Johnson Controls 340968-XIM-A-0108 Gase Rate Cubic Feet PER HOUR1, Checking Supply AIR CFM

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TABLE 12: GASE RATE - CUBIC FEET PER HOUR1

SECONDS

SIZE OF TEST DIAL

FOR ONE

 

 

REV.

1/2 CU. FT.

1 CU. FT.

 

 

 

10

180

360

12

150

300

14

129

257

16

113

225

18

100

200

 

 

 

20

90

180

22

82

164

24

75

150

26

69

138

28

64

129

 

 

 

30

60

120

32

56

113

34

53

106

36

50

100

38

47

95

 

 

 

40

45

90

42

43

86

44

41

82

46

39

78

48

37

75

 

 

 

50

36

72

52

35

69

54

34

67

56

32

64

58

31

62

60

30

60

 

 

 

1.EXAMPLE: By actual measurement, it takes 38 seconds for the hand on the 1-cubic foot dial to make a revolution with just a 100,000 BTUH furnace running. Using this information, locate 38 seconds in the first column of Table 12. Read across to the column headed “1 Cubic Foot,” where you will see that 95 cubic feet of gas per hour are consumed by the furnace at that rate. Multiply 95 x 1050 (the BTU rating of the gas obtained from the local gas company). The result is 99,750 BTUH, which is close to the 100,000 BTUH rating of the furnace.

340968-XIM-A-0108

CHECKING SUPPLY AIR CFM

To check the supply air CFM after the initial balancing has been completed:

1.Remove the two ¼ inch dot plugs in the duct panel.

2.Insert at least 8 inches of ¼ inch tubing into each of these holes for sufficient penetration into the airflow on both sides of the indoor coil.

3.Using an inclined manometer, determine the pressure drop across the dry evaporator coil. Since the moisture on an evaporator coil may vary greatly, measuring the pressure drop across a wet coil under field conditions would be inaccurate. To ensure a dry coil, the compres- sors should be deactivated while the test is being run.

4.Knowing the pressure drop across a dry coil, the actual CFM through the unit can be determined from the curve in Coil Delta P vs. Supply Air CFM figure.

Failure to properly adjust the total system air quan- tity can result in extensive system damage.

After readings have been obtained, remove the tubes and reinstall the two ¼ inch plugs removed in Step 1.

De-energize the compressors before taking any test mea- surements to ensure a dry indoor coil.

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Johnson Controls Unitary Products

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Contents Affinity Series ExportTable of Contents Inspection GeneralApprovals Renewal PartsUnit Application Data InstallationLimitations LocationRoof Curb Unit Weights and Center of GravityDuct Work FiltersService Access Power and Control WiringThermostat Natural GAS Application Data PROPANE1 LP GAS Application DataGAS Piping Natural GAS Pipe Sizing CHART1Propane LP GAS Pipe Sizing CHART1 GAS ConnectionFlue Vent Hood Flue Vent Outlet AIR HoodPhysical Data Electrical DataUnit Dimensions Front Unit Minimum CLEARANCES1Unit Dimensions Front & Bottom Sequence of Operation HeatingPost Purge START-UP Manifold GAS Pressure Adjustment POST-START Check List GASPilot Instructions Adjustment of Temperature Rise Checking GAS InputGase Rate Cubic Feet PER HOUR1 Checking Supply AIR CFMDNA Coil Delta P vs Airflow Superheat Charging Table for DNA024 Superheat Charging Table for DNA030Superheat Charging Table for DNA036 Superheat Charging Table for DNA042 Superheat Charging Table for DNA048Superheat Charging Table for DNA060 XIM-A-0108 Typical Wiring Diagram Notes See FigureJohnson Controls Unitary Products York Drive Norman, OK

340968-XIM-A-0108 specifications

Johnson Controls 340968-XIM-A-0108 is a sophisticated component designed for advanced building management and automation systems. This device is engineered to enhance the performance and efficiency of HVAC (Heating, Ventilation, and Air Conditioning) systems, contributing significantly to energy conservation and optimal climate control in commercial and industrial environments.

One of the main features of the Johnson Controls 340968-XIM-A-0108 is its robust compatibility with various building management systems. This component integrates seamlessly with existing systems, allowing for quick deployment and ease of use. The flexibility of this device supports multiple communication protocols, making it a versatile choice for systems upgrades or replacements.

Another standout characteristic of the 340968-XIM-A-0108 is its advanced sensing technologies. This device is equipped with high-precision sensors that monitor temperature, humidity, and air quality, providing real-time data to the building management system. The ability to collect accurate environmental data enables facility managers to make informed decisions that enhance comfort and efficiency.

Energy efficiency is a key focus of the Johnson Controls 340968-XIM-A-0108. The device incorporates intelligent algorithms that optimize HVAC operations, significantly reducing energy consumption. By analyzing usage patterns and adjusting settings accordingly, it helps facilities decrease operational costs while maintaining ideal indoor conditions.

In addition to its operational efficiency, the Johnson Controls 340968-XIM-A-0108 features a user-friendly interface that simplifies monitoring and management. The intuitive design allows operators to easily access system data and make adjustments as necessary without requiring extensive technical knowledge. This feature enhances the overall user experience and promotes efficient building management.

Safety and reliability are also prioritized in the design of the 340968-XIM-A-0108. Built with durable materials and rigorous testing standards, it ensures long-term operation under various conditions. Furthermore, the device supports multiple fail-safes and alarms, providing peace of mind to facility managers regarding system performance and safety.

In conclusion, the Johnson Controls 340968-XIM-A-0108 stands out in the building automation market due to its compatibility, sensing technologies, energy efficiency, user-friendly interface, and reliable performance. These features make it an essential component for optimizing HVAC operations and ensuring sustainable building management practices.