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Air Distribution

Air Distribution. North Seattle Community College HVAC Program Instructor – Mark T. Weber, M.Ed. Trail EP by Nobara Hayakawa is licensed under a Attribution-NonCommercial-NoDerivatives. Lesson Objectives. Understand: The importance of proper air distribution and air flow;

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Air Distribution

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  1. Air Distribution North Seattle Community College HVAC Program Instructor – Mark T. Weber, M.Ed. Trail EP by Nobara Hayakawa is licensed under a Attribution-NonCommercial-NoDerivatives

  2. Lesson Objectives • Understand: • The importance of proper air distribution and air flow; • Air flow measurement; • Causes of low air flow; • The use of manufacturers data for system checks;

  3. Introduction • You’re in the business of heat transfer. • Refrigerants changing state makes this possible. • Refrigerants evaporate and absorb heat. • Refrigerants condense and reject heat. As an HVACR professional, you are engaged in the business of heat transfer. Whether they know it or not, your customers hire you to move heat from one location to another. In the summer, your job is to make sure that the systems you service remove unwanted heat from indoor conditioned spaces and reject it into the outdoor air. In the winter, the systems must remove heat from the outdoor air or soil and reject it into the indoor air to keep your customers warm.

  4. Air Distribution • Low airflow or air that is too cold may not provide enough heat to boil all of the refrigerant: • Liquid refrigerant reaches the compressor. • Too much airflow or air that is too warm may increase the load on the compressor and reduce dehumidification. One of the most important system performance checks that you can carry out is air flow measurement. The relationship between air flow and the refrigeration cycle is critical. Circulating air is the source of heat needed to boil liquid refrigerant in the evaporator. If the air flow is too low, not enough heat will be available to evaporate the entire amount of liquid refrigerant fed into the coil by the metering device. Likewise, if the air entering the evaporator is too cool, not all of the liquid fed into the coil will be evaporated. All of the refrigerant entering the compressor must be in the vapor state. If the evaporator is unable to boil off the entire amount of liquid refrigerant for any reason, liquid can enter the compressor and damage mechanical components. Problems also arise on the other end of the spectrum. If the air flow across an evaporator is excessive, too much heat will be added to the refrigerant. System pressures will rise, resulting in operating conditions that can easily overload a compressor motor. As you can see, it is very important for the volume and temperature of the air entering an evaporator coil to be correct.

  5. Airflow • 400 CFM/ton: • Typical A/C. • 450 CFM/ton: • Typical heat pump; • High sensible heat. • 350 CFM/ton: • Higher levels of outdoor air; • High latent loads (dehumidification).

  6. Airflow Measurement • External Static Pressure: • Compare to manufacturers’ tables; • Measured with a “diaphragm-type” pressure gauge: • “Magnehelic”; or • Electronic. • Static pressure. • Velocity pressure . • Diagram on next page. A number of methods are available to service technicians for verifying air flow across the evaporator coil. One of these methods involves measuring the external static pressure (ESP) developed by the furnace or air-handler blower. Static pressure is the force of air exerted in all directions (bursting pressure) on the inside surface of ductwork. It is a measure of potential energy (pushing outward against the duct walls) and is used to determine the total resistance to air movement imposed by the ductwork system. Velocity pressure is a measure of kinetic energy, or the pressure exerted by moving air. An electronic meter or diaphragm-type differential pressure gauge calibrated in inches of water column (also called inches of water gauge, abbreviated in. w.g.) is used to measure air pressure within ductwork. The image on this page shows a popular gauge used for this purpose. External static pressure is the sum of the absolute values of static pressures in the supply and return ductwork of an operating system when measured near the furnace or air-handler unit. The measured ESP is used together with blower tables supplied by the equipment manufacturer to determine the air flow being delivered by the indoor section of the system. The diagram on the following slide shows how ESP is measured.

  7. External Static Pressure Measurement In the example illustrated in the drawing shown, the supply static pressure (SSP) is equal to 0.4 in. w.g. above atmospheric pressure and the return static pressure (RSP) is equal to 0.1 in. w.g. below atmospheric pressure. The preferred static pressure for the return ductwork used in a residential heat-pump system is 0.08 in. w.g. Any improvements made in the aerodynamics of existing return ductwork that reduce the RSP will increase air flow through the supply ducts. Ductwork improvements that have the most dramatic effect on the performance of existing systems are typically upgrades to the return ductwork. The plus and minus signs (+ and –) are ignored and the values of the two pressures are added together to determine the external static pressure. In this example, the ESP is equal to 0.5 in. w.g. (0.4 + 0.1). For systems with cooling capacities of 5 tons or less, you should not measure an ESP greater than 0.5 in. w.g. If you do, the ductwork is imposing too much resistance to air flow, and modifications should be made to improve the aerodynamic performance of the ductwork system. An ESP reading of less than 0.5 in. w.g. is preferred to reduce the fan power required to deliver the rated air flow. Many blowers do not deliver the rated air flow (400 cfm per ton of capacity) when the ESP measures more than 0.5 in. w.g.

  8. Airflow Measurement • Temperature-rise method. • Calculate Btus from electric heater: • Amps X volts X 3.413 Btus/watt = Btus. • For gas, clock meter to calculate input X efficiency. • Measure temperature difference between supply and return: • Use one thermometer; and • Be out of the line-of-sight of the heater. • CFM = Btus ÷ (TR X 1.08).

  9. Duct Design • Proper duct design prevents high pressure drops that cause low airflow: • Use ACCA Residential Duct Systems Manual D; • Registers and diffusers—face velocity of no more than 700 ft/min; • Supply trunks 700 ft/min (900 max); • Branch 600 ft/min. • Return trunks 600ft/min (700 max); • Branch 400 ft/min. • Return grill face velocity 500 ft/min max; and • Filter grill 300 ft/min max.

  10. Velocity Recommendations

  11. Causes of Low Air Flow • Duct systems; • Dirty air filters; • Dirty coils; • Closed or restricted diffusers; • Blower: • Wrong speed tap; • Bearing wear; • Low voltage; and • Dirty fan blades.

  12. Heat-pump Air Flow • Low airflow will also effect the heat pump in the heating mode: • High head pressure; • Lower heat output; and • Higher operating costs. • Inadequate air flow volumes also have a dramatic impact on heat-pump systems operating in the heating cycle. In the winter, the indoor coil functions as the condenser and adequate air flow is critical for many reasons. Low air flow volume through the indoor coil reduces the amount of heat delivered to the conditioned space. This results in the need for more auxiliary heat than would otherwise be necessary to maintain space temperature. Low air flow across the indoor coil also causes refrigerant circuit pressures to rise. Elevated pressures can increase operating costs and overload the compressor.

  13. Air Balance • Must have correct total airflow. • Each room must have the correct airflow to provide even temperatures. • Refrigeration cycle components may fail due to improper airflow.

  14. I want to watch her shift with those heels on!

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