Bryant 558F installation instructions

Page 29

To determine the minimum position setting, perform the fol- lowing procedure:

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

(TO x

OA

RA

100 ) + (TR x

100 ) = TM

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. 23 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$er IV damper is desirable when requiring additional temporary ventilation. If a field- supplied remote potentiometer (Honeywell part number S963B1128) is wired to the EconoMi$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. 32.

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$er IV con- trol is occupied mode. Occupied status is provided by the black jumper from terminal TR to terminal N. When unoccu- pied mode is desired, install a field-supplied timeclock func- tion in place of the jumper between TR and N. See Fig. 23. When the timeclock contacts are closed, the EconoMi$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 ventila- tion required to remove contaminants during unoccupied peri- ods. 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.

 

OA

RA

(TO x

100 ) + (TR x

100 ) = TM

TO = Outdoor-Air Temperature

OA = Percent of Outdoor Air

TR = Return-Air Temperature

RA = Percent of Return Air

TM = Mixed-Air Temperature

Once base ventilation has been determined, set the mini- mum damper position potentiometer to the correct position.

The same equation can be used to determine the occupied or maximum ventilation rate to the building. For example, an output of 3.6 volts to the actuator provides a base ventilation rate of 5% and an output of 6.7 volts provides the maximum ventilation rate of 20% (or base plus 15 cfm per person). Use Fig. 33 to determine the maximum setting of the CO2 sensor. For example, a 1100 ppm set point relates to a 15 cfm per person design. Use the 1100 ppm curve on Fig. 33 to find the point when the CO2 sensor output will be 6.7 volts. Line up the point on the graph with the left side of the chart to deter- mine that the range configuration for the CO2 sensor should be 1800 ppm. The EconoMi$er IV controller will output the

6.7volts from the CO2 sensor to the actuator when the CO2 concentration in the space is at 1100 ppm. The DCV set point may be left at 2 volts since the CO2 sensor voltage will be ignored by the EconoMi$er IV controller until it rises above the 3.6 volt setting of the minimum position potentiometer.

Once the fully occupied damper position has been deter- mined, set the maximum damper demand control ventilation potentiometer to this position. Do not set to the maximum position as this can result in over-ventilation to the space and potential high-humidity levels.

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Contents II. Field Fabricate Ductwork ContentsSafety Considerations Positioning III. Install External Trap for Condensate DrainIV. RIG and Place Unit Roof Curb Details 558F ‘‘A’’‘‘C’’ Base Unit Dimensions 558F090,102,120,150 Base Unit Dimensions 558F091,103,121,151 558F Unit Size Physical Data 558F090,102,120,150 UnitsAshrae 90.1-1999 Compliant Units Physical Data 558F091,103,121,151 UnitsMake Electrical Connections Field Power SupplyField Control Wiring Voltage Compressor OFM Electric Power Disconnect Nominal Type FLA Size 150 Voltage Compressor 103 151 Type FLA 17.0 17.1 31.4 136 34.0 34.1 52.7 51.0 51.2 60.8 150 44.9 234/234 017 10.4 21.7 25.0 006 49.1 277/277 017 10.4 21.7 25.0 006 61.0 364/364 017 10.4 21.7 25.0 012 Convenience Outlet Conduit InstallationDamper Panel with Manual Outdoor-Air Damper Installed EconoMi$er IV Component Locations Barometric Flow Capacity EconoMi$er IV Sensor Usage EconoMi$er IV Control ModesOutside Air Temperature Changeover Set Points Enthalpy Changeover Set Points Page CO2 Sensor Standard Settings Typical Belt-Drive Motor Mounting for Sizes 090,091,102,103 VII. Adjust EVAPORATOR-FAN SpeedEvaporator-Fan Motor Efficiency Fan Rpm at Motor Pulley SettingsAccessory/FIOP Static Pressure* in. wg General FAN Performance Notes Evaporator Fan Motor DataRpm Bhp Watts External Static Pressure in. wg511 492 519 518519 518 597 709 666 916 511 492 591 680 660 885534 571 611 768 678 982 550 629 624 832519 518 597 709 666 916 727 1140 784 1378 511 492 591 680 660 885 722 1106 779 1342534 571 611 768 678 982 739 1210 795 1453 550 629 624 832 690 1051 750 1285 805 1533646 504 468 584 653 654 855663 679630 985 696 1220 756 1469 811 1731 504 468 584 653 654 855 716 1074 774 1307646 1071 711 1313 770 1568 824 1835 663 1162 726 1411 784 1672 837 1944545 607 615 755 678 903 532 559 604 702 668 846557 658 627 810 570 712 638 869545 607 615 755 678 903 735 1052 788 1202 532 559 604 702 668 846 726 990 779 1136557 658 627 810 689 963 745 1117 797 1271 570 712 638 869 699 1026 755 1184 806 13431144 3847 1134 37011153 3999 1162 4154683 726 1299 779 1481 828 1662739 1385 792 1572 840 1758 753 1474 804 1666 852 1857753 1474 804 1666 739 1385 792 1572780 1665 794 1767471 421 560 618 465 402 555 596483 461 571 665 495 503 581 715471 421 560 618 634 828 465 402 555 596 629 802483 461 571 665 644 881 495 503 581 715 654 937471 421 560 618 634 828 699 1050 757 1283 465 402 555 596 629 802 694 1021 753 1252483 461 571 665 644 881 708 1109 766 1348 495 503 581 715 654 937 717 1171 775 1416662 1361 459 384 550 575 625 778675 1454 943 2241662 1361 732 1670 794 1985 851 2307 903 2635 459 384 550 575 625 778 690 994 748 1221675 1454 745 1771 806 2093 862 2422 913 2758 689 1553 757 1877 818 2207 873 2543 924 2886494 550 571 672 638 802 484 506 562 625 630 752505 597 581 723 647 855 516 647 590 776 655 911494 550 571 672 638 802 699 941 754 1089 484 506 562 625 630 752 691 888 747 1035505 597 581 723 647 855 706 996 761 1146 516 647 590 776 655 911 714 1055 768 1207616 1233 680 1395 738 1559 791 1728 604 1155 669 1312 728 1473 782 1639627 1316 690 1481 747 1648 800 1821 639 1402 701 1570 757 1741 809 1917641 628 997 685 1167 739 1343 791 1525 841 1712697 1243 750 1423 801 1608 850 1799 709 1322 761 1506 812 1695697 1243 750 1423 801 1608 628 997 685 1167 739 1343 791 1525734 1492 784 1683 747 1582 796 1777VI. Refrigerant Service Ports Internal WiringPRE-START-UP START-UP Unit PreparationXII. Operating Sequence Safety ReliefVIII. Cooling Evaporator Coil Service CleaningCondenser Coil Condensate DrainII. Lubrication VI. Economizer AdjustmentIII. Evaporator FAN Belt Inspection Manual OUTDOOR-AIR DamperVIII. HIGH-PRESSURE Switch To Use Cooling Charging ChartsIX. LOSS-OF-CHARGE Switch XI. Replacement PartsCooling Charging Chart 558F120 Cooling Charging Chart 558F091 II. ECONOMI$ER IV Troubleshooting Troubleshooting Unit TroubleshootingEconoMi$er IV Troubleshooting Completion DCV Demand Controlled Ventilation and Power ExhaustEconoMi$er IV Preparation Differential EnthalpyTypical Unit Wiring Schematic Cooling Service Analysis Terminal† EconoMi$er IV Input/Output LogicDemand Control Enthalpy Index Call for Free Catalog Service TrainingCopyright 2005 Bryant Heating & Cooling Systems Catalog no Page Temperatures START-UP ChecklistPreliminary Information III. START-UP Electrical
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558F specifications

The Bryant 558F is a highly efficient and versatile gas furnace designed to provide reliable heating for residential spaces. Known for its exceptional performance and advanced technology, the 558F caters to homeowners looking for comfort, efficiency, and sustainability in their heating solutions.

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