humidistat Manual Outdoor-Air Damper Convenience OutletOptional EconoMi$er Hood Box Removal EconoMi$er IV Standard SensorsOutdoor-Air Hood Construction EconoMi$er IV Sensor Usage EconoMi$er IV Control ModesEconoMi$er IV Controller Potentiometer LED Locations Enthalpy Changeover Set Points Page Ppm CO2 Sensor Standard SettingsUration VII. Adjust EVAPORATOR-FAN SpeedUnit Heater Required Config Minimum Required Airflow ExceptionsFan Rpm at Motor Pulley Setting* High-Static Motor/Drive Fan Rpm at Motor Pulley Setting* Standard Motor/DriveEvaporator-Fan Motor Data Standard Motor General FAN Performance Notes Accessory/FIOP EconoMi$er IV Static Pressure* in. wgAccessory/FIOP Electric Heaters Static Pressure in. wg Evaporator-Fan Motor Data High-Static MotorsAirflow 974 716 1204 774 1449 832 690 1051 750 1285866 697 1088 756 1324 901 703 1125 762 1365502 424 489 386506 629 625 688 745 8661844 15671656 1748760 1170 809 1323 748 684 891 738 1034 789 1177805 695 953 749 1100 799 1249 865 7071873 865 707 1018 760 1170 809 1323929 718 1086 771 1244 820 1401 1665697 1281 753 654 1040 713668 1116 726 683 1197 739471 421 465 402596 629 802 694 1021 12521009 705 1266 766 1533 823 674 1059 737 1306882 684 1125 746 1378 944 695 1194 756 1453474 381 462 348467 614 594 681 728 8682930 27162821 2293 996 2501 1038 27131775 820 1978 710 14821677 808 1876 855 2081 723 15771877 1492 784 16831582 796 1777 1677 808 1876791 1525 614 929 673781 1445 628 997 685START-UP Unit Preparation Internal WiringVI. Refrigerant Service Ports PRE-START-UPXII. Ventilation Continuous FAN Heating if Accessory Heater is InstalledXI. Safety Relief IX. CoolingPerfect Humidity System Normal Design Cooling Operation Condenser Coils Units With Power ExhaustService Cleaning Evaporator CoilII. Lubrication III. CONDENSER-FAN Adjustment FIGIV. BELT/PULLEY Adjustment ECONOMI$ER IV AdjustmentCooling Charging Charts, Standard 551B090 Unit Cooling Charging Charts, Standard 551B120 Unit VII. Replacement Parts Cooling Troubleshooting Troubleshooting Unit TroubleshootingProblem Cause Remedy Low System Capacity Subcooling Mode Liquid ReheatReheat Mode Will Not Energize Will Not EnergizeII. ECONOMI$ER IV Troubleshooting Demand Control Enthalpy EconoMi$er IV Troubleshooting CompletionEconoMi$er IV Input/Output Logic Inputs OutputsIndex Operating sequence Cooling EconoMi$er HeatingPage III. START-UP Electrical START-UP ChecklistTemperatures Preliminary Information
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551B specifications

The Bryant 551B and 551C are two highly efficient air conditioning units designed to provide optimal comfort in residential settings. Known for their reliability and performance, these models are part of Bryant's esteemed line of heating and cooling solutions.

One of the standout features of the Bryant 551B is its two-stage cooling system, which allows for better humidity control and increased comfort. This ensures that homeowners can enjoy consistent temperatures while reducing energy consumption. The unit operates quietly, thanks to its noise-reducing technology, making it an ideal choice for bedrooms and living spaces.

On the other hand, the Bryant 551C builds upon this foundation with its variable-speed compressor. This technology allows the unit to adjust its cooling output according to the specific needs of the home. This results in seamless operation and even greater energy efficiency. Both models also incorporate Bryant's advanced control capabilities, which allow users to monitor and adjust settings remotely via smart devices, adding a layer of convenience and modernity to home climate control.

With an emphasis on durability, both the 551B and 551C feature a galvanized steel cabinet that protects against weather-related damage. The powder coat finish further enhances their resistance to rust and corrosion, ensuring a long lifespan and minimal maintenance.

Another significant characteristic of these units is their excellent Seasonal Energy Efficiency Ratio (SEER) ratings. The 551B boasts a SEER rating of up to 16, while the 551C takes it even further with ratings exceeding 20. This efficiency not only translates to lower energy bills for homeowners but also contributes to a reduced carbon footprint, making these units environmentally friendly options.

Both models are also designed to operate with eco-friendly refrigerants, aligning with modern energy standards and regulations aimed at reducing greenhouse gas emissions.

In summary, the Bryant 551B and 551C are exemplary choices for homeowners looking for reliable, efficient, and high-performing air conditioning solutions. With features such as two-stage and variable-speed compressors, advanced smart technology, and robust construction, these models stand out in the competitive HVAC market. They promise a comfortable indoor environment along with significant energy savings, making them a wise investment for the future.