HVAC Systems: How They Work

November 9, 2000
/ Print / Reprints /
/ Text Size+
Figure 1. HVAC system components.

The main purpose of commercial HVAC (heating, ventilating, and air conditioning) systems is to provide the people working inside buildings with "conditioned" air so that they will have a comfortable and safe work environment. "Conditioned" air means that air is clean and odor-free, and the temperature, humidity, and movement of the air are within certain comfort ranges.

Many factors affect the way people respond to their work environment. Air quality is one of these factors. The American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) has established standards which outline air quality for indoor comfort conditions that are acceptable to 80% or more of a commercial building's occupants. Generally, these indoor comfort conditions, sometimes called the "comfort zone," are between 68 degrees F and 75 degrees F for winter and 73 degrees F to 79 degrees F during the summer. Both these temperature ranges are for room air at approximately 50% relative humidity and moving at velocity of 30 feet per minute or slower.

Heat and Temperature

Heat is energy in the form of molecules in motion. As a material becomes warmer, its molecular motion and energy level (temperature) increases, and vice versa. Temperature describes the level of heat (energy) with reference to no heat. Heat is a positive value relative to no heat. Therefore, warm, hot, cool and cold are comparative terms used to describe higher or lower temperature levels.

The Fahrenheit scale is the standard system of temperature measurement used in the United States. The U.S. is one of the few countries in the world that still uses this system. Most countries use the metric temperature measurement system-the Celsius scale. However, the Fahrenheit and Celsius scales are currently used interchangeably in the U.S. to describe equipment and fundamentals in the heating, ventilating and air conditioning industry.

Heat Transfer

Heat naturally flows from a higher energy level to a lower energy level. In other words, heat travels from a warmer material to a cooler material. The unit of measurement used to describe the quantity of heat contained in a material is a British thermal unit (Btu).

When there is a temperature difference between two materials, heat transfer will occur. In fact, temperature difference is the driving force behind heat transfer,

i. e., the greater the temperature difference, the greater the heat transfer. The rate of heat transfer can be described by adding the dimension of time, for example, British thermal units per hour (Btu/hr or Btuh).

Types of Heat Transfer

The three types of heat transfer are conduction, radiation, and convection. Your hand touching a cold wall is an example of heat transfer by conduction. A portable electric heater that glows red-hot is an example of heat transfer by radiation.

Heat transfer by convection is when some material that is readily movable such as air, water, steam, and refrigerant moves heat from one location to another. For example, when air is heated, it rises; this is heat transfer by "natural" convection. "Forced" convection is when a fan or pump is used to convey heat in fluids such as air and water. Compare the words "convection" (the action of conveying) and "convey" (to take or carry from one place to another).

HVAC System Components

The basic components in a common central HVAC system as illustrated in Figure 1 are:

1. Fan(s) to circulate the supply air (SA) and return air (RA).

2. Supply air ductwork in which the air flows from the supply fan to the conditioned space.

3. Air devices such as supply air outlets and return air inlets.

4. Return air path or ductwork in which the air flows back from the conditioned space to the mixed air chamber (plenum).

5. Outside air (OA) device such as an opening, louver or duct to allow for the entrance of outside air into the mixed air chamber.

6. Mixed air chamber to receive the return air and mix it with outside air.

7. Filter section(s) to remove dirt and dust particles from the mixed air.

8. Heat exchanger(s) such as hot water coil(s), steam coil(s), refrigerant evaporator(s), or chilled water coil(s) to add heat to or remove heat from the circulated air.

9. Auxiliary heating devices such as natural gas furnace(s) or electric heating element(s).

10. Compressor(s) to compress the refrigerant vapor and pump the refrigerant around the system.

11. Condenser(s) to remove heat from the refrigerant vapor and condense it to a liquid.

12. Fan(s) to circulate outside air across air-cooled condenser(s)

13. Pump(s) to circulate water through water-cooled condenser(s); condenser water pump (CWP); and condenser water supply (CWS) and return (CWR).

14. Pump(s) to circulate hot water from the boiler(s) through the hot water coil(s) and back or to circulate chilled water from the chiller(s) through the chilled water coil(s) and back to the chiller(s).

15. For central systems, water or steam boiler(s) as a central heating source.

16. For central systems, water chiller(s) as a central cooling source.

17. For central systems, cooling tower(s) with water-cooled condenser(s).

18. Controls to start, stop, or regulate the flow of air, water, steam, refrigerant and electricity.

HVAC System Example

Airflow: The volume of air required to heat, cool and provide good indoor air quality is calculated based on the heating, cooling and ventilation loads. The air volumes are in units of cubic feet per minute (cfm). Constant volume fans (supply and return) circulate the conditioned air.

For the example system (Figure 1), the total volume of air supplied to the conditioned space is 6,000 cfm. Of this 6,000 cfm circulated through the conditioned space and back to the air handling unit (AHU), 1,000 cfm is exhausted in the return air plenum through the exhaust air (EA) damper. The remaining 5,000 cfm goes into the mixed air chamber.

At the same time, 1,000 cfm is exhausted another 1,000 cfm is brought in through the outside air (OA) dampers in the mixed air plenum. This 1,000 cfm of outside air mixes with the remaining 5,000 cfm of return air. The 6,000 cfm of mixed air then travels through the filters into the coil sections.

Heating: The heating load requirement is based on design indoor and outdoor winter conditions. The design conditioned space heating load is 227,000 Btu/hr. This is the amount of heat lost (mainly by conduction) through the walls, windows, doors, roofs, etc., in the winter. An additional amount of heat is required to heat the outside ventilation air based on design conditions.

To maintain the temperature and humidity in the comfort zone for the conditioned space, the heating cycle is this: The supply air leaves the heating coil carrying 227,000 Btuh of heat. The air goes through the supply air fan (SAF), down the insulated supply duct, past the manual volume dampers (MVD) which have been set for the correct amount of air for each diffuser, and into the conditioned space. The supply air gives up all of its 227,000 Btuh of heat to the conditioned space to replace the 227,000 Btuh that is leaving the space through the walls, roof, etc. As the air gives up its heat it makes its way through the room and into the return air (RA) inlets, then into the return air duct and back to the air handling unit. This AHU is located on the roof and is therefore designated as a "roof top unit" (RTU).

The return air goes through the return air fan (RAF), through the return air automatic temperature- controlled (ATC) dampers into the mixed air chamber and mixes with the outside air (OA). The mixed air flows through the filters, through the cooling coil (which is off), and into the heating coil. The mixed air travels through the heating coil where it picks up heat via conduction through the hot water tubes in the coil. In addition to the tubes, the heating coil also has fins attached to the tubes to facilitate the heat transfer. The supply air leaves the heating coil carrying its 227,000 Btuh of heat and the air cycle repeats.

The water, after giving up heat to the air, leaves the coil and goes back to the oil-fired boiler through the hot water return (HWR) pipe and into the boiler where it picks up the same amount of heat that it has just given up in the coil. The water leaves the boiler, flows through the hot water pump (HWP) and is pumped through the hot water supply (HWS) or heating hot water supply (HHWS) piping into the heating coil to give up its heat into the mixed air and the water cycle repeats.

Ventilating: In the human respiratory process, oxygen is inhaled and carbon dioxide, a contaminant, is exhaled. In commercial buildings, carbon dioxide and other contaminants such as cigarette smoke must be continuously removed or uncomfortable or unhealthy conditions will result. "Ventilation" is the process of supplying outside air to buildings in the proper amount to offset the contaminants and odors produced by people and equipment.

In many situations, local building codes stipulate the amount of ventilation required for commercial buildings and work environments to maintain good indoor air quality (IAQ). This requirement is usually 20 cubic feet per minute of outside air for each occupant. The example HVAC system supplies air to a suite in an office complex designed for 50 people. Therefore, the outside air requirement is 1,000 cfm.

Air Conditioning (Cooling): For this system, the total heat given off by the people, lights and equipment in the conditioned space plus the heat entering the space through the outside walls, windows, doors, roof, etc., and the heat contained in the outside ventilation air will be approximately 195,000 Btu/hr. A ton of refrigeration is equivalent to 12,000 Btu/hr of heat. Therefore, this HVAC system requires a chiller that can provide 16.25 tons of cooling.

To maintain the proper temperature and humidity in the conditioned space, the cooling cycle is described as: The supply air (which is approximately 20 degrees (F cooler than the air in the conditioned space) leaves the cooling coil and goes through heating coil (which is off), through the supply air fan, down the duct and into the conditioned space. The cool supply air picks up heat in the conditioned space. The warmed air makes its way into the return air inlets, then into the return air duct and back to the air handling unit. The return air goes through the return air fan into the mixed air chamber and mixes with the outside air. The mixed air goes through the filters and into the cooling coil. The mixed air flows through the cooling coil where it gives up its heat into the chilled water tubes in the coil. This coil also has fins attached to the tubes to facilitate heat transfer. The cooled supply air leaves the cooling coil and the air cycle repeats.

The water, after picking up heat from the mixed air, leaves the cooling coil and goes through the chilled water return (CHWR) pipe to the water chiller's evaporator. The "warmed" water flows into the chiller's evaporator (sometimes called the water cooler) where it gives up the heat (from the mixed air) into the refrigeration system. The newly "chilled" water leaves the evaporator, goes through the chilled water pump (CHWP) and is pumped through the chilled water supply (CHWS) piping into the cooling coil to pick up heat from the mixed air and the water cycle repeats.

The evaporator is a heat exchanger that allows heat from the CHWR to flow by conduction into the refrigerant tubes. The liquid refrigerant in the tubes "boils off" to a vapor removing heat from the water and conveying the heat to the compressor and then to the condenser. The heat from the condenser is conveyed to the cooling tower by the condenser water. Finally, outside air is drawn across the cooling tower, removing the heat from the water through the process of evaporation.

An HVAC system is simply a group of components working together to move heat to where it is wanted (the conditioned space) or to remove heat from where it is not wanted (the conditioned space) and put it where it is unobjectionable (the outside air).

Did you enjoy this article? Click here to subscribe to edc Magazine. 

You must login or register in order to post a comment.



Image Galleries


Metl-Span panels have contributed to energy-efficient projects including 502 Rigsbee, Ballard Blocks, Haughton Middle School, and Pacific Plaza.


NCI Group's Candy McNamee, LEED Green Associate, explains how dematerialization can greatly affect the building industry over time, how AEC professionals will be challenged to incorporate the practice into their work and what the benefits are.

More Podcasts

EDC Magazine


2014 November

Learn about the California drought, how North Carolina retailers are going green, and more.
Table Of Contents Subscribe

iPad Usage

Do You Use an iPad for?
View Results Poll Archive

EDC Magazine STORE

sustainable healthcare.jpg
Sustainable Healthcare Architecture, 2nd Edition

The essential guide for architects, interior designers, engineers, healthcare professionals, and administrators who want to create healthy environments for healing.

More Products

Green Product Buzz Guide

Green Product Buzz GuideEDC's Green Product Buzz Guides bring you the latest in green building products and services from companies exhibiting at trade shows, including Greenbuild, the AIA Expo, Coverings, Surfaces and more.


fb twitter youtube linked Google+