HVAC Glossary of Terms Index

2.5% Design

Outside summer temperatures and coincident air moisture content that will be exceeded only 2.5% of the hours from June to September. In other words, 2.5% design conditions are outdoor temperatures historically exceeded 73 out of the 2,928 hours in these summer months.
Abatement

Reduction or removal of a contaminant.
Absolute Humidity

This is often confused with mixing ratio. It is the ratio of the mass of water vapor to the unit volume of moist air. Vaisala products give this output as grams of water per cubic metre of air (g/m3).
Absolute Pressure

Gauge pressure plus atmospheric pressure (14.7 lb.per sq.in.) equals absolute pressure.
Absolute Temperature

Temperature measured from absolute zero.
Absolute Zero Temperature

Temperature at which all molecular motion ceases (-460 F. and -273 C.)
Absorbent

Substance with the ability to take up or absorb another substance.
Absorption Refrigerator

Refrigerator which creates low temperature by using the cooling effect formed when a refrigerant is absorbed by chemical substance.
ACCA

A leading HVAC/R Association – http://www.acca.org/
Acceptable indoor air quality

Indoor air that does not contain harmful concentrations of contaminants; air with which at least 80% of building occupants do not express dissatisfaction.
Accessible Hermetic

Assembly of a motor and compressor inside a single bolted housing unit.
Accumulator

Storage tank which receives liquid refrigerant from evaporator and prevents it from flowing into suction line before vaporizing. Tank on the suction side of a system that holds excess refrigerant to prevent slugging the compressor with liquid.
ACGIH

American Conference of Governmental Industrial Hygienists.
ACH

Air Changes Per Hour. The number of times that air in a house is completely replaced with outdoor air in one hour.
Acid Condition In System

Condition in which refrigerant or oil in system is mixed with fluids that are acid in nature.
ACR Tubing

Tubing used in air conditioning and refrigeration. Ends are sealed to keep tubing clean and dry.
Action Level

A term used to identify the level of indoor radon at which remedial action is recommended.
Action Packet

In reference to the indoor air quality Tools for Schools Kit. The packet contains three components – an introductory memo, IAQ Backgrounder, and IAQ Checklist – to assist school personnel to implement an effective yet simple indoor air quality program in their school.
Activated Alumina

Chemical which is a form of aluminum oxide. It is used as a drier or desiccant.
Activated Carbon

Specially processed carbon used as a filter drier ; commonly used to clean air.
Actuator

That portion of a regulating valve which converts mechanical fluid, thermal energy or electrical energy into mechanical motion to open or close the valve seats.
Add On Heat Pump

Installing a heat pump in conjunction with an existing fossil fuel furnace. The result is a dual fuel system.
Adiabatic Compression

Compressing refrigerant gas without removing or adding heat.
Adjustable Grille

A grille with linear blades which can be adjusted to vary the direction of the discharged air. The linear blades are normally either vertical or horizontal, or both horizontal and vertical.
Adsorbent

Substance with the property to hold molecules of fluids without causing a chemical or physical damage.
Aeration

Act of combining substance with air.
Aerosol

A suspension of liquid or solid particles in air.
AFLU (Annual Fuel Utilization Efficiency)

A rating that reflects the efficiency of a gas furnace in converting fuel to energy. A rating of 90 means that approximately 90% of the fuel is utilized to provide warmth to your home, while the remaining 10% escapes as exhaust.
AFUE (Annual Fuel Utilization Efficiency )

This number represents how efficiently a furnace converts fuel to energy. The ratio of annual output of useful energy or heat to the annual energy input to the furnace. The higher the AFUE, the more efficient the furnace — higher efficiency translates to more savings on fuel bills. This will range from 80% to 95%. Percentage of fuel used for heating. A measure of heating efficiency, in consistent units, determined by applying the federal test method for furnaces. This value is intended to represent the ratio of heat transferred to the conditioned space by the fuel energy supplied over one year.
Agitator

Device used to cause motion in confined fluid.
AHU (Air Handler Unit)

The inside part of the A/C system that contains the blower, cooling (evaporator) coil, and heater. The part of an HVAC system responsible for moving air, which may also clean, heat, or cool the air. This refers to equipment used to provide conditioned air to a space. The air handler unit generally includes a blower or fan, heating and/or cooling coils, and related equipment such as controls, condensate drain pans, and air filters. Does not include ductwork, registers or grilles, or boilers and chillers.
Air Change

The amount of air required to completely replace the air in a room or building; not to be confused with recirculated air.
Air Cleaner

Device used for removal of airborne impurities. A device that actively removes impurities from the air, including forced air filtration systems and electronic air cleaners. Air cleaners may be added to HVAC systems or stand-alone room units.
Air Cleaning

An indoor air quality control strategy to remove various airborne particulates and/or gases from the air. The three types of air cleaning most commonly used are particulate filtration, electrostatic precipitation, and gas sorption.
Air Coil

Coil on some types of heat pumps used either as an evaporator or condenser.
Air Conditioner

Device used to control temperature, humidity, cleanliness and movement of air in a confined space.
Air Conditioning

Control of the temperature, humidity, air movement and cleaning of air in a confined space.
Air Cooler

Mechanism designed to lower temperature of air passing through it.
Air Core Solenoid

Solenoid that has a hollow core instead of a solid core.
Air Diffuser

An air distribution outlet or grille designed to direct airflow into desired patterns. Supply air terminal device, designed to direct airflow into desired patterns, usually placed in the ceiling, generally of circular, square or rectangular shape, and composed of divergent deflecting members.
Air Diffusion

Distribution of the air in a space, called the treated space, by means of devices, called air terminal devices, in a manner so as to meet certain specified conditions, such as air change rate, pressure, cleanliness, temperature, humidity, air velocity and noise level.
Air Distribution

The transportation of a specified air flow to or from the treated space or spaces, generally by means of ductwork.
Air Exchange Rate

The rate of air flow moving through a space, usually expressed in terms of room volume units per unit of time such as room air changes per hour.
Air Exchange Rate

The rate at which outside air replaces indoor air in a space. Expressed in one of two ways: the number of changes of outside air per unit of time in air changes per hour (ACH); or the rate at which a volume of outside air enters per unit of time – cubic feet per minute (cfm).
Air Gap

The space between magnetic poles or between rotating and stationary assemblies in a motor or generator.
Air Handler

Fan-blower, filter and housing parts of a system. Fan-blower, filter, heat transfer coil, and housing parts of a system. Also known as the blower section and part of the split system, this unit is commonly in your home or attic and blows the air through your house. This has to be matched with the condenser properly to assure maximum efficiency. This will contain your heating and evaporator coil.
Air Infiltration

Leakage of air into rooms through cracks, windows doors and other openings.
Air Quality Standard

A government-mandated regulation that specifies the maximum contaminant concentration beyond which health risks are considered to be unacceptable.
Air Source Equipment

Heat pumps or air conditioners that uses the outdoor air to transfer heat to and from the refrigerant in the unit.
Air Terminal Device

A device located in an opening provided at the boundaries of the treated space to ensure a predetermined motion of air in this space.
Air Terminal Device, Lighting Troffer

An air terminal device, usually in the form of a slot or combination of slots, designed for use with a troffer unit.
Air Terminal Device, Linear

Air terminal device (grille) with an aspect ratio of 10: 1 or more.
Air Terminal Device, Slot

A device with one or several slots with an aspect ratio of 10: 1 or more for each slot (the aspect ratio is the ratio of the length to the width of the closed rectangular opening). A slot may or may not have an adjustable member to vary the direction of the air jet(s) or air flow rate.
Air Terminal Device, Supply

An air terminal device through which air enters a treated space. It usually consists of one or several deflecting members which ensure reduction of the air velocity in the occupied zone as well as efficient mixing of the supply air with the air in the treated space. Moreover supply air terminal devices usually determine the direction of the air jet(s).
Air-Cooled Condenser

Heat of compression, plus the heat of absorption, is transferred from refrigerant within coil to surrounding air, either by convection or fan or blower.
Airflow

The distribution or movement of air.
Ak value (of an air terminal device)

Quotient obtained by dividing a measured air flow rate by a measured air velocity according to a specific process and a specific instrument.
Algaecide

Normally in tablet form, placed in evaporator drain pan. Used to help slow the growth of bacteria.
Allergens and Pathogens

Biological material, including bacteria, viruses, fungi, mold spores, pollens, skin flakes and insect parts are ubiquitous in indoor environments. These particulates range from less than one to several microns in size. When airborne, they are usually attached to dust particulates of various sizes so that all sizes of airborne particulates may include them.
Alternating Current (AC)

Flow of electricity that constantly changes direction between positive and negative sides. Almost all power produced by electric utilities in the United States moves in current that shifts direction at a rate of 60 times per second.
Ambient

The surrounding atmosphere; encompassing on all sides; the environment surrounding a body but undisturbed or unaffected by it.
Ambient Air

The air surrounding a building; outside air.
Ambient Air Temperature

Surrounding temperature, such as the outdoor air temperature around a building.
Ampere (A or Amp)

The primary unit of measurement of electrical current. One ampere of current is produced in a circuit by 1 volt acting through a resistance of 1 ohm.
Amplification

An increase in the numbers or concentration of a microbe or its products through reproduction and growth of the microbe.
Annual Effects

The total effects in energy use (measured in megawatthours) and peak load (measured in kilowatts) caused by all participants in the DSM programs that are in effect during a given year. It includes new and existing participants in existing programs (those implemented in prior years that are in place during the given year) and all participants in new programs (those implemented during the given year). The effects of new participants in existing programs and all participants in new programs should be based on their start-up dates (i.e., if participants enter a program in July, only the effects from July to December should be reported). If start-up dates are unknown and cannot be reasonably estimated, the effects can be annualized (i.e., assume the participants were initiated into the program on January 1 of the given year). The annual effects should consider the useful life of efficiency measures, by accounting for building demolition, equipment degradation and attrition.
Antimicrobial

Agent that kills microbial growth.
Appliance Efficiency Standards

California Code of Regulations, Title 20, Chapter 2, Subchapter 4: Energy Conservation, Article 4: Appliance Efficiency Standards. Appliance Efficiency Standards regulate the minimum performance requirements for appliances sold in California and apply to refrigerators, freezers, room air conditioners, central air conditioners, gas space heaters, water heaters, plumbing fittings, fluorescent lamp ballasts and luminaires, and ignition devices for gas cooking appliances and gas pool heaters. New National Appliance Standards are in place for some of these appliances and will become effective for others at a future date.
APR

Air Purifying Respirator
ARI (Air-Conditioning and Refrigeration Institute)

Air-Conditioning and Refrigeration Institute is a nonprofit, voluntary organization comprised of heating,air conditioning and refrigeration manufacturers. ARI publishes standards for testing and rating heat pumps and air conditioners to provide you with a standardized measure of comparison. So, ARI ensures a level of performance within the industry.
Asbestos

A class of silicate minerals composed of long, thin fibers.
ASHRAE

A leading HVAC/R Association – American Society of Heating, Refrigerating and Air Conditioning Engineers – http://www.ashrae.org/ The trade association that provides information and sets standards for the industry.
ASTM

American Society for Testing and Materials.
ASTM

American Society for Testing and Materials.
Backdrafting

Reverse flow of combustion gases down the chimney of a vented combustion appliance, which is often caused by depressurization of the room where the appliance is located. A condition where the normal movement of combustion products from a combustion appliance up a flue is reversed so that the combustion products can enter the building.
Background Concentration

The level of a contaminant present before the introduction of a new source.
Balance Point

The lowest outdoor temperature at which the refrigeration cycle of a heat pump will supply the heating requirements. Usually a temperatyre between 30°F to 45°F — at which a heat pump’s output exactly equals the heating needs of the house. Below the balance point, supplementary electric resistance heat is needed to maintain indoor comfort.
Balancing

The process of adjusting the flow of air in duct systems, or water flow in hot-water heating systems. Proper balancing is performed using accurate instrumentation to deliver the right amount of heating or cooling to each area or room of the home.
Bioaerosol

An airborne microbial contaminant, such as a virus, bacteria, fungus, algae, or protozoa, or particulate material associated with one of these microorganisms.
Biocide

Substance or chemicals that kills organisms such as molds.
Biological Contaminants

Agents derived from, or that are, living organisms (e.g., viruses, bacteria, fungi, and mammal and bird antigens) that can be inhaled and can cause many types of health effects including allergic reactions, respiratory disorders, hypersensitivity diseases, and infectious diseases. Also referred to as “microbiologicals” or “microbials.”
Blower door

A large powerful variable-speed fan mounted in a doorway that blows air into (pressurizes) or sucks air out of (depressurizes) a house. It’s used to test for air leakage in a house. The size and complexity of the fan varies, but all blower doors have adjustable frames around the fan so that they can fit snugly into most doorways.
Blower (Fan)

An air handling device for moving air in a distribution system.
Boiler

A device for generating steam for power, processing, or heating purposes or for producing hot water for heating purposes or hot water supply. Heat from an external combustion source is transmitted to a fluid contained within the tubes in a boiler shell, a closed vessel in which water is converted to pressurized steam. This fluid is delivered to an end-use at a desired pressure, temperature, and quality.
Boot

A piece of duct used to connect ducts with registers.
Breathing Zone

The area of a room in which occupants breathe as they stand, sit, and lie down.
Breathing Zone

That area of a room in which occupants breathe as they stand, sit, or lie down.
BRI (Building-Related Illness)

Diagnosable illness whose symptoms can be identified and whose cause can be directly attributed to airborne building pollutants (e.g., Legionnaire’s disease, hypersensitivity pneumonitis). Also: A discrete, identifiable disease or illness that can be traced to a specific pollutant or source within a building. (Contrast with “Sick building syndrome”).
BTU (British Thermal Unit)

The amount of heat that will raise or lower one pound of water 1 degree F. at 39.2 degrees F. One BTU is the equivalent of the heat given off by a single wooden kitchen match. The British Thermal Unit is a standard of measure for cooling and heating capacities. This is how the capacity of air conditioning is measured. A standard measure of heat energy in the U.S., commonly used to measure the energy content of various fuels and steam. It takes one Btu to raise the temperature of one pound of water by one degree Fahrenheit at sea level. For example, it takes about 2,000 Btus to make a pot of coffee. One Btu is equivalent to 252 calories, 778 foot-pounds, 1055 joules, and 0.293 watt-hours. Note: In the abbreviation, only the B is capitalized. For your home, it represents the measure of heat givens off when fuel is burned for heating or the measure of heat extracted from your home for cooling.
BTUH (British Thermal Unit Per Hour)

Establishes a time reference to btu input or output rates. A BTUH is how many BTUs are used per hour.
Buffer zone

An area within the home between the conditioned zones and the outside. Thus it normally is not conditioned (for instance, attics, attached garages, crawlspaces, basements, and enclosed porches).
Building Energy Efficiency Standards

California Code of Regulations, Title 24, Part 2, Chapter 2-53; regulating the energy efficiency of buildings constructed in California.
Building, Envelope

the outer walls, windows, doors, roof, and floors of a building; the building shell.
Building Envelope

Elements of the building, including all external building materials, windows, and walls, that enclose the internal space.
Butane

A hydrocarbon gas found in the earth along with natural gas and oil. Butane turns into a liquid when put under pressure. It is sold as bottled gas. It is used to run heaters, stoves and motors, and to help make petrochemicals.
CAE (Combined Annual Efficiency)

A measure of the amount of heat produced for every dollar of fuel consumed for both home heating and water heating.
Calorie

One energy calorie is equivalent to 4.2 joules. Thus, it takes 500,000 calories of energy to boil a pot of coffee. One food calorie equals 1,000 energy calories.
Capacitor

A device used to start a motor or compressor (or to keep it running after start up.)
Capacity (or System Capacity )

The output or producing ability of a piece of cooling or heating equipment. Cooling and heating capacity are normally referred to in BTUs. The capacity of an air conditioner is measured by the amount of cooling it can do when running continuously. The total capacity is the sum of the latent capacity (ability to remove moisture from the air) and sensible capacity (ability to reduce the dry-bulb temperature). Each of these capacities is rated in Btus per hour (Btu/h). The capacity depends on the outside and inside conditions. As it gets hotter outside (or cooler inside) the capacity drops. The capacity at a standard set of conditions is often referred to as “tons of cooling.”
Carbon Dioxide (CO2)

A colorless, odorless, non-poisonous gas that is a normal part of the air. Carbon dioxide, also called CO2, is exhaled by humans and animals and is absorbed by green growing things and by the sea. A gas which can at high levels (above 1.5 % or 15,000 parts per million), have physiological effects. Main indoor source is human respiration; measurements used as indicators of ventilation conditions.
Carbon Monoxide (CO)

An colorless, odorless gas that is the product of incomplete fuel combustion or carbon burns without sufficient air nearby. It is a chemical asphyxiant; in the bloodstream it effectively prevents the transport of oxygen to the body’s tissues. CO exposure can affect the lungs, heart, and nervous system, and can cause death. Sources include cooling and heating appliances, tobacco smoke, and entrained exhaust from parking garages and truck idling areas. A gas, made up of carbon and oxygen molecules, produced by incomplete burning of carbon or carbonaceous materials, including carbon-based fuels. including coal, natural gas, gasoline, oil and wood. It is a major air pollutant on the basis of weight. Carbon monoxide is also produced from incomplete combustion of many natural and synthetic products. For instance, cigarette smoke contains carbon monoxide. When carbon monoxide gets into the body, the carbon monoxide combines with chemicals in the blood and prevents the blood from bringing oxygen to cells, tissues and organs. The body’s parts need oxygen for energy, so high-level exposures to carbon monoxide can cause serious health effects, with death possible from massive exposures. Symptoms of exposure to carbon monoxide can include vision problems, reduced alertness, and general reduction in mental and physical functions. Carbon monoxide exposures are especially harmful to people with heart, lung and circulatory system diseases.
Carboxyhemogoblin Saturation

Carbon monoxide poisoning.
Carcinogen

An agent suspected or known to cause cancer.
Ceiling Plenum

The space between the suspended and structural ceiling used as part of the air distribution system that accomodates the mechanical and electrical equipment. This space usually accommodates electrical, communications, and mechanical connections as well. The space is kept under negative pressure.
Celsius

A temperature scale based on the freezing (0 degrees) and boiling (100 degrees) points of water. Abbreviated as C in second and subsequent references in text. Formerly known as Centigrade. To convert Celsius to Fahrenheit, multiply the number by 9, divide by 5, and add 32. For example: 10 degrees Celsius x 9 = 90; 90 / 5 = 12; 18 + 32 = 50 degrees Fahrenheit.
Central Air Handling Unit (Central AHU)

This is the same as an Air Handling Unit, but serves more than one area.
Central Forced-Air Heating System

A piece of equipment that produces heat in a centralized area, then distributes it throughout the home through a duct system.
CFC (Chlorofluorocarbons or Chlorinated Fluorocarbons)

A class of refrigerants. Generally refers to the Chlorofluorocarbon family of refrigerants. Sometimes called Freon A family of artificially produced chemicals receiving much attention for their role in stratospheric ozone depletion. Since they were introduced in the mid-1930s, CFCs have been used as refrigerants, solvents and in the production of foam material. These chemicals and some related chemicals have been used in great quantities in industry, for refrigeration and air conditioning, and in consumer products. CFCs and their relatives, when released into the air, rise into the stratosphere, a layer of the atmosphere high above the Earth. In the stratosphere, CFCs and their relatives take part in chemical reactions which result in reduction of the stratospheric ozone layer, which protects the Earth’s surface from harmful effects of radiation from the sun. On a per molecule basis, these chemicals are several thousand times more effective as greenhouse gases than carbon dioxide. The 1987 Montreal protocol on CFCs seeks to reduce their production by one-half by the year 1998. The 1990 CLEAN AIR ACT includes provisions for reducing releases (emissions) and eliminating production and use of these ozone-destroying chemicals.
CFM (Cubic Feet per Minute)

A standard measurement of airflow that indicates how many cubic feet of air pass by a stationary point in one minute. The higher the number, the more air is being forced through the system. A typical system produces 400 CFM per ton of air conditioning.
Charge

Amount of refrigerant placed in a refrigerating unit.
Chemical Sensitization

Evidence suggests that some people may develop health problems characterized by effects such as dizziness, eye and throat irritation, chest tightness, and nasal congestion that appear whenever they are exposed to certain chemicals. People may react to even trace amounts of chemicals to which they have become “sensitized.”
Chiller

A device that produces chilled water to provide air conditioning for large buildings or cooling for process applications. A device that cools water, usually to between 40 and 50 degrees Fahrenheit for eventual use in cooling air.
Circuit

One complete run of a set of electric conductors from a power source to various electrical devices (appliances, lights, etc.) and back to the same power source.
Clean Air Act

The original Clean Air Act was passed in 1963, but the national air pollution control program is actually based on the 1970 version of the law. The 1990 Clean Air Act Amendments are the most far-reaching revisions of the 1970 law. The 1990 amendments are often referred to as as the 1990 Clean Air Act.
Clean Air Act Amendments of 1990

These ammendments represent a major overhaul of the earlier Clean Air Act of 1970. Changes include revised provisions for attainment and maintenance of National Ambient Air Quality Standards, mobile sources, hazardous air pollutants, and other assorted air quality issues. In addition, it establishes guidelines for reductions in air pollution. The Act also specifically limits sulfur dioxide and nitrogen oxide emissions of power plants.
Cogeneration

Simultaneous production of two or more forms of useable energy from a single fuel source, e.g., heat energy and electrical or mechanical power, in the same facility. Because a typical cogeneration facility uses thermal energy which is generally vented in a traditional power plant, the process can be 50 to 70 percent more efficient. Fuels used in cogeneration facilities may take the form of natural gas, biomass, oil or coal. Most cogeneration systems are designed to simultaneously produce electric power (to be used on site or sold back to an investor-owned utility or both) and thermal heat for industrial processes or the heating and cooling of buildings. Cogeneration projects can be any size, from 10 kilowatts to 1,000 megawatts or more.
Coil

A cooling or heating element, often including fins, through which treated gas or liquid is passed, exchanging thermal energy with air surrounding it for heating or cooling.
Colony Forming Unit (CFU)

A laboratory measure of fungal concentration, indicating the quantity of viable organisms collected for a given unit sample.
Comfort Conditioning

The process of treating air to simultaneously control its temperature, humidity, cleanliness, and distribution to meet the comfort requirements of the occupants of the conditioned space.
Comfort Zone

The range of temperatures, humidities and air velocities at which the greatest percentage of people feel comfortable. The range of temperatures over which the majority of persons feel comfortable (neither too hot nor too cold).
Commercial

The commercial sector is generally defined as nonmanufacturing business establishments, including hotels, motels, restaurants, wholesale businesses, retail stores, and health, social, and educational institutions. The utility may classify commercial service as all consumers whose demand or annual use exceeds some specified limit. The limit may be set by the utility based on the rate schedule of the utility.
Commissioning

The testing of HVAC systems prior to building occupancy to check whether the systems meet the operational needs of the building within the capabilities of the system design. Start-up of a building that includes testing and adjusting HVAC, electrical, plumbing, and other systems to assure proper functioning and adherence to design criteria. Commissioning also includes the instruction of building representatives in the use of the building systems.
Compressor

The heart of an air conditioning or heat pump system. The large (usually black) part in the condenser (outdoor unit) that pumps refrigerant. The pump of a refrigerating mechanism which draws a low pressure on cooling side of refrigerant cycle and squeezes or compresses the gas into the high pressure or condensing side of the cycle. The compressor maintains adequate pressure to cause refrigerant to flow in sufficient quantities to meet the cooling requirements of the system.
Condenser

This is the unit that will sit outside and is part of a split system, it contains the compressor which is the heart of your air conditioner or Heat Pump, it pumps the refrigerant through your system. Some people call the condenser the compressor, but the compressor is a component of the condenser along with the fan motor and condenser coil. Coil or outdoor coil dissipates heat from the refrigerant, changing the refrigerant from vapor to liquid.
Condenser Approach Temperature

The temperature difference between the condenser’s refrigerant temperature and the leaving condenser water temperature. An ideal indicator of fouling of condenser tubes, which can significantly degrade chiller efficiency.
Condenser Coil

[Also see Outdoor Coil] The outdoor portion of a heating or cooling system that either releases or collects heat from the outside air, depending on the time of year. The Condenser Coil is connected directly to the home’s Air Handler and is also known as the Outdoor Coil.
Condensing Unit

Part of a refrigerating mechanism which pumps vaporized refrigerant from the evaporator, compresses it, liquefies it in the condenser and returns it to the refrigerant control. The outdoor portion of a split system air conditioner contains the compressor and outdoor coil ignoring the reverse cycle operation, also the outdoor in a heat pump system.
Conditioned Air

The air that has been heated, cooled, humidified, or dehumidified to maintain an interior space within the “comfort zone.”
Conditioned Floor Area

The floor area of enclosed conditioned spaces on all floors measured from the interior surfaces of exterior partitions for nonresidential buildings and from the exterior surfaces of exterior partitions for residential buildings.
Conditioned Space

Enclosed space that is either directly conditioned space or indirectly conditioned space.
Conditioned Space, Directly

An enclosed space that is provided with heating equipment that has a capacity exceeding 10 Btus/(hr-ft2), or with cooling equipment that has a capacity exceeding 10 Btus/(hr-ft2). An exception is if the heating and cooling equipment is designed and thermostatically controlled to maintain a process environment temperature less than 65 degrees Fahrenheit or greater than 85 degrees Fahrenheit for the whole space the equipment serves.
Conditioned Space, Indirectly

Enclosed space that: (1) has a greater area weighted heat transfer coefficient (u-value) between it and directly conditioned spaces than between it and the outdoors or unconditioned space; (2) has air transferred from directly conditioned space moving through it at a rate exceeding three air changes per hour.
Conductance

The quantity of heat, in Btu’s, that will flow through one square foot of material in one hour, when there is a 1 degree F temperature difference between both surfaces. Conductance can be expressed in other units as well. Conductance values are given for a specific thickness of material, not per inch thickness.
Conduction

The transfer of heat through a solid material. The transfer of heat energy through a material (solid, liquid or gas) by the motion of adjacent atoms and molecules without gross displacement of the particles.
Configuration

This describes the direction in which a furnace outputs heat. A furnace may have an upflow, downflow or crossflow (horizontal) configuration.
Constant Air Volume Systems

Air handling system that provides a constant air flow while varying the temperature to meet heating and cooling needs.
Contactor

In the condenser, the main switch that turns the condenser on.
Contaminant

An unwanted constituent that may or may not be associated with adverse health or comfort effects.
Convection

The movement of heat by air flow.
Cooling Capacity

The maximum rate at which cooling equipment removes heat from airflow at operating conditions.
Cooling Capacity, Latent

Available refrigerating capacity of an air conditioning unit for removing latent heat from the space to be conditioned.
Cooling Capacity, Sensible

Available refrigerating capacity of an air conditioning unit for removing sensible heat from the space to be conditioned.
Cooling Capacity, Total

Available refrigerating capacity of an air conditioner for removing sensible heat and latent heat from the space to be conditioned.
Cooling Degree Day

A unit of measure that indicates how heavy the air conditioning needs are under certain weather conditions.
Cooling Load

The rate at which heat must be extracted from a space in order to maintain the desired temperature within the space.
Cooling Load Temperature Difference (CLTD)

A value used in cooling load calculations for the effective temperature difference (delta T) across a wall or ceiling, which accounts for the effect of radiant heat as well as the temperature difference.
Cooling System

A system of air-to-air, liquid-to-air, liquid-to-liquid, etc., heat exchangers, ducts and/or pipes, etc., for removing head from a system contianing heat sources, such as power plants, automobile engines, and homes. Also, an energy Efficiency program promotion aimed at improving the efficiency of the cooling delivery system, including replacement, in the residential, commercial, or industrial sectors.
Cooling tower

A heat transfer device, which cools warm water using outside air.
COP (Coefficient Of Performance)

COP compares the heating capacity of a heat pump to the amount of electricity required to operate the heat pump in the heating mode. COPs vary with the outside temperature: as the temperature falls, the COP falls also, since the heat pump is less efficient at lower temperatures. ARI standards compare equipment at two temperatures, 47 F and 17 F, to give you an idea of the COP in both mild and colder temperatures. Geothermal equipment is compared at 32 F enter water temperature. COP & HSPF can not be compared equally. Air Source Equipment is rated by HSPF or COP and Geothermal equipment is rated by COP.
Current (Electric)

A flow of electrons in an electrical conductor. The strength or rate of movement of the electricity is measured, e.g., in amperes.
Damper

A device that is located in ductwork to adjust air flow. This movable plate opens and closes to control airflow. Dampers are used effectively in zoning to regulate airflow to certain rooms. There are basically two types of dampers: Manual and motorized. A manual damper generally consists of a sheet metal (or similar material) flap, shaped to fit the inside of a round or rectangular duct. By rotating a handle located outside of the duct a technician can adjust (see Balancing) air flow to match the needs of a particular area or room. A motorized damper is generally used in a zoned system (see Zoning) to automatically deliver conditioned air to specific rooms or zones. In particular, the following types, can be distinguished:

Multiple leaf dampers, comprising of a number of blades (or shutters) of opposed or parallel leaf type.
Single leaf dampers (the flap being mounted at one end), commonly called splitter dampers.
Hit-and-miss dampers, having two or more slotted slide mechanism.
Butterfly dampers, with two flaps in “V” arrangement.

Dampers

Controls that vary airflow through an air outlet, inlet, or duct. A damper position may be immovable, manually adjustable or part of an automated control system.
db (Decibel)

A decibel describes the relative loudness of a sound. Some common sounds are fairly close to a typical air conditioner or heat pump’s sound level: human voice, 7.0 decibels; blender, 8.8 decibels.
DDC (Direct Digital Control)

Direct Digital Control
Defrost Cycle

The process of removing ice or frost buildup from the outdoor coil during the heating season.
Degree Day

A unit, based upon temperature difference and time, used in estimating fuel consumption and specifying nominal annual heating load of a building. When the mean temperature is less than 65 degrees Fahrenheit the heating degree days are equal to the total number of hours that temperature is less than 65 degrees Fahrenheit for an entire year.
Dehumidification

The reduction of water vapor in air by cooling the air below the dew point; removal of water vapor from air by chemical means, refrigeration, etc.
Delta (or Delta T)

A difference in temperature. Often used in the context of the difference between the design indoor temperature and the outdoor temperature.
Demand Billing

The electric capacity requirement for which a large user pays. It may be based on the customer’s peak demand during the contract year, on a previous maximum or on an agreed minimum. Measured in kilowatts.
Demand Charge

The sum to be paid by a large electricity consumer for its peak usage level.
Demand (Utility)

The rate at which electricity or natural gas is delivered to or by a system,, part of a system, or piece of equipment, e.g., to end users, at a given instant or averaged over any designated period of time. Electricity demand is typically expressed in kilowatts.
Design Conditions

Cooling loads vary with inside and outside conditions. A set of conditions specific to the local climate are necessary to calculate the expected cooling load for a home. Inside conditions of 75 degrees Fahrenheit and 50% relative humidity are usually recommended as a guideline. Outside conditions are selected for the 2.5% design point.
Dewpoint

Is the temperature at which air becomes saturated with water and begins to condense – forming a dew. Therefore at 100 % RH the ambient or process temperature equals the dewpoint temperature. The more negative the dewpoint temperature is from the ambient temperature the less the risk of condensation and the drier the gas or air stream.
Diffusers and Grilles

Components of the ventilation system that distribute and return air to promote air circulation in the occupied space. Generally speaking, supply air enters a space through a diffuser or vent and return air leaves a space through a grille.
Dilution

A mitigation strategy that lowers the concentration of airborne contaminants by increasing the fraction of outdoor air in the supply airstream.
Direct Current (DC)

Electricity that flows continuously in the same direction.
Direct Expansion (Refrigeration)

Any system that, in operation between an environment where heat is absorbed (heat source), and an environment into which unwanted heat is directed (heat sink) at two different temperatures, is able to absorb heat from the heat source at the lower temperature and reject heat to the heat sink at the higher temperature. The cooling effect is obtained directly from a fluid called a refrigerant that absorbs heat at a low temperature and pressure, and transfers heat at a higher temperature and higher pressure.
Direct Gas-Fired Heater

The burner fires directly in the air stream being heated, rather than through a heat exchanger. 100% of available BTUs are delivered to the heated space because no flue or heat exchanger is required. This results in no wasted energy.
DOE (Department of Energy)

The Department of Energy is a federal agency in charge of setting industry efficiency standards and monitoring the consumption of energy sources.
Double Glazing

Windows having two sheets of glass with an airspace between.
Downflow

A type of furnace that takes cool air from the top and blows warm air to the bottom – common where your furnace must be located in a second-floor closet or utility area.
Downflow Furnace

A furnace that pulls in cool return air from the top and blows/expels warm air at the bottom – common where your furnace must be located in a second-floor closet or utility area.
Drain Trap

A dip in the drain pipe of sinks, toilets, floor drains, etc., which is designed to stay filled with water, thereby preventing sewer gases from escaping into the room.
Drier

Sometimes called filter/drier, it removes moisture and keeps the refrigerant clean.
Dry Bulb Temperature (DB)

The temperature measured by a standard thermometer. A measure of the sensible temperature of air.
Dual Fuel System

A dual heating system, for example a heat pump and a fossil fuel furnace.
Dual-Duct System

A central plant heating , ventilation and air conditioning (HVAC ) system that produces conditioned air at two temperatures and humidity levels. The air is then supplied through two independent duct systems to the points of usage where mixing occurs.
Dual-Paned (Double-glazed)

Two panes of glass or other transparent material, separated by a space.
Duct

A pipe or closed conduit made of sheet metal, fiberglass board, or other suitable material used for conducting air to and from an air handling unit. A passageway made of sheet metal or other suitable material used for conveying air or other gas at relatively low pressures.
Duct tape

This (initially) sticky tape is unfortunately the most common material used to seal duct connections. Care must be taken when it’s applied. For effective sealing, the surface it is applied to must be clean–free of dust, dirt, oil, or other substances. Duct tape has a tendency to lose adhesion with age, especially when used on ducts in unconditioned spaces.
Ductwork

A pipe or closed conduit made of sheet metal, fiberglass board, or other suitable material used for conducting air to and from an air handling unit. Hollow pipes or channels that carry/transfer air from the Air Handler to the air vents throughout your home. The delivery system through which warm air from the furnace is brought to where it’s needed. Ductwork is made of sheet metal, fiberglass, or flexible plastic, and can be round or rectangular in shape. Ductwork is one of the most important components of a home heating and cooling system.
Dust

Dust is comprised of particles in the air that settle on surfaces. Large particles settle quickly and can be trapped by the body’s defense mechanisms. Small particles are more likely to be airborne and are capable of passing through the body’s defenses and entering the lungs.
Economizer, Air

A ducting arrangement and automatic control system that allows a heating, ventilation and air conditioning (HVAC) system to supply up to 100 percent outside air to satisfy cooling demands, even if additional mechanical cooling is required.
Economizer, Water

A system which uses either direct evaporative cooling, or a secondary evaporatively cooled water loop and cooling coil to satisfy cooling loads, even if additional mechanical cooling is required.
EER – (Energy Efficiency Ratio)

A ratio calculated by dividing the cooling capacity in Btu’s per hour (Btuh) by the power input in watts at any given set of rating conditions, expressed in Btuh per watt (Btuh/watt). EER & SEER can not be compared equally. Air source equipment is rated by SEER and geothermal equipment is rated by EER. EER changes with the inside and outside conditions, falling as the temperature difference between inside and outside gets larger.
Effective area (of an air terminal device)

The smallest net area of an air terminal device used by the air stream in passing through the air terminal device.
Efficiency

A rating on comfort equipment is similar to the miles per gallon rating on your car. The higher the rating number, the more efficient the system and the lower your fuel consumption will be. You can save a lot of money with a high efficiency unit. Depending on your local climate, lifestyle and electricity rates, savings will vary. For furnaces. it is the rate at which a furnace maximizes fuel use. This rate is numerically described as a ratio called AFUE (see AFUE). As of January, 1991, no furnaces can be manufactured with efficiencies lower than 78% afue. High efficiency furnaces will be rated 85 to 95% afue.
Electric Radiant Heating

A heating system in which electric resistance is used to produce heat which radiates to nearby surfaces. There is no fan component to a radiant heating system.
Electric Rate Schedule

A statement of the electric rate and the terms and conditions governing its application, including attendant contract terms and conditions that have been accepted by a regulatory body with appropriate oversight authority.
Electric Resistance Heater

A device that produces heat through electric resistance. For example, an electric current is run through a wire coil with a relatively high electric resistance, thereby converting the electric energy into heat which can be transferred to the space by fans.
Electrostatic air cleaner

A device that uses an electrical charge to trap particles traveling in the air stream.
Emergency Heat (Supplementary Electric Heat)

The back up electric heat built into a heat pump system. The same as an auxiliary heater, except it is used exclusively as the heat source when the heat pump needs repair.
Emission Standard

A voluntary guideline or government regulation that specifies the maximum rate at which a contaminant can be released from a source.
Encapsulate

A mitigation technique that reduces or eliminates emissions from a source by sealing with an impenetrable barrier.
Endotoxin

A biological agent that is part of the outer membrane of some bacteria. Endotoxins are highly toxic, capable of causing fever, malaise, respiratory distress, even death.
Energy

Broadly defined, is the capability of doing work. More specifically, it is the capacity for doing work as measured by the capability of doing work (potential energy) or the conversion of this capability to motion (kinetic energy). Forms of energy include: thermal, mechanical, electrical and chemical. Energy may be transformed from one form into another form useful for work. Most of the world¹s convertible energy comes from fossil fuels that are burned to produce heat that is then used as a transfer medium to mechanical or other means in order to accomplish tasks. Electrical energy is usually measured in kilowatt-hours, while heat energy may be measured in British thermal units or other traditional non-metric speciallized units in addition to metric units. In the electric power industry, energy is more narrowly defined as electricity supplied over time, expressed in kilowatts.
Energy Efficiency

Refers to programs that are aimed at reducing the energy used by specific end-use devices and systems, typically without affecting the services provided. These programs reduce overall electricity consumption (reported in megawatthours), often without explicit consideration for the timing of program-induced savings. Such savings are generally achieved by substituting technically more advanced equipment to produce the same level of end-use services (e.g. lighting, heating, motor drive) with less electricity. Examples include high-efficiency appliances, efficient lighting programs, high-efficiency heating, ventilating and air conditioning (HVAC) systems or control modifications, efficient building design, advanced electric motor drives, and heat recovery systems.
Energy Management System

A control system (often computerized) designed to regulate the energy consumption of a building by controlling the operation of energy consuming systems, such as the heating, ventilation and air conditioning (HVAC), lighting and water heating systems.
Enforcement

The legal methods used to make polluters obey the CLEAN AIR ACT. Enforcement methods include citations of polluters for violations of the law (citations are much like traffic tickets), fines and even jail terms. EPA and the state and local governments are responsible for enforcement of the Clean Air Act, but if they don’t enforce the law, members of the public can sue EPA or the states to get action. Citizens can also sue violating sources, apart from any action EPA or state or local governments have taken. Before the 1990 Clean Air Act, all enforcement actions had to be handled through the courts. The 1990 Clean Air Act gave EPA authority so that, in some cases, EPA can fine violators without going to court first. The purpose of this new authority is to speed up violating sources’ compliance with the law and reduce court time and cost.
Enthalpy

The quantity of heat necessary to raise the temperature of a substance from one point to a higher temperature. The quantity of heat includes both latent and sensible.
Envelope

The geometrical surface of the points of an air jet, corresponding to a determined value of the measured air velocity. This velocity is generally called «terminal velocity». Also, the air barrier that separates the conditioned space from the outside and from unconditioned spaces like attics and garages.
Environmental Agents

Conditions other than indoor air contaminants that cause stress, comfort, and/or health problems (e.g., humidity extremes, drafts, lack of air circulation, noise, and over-crowding).
Environmental Tobacco Smoke (ETS)

The combination of sidestream and mainstream smoke that is emitted from a burning cigarette; also called second-hand smoke.
Environmental Tobacco Smoke (ETS)

Mixture of smoke from the burning end of a cigarette, pipe, or cigar and smoke exhaled by the smoker.
EPA (Environmental Protection Agency)

Environmental Protection Agency – http://www.epa.gov/ A federal agency created in 1970 to permit coordinated governmental action for protection of the environment by systematic abatement and control of pollution through integration of research, monitoring, standards setting and enforcement activities. EPA administers federal environmental policies, enforces environmental laws and regulations, performs research, and provides information on environmental subjects. The agency also acts as chief advisor to the President on U.S. environmental policy and issues.
Epidemiological

Dealing with the scientific study of the incidence, control, and spread of disease in a population.
Ergonomics

The science that investigates the impact of people’s physical environment on their health and comfort (e.g., chair design, monitor location, desk configuration or height, etc.)
ERV (Energy Recovery Ventilator)

This device preheats incoming outside air during the winter and pre-cools incoming air during the summer to reduce the impact of heating and or cooling the indoor air. This means that smaller capacity heating and cooling systems can be used in homes, which results in lower installation costs, lower peak demand for energy, and lower operating costs.
Evaporative Cooler

A type of cooling equipment that turns air into moist, cool air by saturating the air with water vapor. It does not cool air by use of a refrigeration unit. This type of equipment is commonly used in warm, dry climates.
Evaporative Cooling

Cooling by exchange of latent heat from water sprays, jets of water, or wetted material.
Evaporator Approach Temperature

The temperature difference between the evaporator¹s refrigerant temperature and the leaving chilled water temperature.
Evaporator Coil

[Also see Indoor Coil] The evaporator coil is located inside your house in a split system in the airhandler, or above the gas furnace. This will produce cooling in the air conditioning mode and heating in a Heat Pump mode. This coil section in the evaporator is where refrigerant evaporates and absorbs heat from air passed over the coil.This is also very important in removing humidity from your home.
Exfiltration

Uncontrolled air leakage out of a building.
Exfiltration

Air flow outward through a wall, building envelope, etc.
Exhaust

Air removed deliberately from a space, by a fan or other means, usually to remove contaminants from a location near their source. The air flow leaving the treated space. Exhaust may be accomplished by one or more of the following methods:

a. Extraction: exhaust in such a manner that the air is discharged into the atmosphere.
b. Relief: exhaust in such a manner that the air is allowed to escape from the treated space if the pressure in that space rises above a specified level.
c. Recirculation: exhaust in which the air is returned to the air treatment system.
d. Transfer: exhaust in which air passes from the treated space to another treated space.

Exhaust Air Flow Rate

Volume of air leaving an exhaust air terminal device within a time unit.
Exhaust Air Terminal Device

Air terminaI device through which air leaves the treated space.
Exhaust Ventilation

Mechanical removal of air from a portion of a building (e.g., piece of equipment, room, or general area).
Fahrenheit (F)

A temperature scale in which the boiling point of water is 212 degrees and its freezing point is 32 degrees. To convert Fahrenheit to Celsius, subtract 32, multiply by 5, and divide the product by 9. For example: 100 degrees Fahrenheit – 32 = 68; 68 x 5 = 340; 340 / 9 = 37.77 degrees Celsius.
Fan Coil

An indoor component of a heat pump system used in place of a furnace, to provide additional heating on cold days when the heat pump does not provide adequate heating. A component of a heating, ventilation and air conditioning (HVAC) system containing a fan and heating or cooling coil, used to distribute heated or cooled air.
FAQ (Frequently Asked Questions)

Used to mean a list of frequently asked questions.
Filter

A device for removing dust particles from air or unwanted elements from liquids.
Fire Valves (or Fire Dampers)

Components which are installed in an air distribution system between two fire separating compartments and are designed to prevent propagation of fire and/or smoke. Generally are kept open by mechanical restraint, whose effect is canceled under specific conditions. The valve is then closed automatically.
Flame roll-out

A dangerous situation that occurs when flame is pushed out of the bottom of a combustion appliance. It can lead to fires.
Flex duct

Usually installed in a single, continuous piece between the register and plenum box, a flexible duct usually has an inner lining and an insulated coating on the outside.
Flow Hood

A diagnostic tool used to measure air flow through ducts, supply registers, and return grilles. Device that easily measures airflow quantity, typically up to 2,500 cfm.
Follow-Up Testing

The testing designed to confirm the results of the initial testing using identical testing devices and similar test conditions.
Forced Air

This describes a type of heating system that uses a blower motor to move air through the furnace and into the ductwork. Heating and or cooling system that connects to the conditioned space with duct-work that uses air as the moving fluid. The heating or cooling can come from any number of sources.
Forced Air Unit (FAU)

A central furnace equipped with a fan or blower that provides the primary means for circulation of air.
Formaldehyde

Formaldehyde is a colorless water-soluble gas. Due to its wide use, it is frequently considered separately from other volatile organic compounds (VOCs)
Frequency

The number of cycles which an alternating current moves through in each second. Standard electric utility frequency in the United States is 60 cycles per second, or 60 Hertz.
Fungi

A large group of organisms including molds, mildews, yeasts, mushrooms, rusts, and smuts. Any of a group of parasitic lower plants that lack chlorophyll. Most fungi produce spores, which are broadcast through the air so that virtually all environmental surfaces will have some fungal material. Most health effects are associated with allergic responses to antigenic material or toxic effects from mycotoxins. Fungi also generate certain volatile organic compounds.
Fungicide

Substance or chemical that kills fungi.
Furnace

That part of an environmental system which converts gas, oil, electricity or other fuel into heat for distribution within a structure.
Furnace, Horizontal

A furnace that lies on its side, pulling in return air from one side and expelling warm air from the other.
Gas Sorption

Devices used to reduce levels of airborne gaseous compounds by passing the air through materials that extract the gases.
Geothermal Energy

Natural heat from within the earth, captured for production of electric power, space heating or industrial steam.
Geothermal Equipment

Heat pumps that uses the ground to transfer heat to and from the refrigerant in the unit. The unit circulates water through a heat exchanger in the to a closed loop buried in the ground or by pumping water from a well through the unit.
Geothermal Gradient

The change in the earth’s temperature with depth. As one goes deeper, the earth becomes hotter.
Global Climate Change

Gradual changing of global climates due to buildup of carbon dioxide and other greenhouse gases in the earth’s atmosphere. Carbon dioxide produced by burning fossil fuels has reached levels greater than what can be absorbed by green plants and the seas.
Greenhouse Effect

The presence of trace atmospheric gases make the earth warmer than would direct sunlight alone. These gases (carbon dioxide [CO2], methane [CH4], nitrous oxide [N2O], tropospheric ozone [O3], water vapor [H2O], and chlorofluorocarbons) allow visible light and ultraviolet light (shortwave radiation) to pass through the atmosphere and heat the earth’s surface. This heat is re-radiated from the earth in form of infrared energy (longwave radiation). The greenhouse gases absorb part of that energy before it escapes into space. Thus the greenhouse effect allows solar radiation to penetrate but absorbs the infrared radiation returning to space. This process of trapping the longwave radiation specifically is known as the greenhouse effect. Scientists estimate that without the greenhouse effect, the earth’s surface would be roughly 54 degrees Fahrenheit colder than it is today — too cold to support life as we know it. See GLOBAL CLIMATE CHANGE.
Greenhouse Effect (Relating to Buildings)

The characteristic tendency of some transparent materials (such as glass) to transmit radiation with relatively short wavelengths (such as sunlight) and block radiation of longer wavelengths (such as heat). This tendency leads to a heat build-up within the space enclosed by such a material.
Grille

An air terminal device with multiple passages for the air.
Grilles

Coverings for the ducts where they open to the conditioned space. (Same as Registers)
Half-Life

The amount of time it takes for half of the existing amount of a radioactive element to decay to non-radioactive products.
HCFC (Hydrochlorofluorocarbon)

A class of refrigerants. Generally refers to Halogenated Chlorofluorocarbon family of refrigerants.
Heat Balance

The outdoor temperature at which a building’s internal heat gain (from people, lights and machines) is equal to the heat loss through windows, roof and walls.
Heat Capacity

The amount of heat necessary to raise the temperature of a given mass one degree. Heat capacity may be calculated by multiplying the mass by the specific heat.
Heat Engine

An engine that converts heat to mechanical energy.
Heat Exchanger

This is a device that enables furnaces to transfer heat from combustion safely into breathable air. The primary heat exchanger transfers heat from combustion gases to the air blowing through the ductwork. It’s vital that none of the combustion gas itself gets into the airstream. The primary heat exchanger handles the hottest gases. This device transfers heat from outgoing stale air to incoming cold air. In warm climates, this process can be reversed. In high efficiency furnaces, secondary heat exchangers recover heat that used to be vented up the chimney with the exhaust gases. By recovering this heat, the furnace becomes more efficient. Part of the heat recovered here causes the water and acid to condense out of the exhaust gas. Because this liquid is corrosive, secondary heat exchangers must be designed to prevent deterioration. Usually this means they are made of stainless steel or some derivative of it.
Heat Gain

The amount of heat gained, measured in BTU’s, from a space to be conditioned, at the local summer outdoor design temperature and a specified indoor design condition. An increase in the amount of heat contained in a space, resulting from direct solar radiation, heat flow through walls, windows, and other building surfaces, and the heat given off by people, lights, equipment, and other sources.
Heat Loss

The amount of heat lost, measured in BTU’s from a space to be conditioned, at the local winter outdoor design temperature and a specified indoor design condition. A decrease in the amount of heat contained in a space, resulting from heat flow through walls, windows, roof and other building surfaces and from exfiltration of warm air.
Heat Pump

A heating and air conditioning unit that heats or cools by moving heat. A Heat Pump is a reverse cycle air conditioner. The Heat Pump uses a compression cycle system to supply heat or remove heat remove a temperature controlled space. An air-conditioning unit which is capable of heating by refrigeration, transferring heat from one (often cooler) medium to another (often warmer) medium, and which may or may not include a capability for cooling. This reverse-cycle air conditioner usually provides cooling in summer and heating in winter. When you run your air conditioner, your outdoor unit will be blowing hot air, (in other words, removing the heat from your home and sending it outside). When you run your heat pump, you reverse the flow of refrigerant and remove the heat from the atmosphere outside and blow it inside. When the temperature dips below 40 degrees outside, the Heat Pump labors in producing heat so they install a back up or auxiliary electric heat strip to supplement the Heat Pump. Electric Heat strips are very expensive to operate. In southern climates where it rarely dips below 40 degrees the heat pump is very efficient. A 3 to 1 savings in heating compared to electric heat strips.
Heat Pump Cooling Mode

In the cooling cycle of a Heat Pump , you are removing hot air from inside the house and sending it outside. You can feel the hot air outside, over the condenser fan motor.
Heat Pump Heating Mode

In the heating mode of a Heat Pump the refrigerant cycle is reversed and you are now removing the heat from the outside and sending it inside the house. You can feel the cool air outside, over the condenser fan motor. When temperatures go below 40 degrees Heat Pumps labor in producing heat and must use back up electric heat strips. Heat strips cost 3 times as much to operate as a Heat Pump when producing heat.
Heat Rate

A number that tells how efficient a fuel-burning power plant is. The heat rate equals the Btu content of the fuel input divided by the kilowatt-hours of power output.
Heat Source

A body of air or liquid from which heat is collected. In an air source heat pump, the air outside the house is used as the heat source during the heating cycle.
Heat Transfer

Flow of heat energy induced by a temperature difference. Heat flow through a building envelope typically flows from a heated, or hot area to a cooled, or cold area.
Heating Degree Day

A unit that measure the space heating needs during a given period of time.
Heating Load

The rate at which heat must be added to a space in order to maintain the desired temperature within the space.
Heating System

Energy Efficiency program promotion aimed at improving the efficiency of the heating delivery system, including replacement, in the residential, commercial, or industrial sectors.
Hertz

A unit of electromagnetic wave frequency that is equal to one cycle per second. — It is named after Henrich R. Hertz.
HFC (Hydrofluorocarbon)

A class of refrigerants. Generally refers to Hydrofluorocarbon family of refrigerants
High-Efficiency Particulate Air (HEPA) Filter

A specialized filter capable of removing 99.97% of particulates 0.3 µ in diameter. High efficiency particulate arrestance (filters).
Home Energy Assistance Program (HEAP)

A centrally operated direct payment program that assists eligible households in offsetting the cost of heating and cooling their homes. Payments are generally made in the form of dual party warrants (checks) made payable to the applicant and their designated utility company. For example, the program is administered in California by the California Department of Economic Opportunity using federal and state funds.
Horsepower (HP)

A unit for measuring the rate of doing work. One horsepower equals about three-fourths of a kilowatt (745.7 watts).
House Dust Mite

A common microscopic household arachnid, which feeds on shed skin scales, and so tends to concentrate around mattresses and furniture. Antigens present in the mite’s excreta are implicated in cases of allergic asthma and allergic rhinitis.
HRV (Heat Recovery Ventilator)

This device bring fresh, outside air into a home while simultaneously exhausting stale indoor air outside. In the process of doing this, an HRV removes heat from the exhaust air and transfer it to the incoming air, pre-heating it. This allows for the reclamation of much of the energy that otherwise would simply be vented outside. The end result: home comfort systems operate more efficiently.
HSPF (Heating Seasonal Performance Factor)

Indicates how efficiently a Heat Pump is working. A higher number means the unit works more efficiently. Heating Seasonal Performance Factor is similar to SEER, but it measures the efficiency of the heating portion of your heat pump. Like SEER, industry minimums have been raised recently, and the minimum is now 6.80 HSPF. Most new units have ratings from 7.0 to 9.4. A representation of the total heating output of a central air-conditioning heat pump in Btus during its normal usage period for heating, divided byu the total electrical energy input in watt-hours during the same period, as determined using the specified test procedures. Efficiency is derived according to federal test methods by using the total Btus during its normal usage period for heating divided by the total electrical energy input in watt-hours during the same period. The total heating output of a heat pump during its normal annual usage period for heating divided by the total electric power input in watt-hours during the same period. COP & HSPF can not be compared equally. Air Source equipment is rated by HSPF or COP and Geothermal equipment is rated by COP. ARI standards compares air source equipment at two temperatures, 47 F and 17 F. Geothermal equipment is compared at 32 F enter water temperature.
Humidifier

A device that adds moisture to warm air being circulated or directed into a space. This adds necessary moisture to protect your furnishings and reduce static electricity.
Humidistat

A device designed to regulate humidity input by reacting to changes in the moisture content of the air. Much like a thermostat but turns the system on & off by sensing the humidity level.
Humidity

The amount of moisture in the air. Air conditioners remove moisture for added comfort.
HVAC (Heating, Ventilating and Air Conditioning)

Heating, Ventilating and Air Conditioning
HVAC/R (Heating, Ventilating, Air Conditioning, & Refrigeration)

Heating, Ventilating, Air Conditioning, & Refrigeration
Hydronic Heating

A system that heats a space using hot water which may be circulated through a convection or fan coil system or through a radiant baseboard or floor system.
IAQ Backgrounder

A component of the IAQ Tools for Schools Action Packet that provides a general introduction to IAQ issues in educational facilities.
IAQ Coordinator

An individual (usually with facility management) who provides leadership and coordination of all IAQ activities.
IAQ (Indoor Air Quality)

Indoor Air Quality – characteristics of the indoor climate of a building, including the gaseous composition, temperature, relative humidity, and airborne contaminant levels.
IAQ Management Plan

A set of flexible and specific steps for preventing and resolving IAQ problems in any kind of commercial facility.
Indicator Compounds

Chemical compounds, such as carbon dioxide, whose presence at certain concentrations may be used to estimate certain building conditions (e.g., airflow, presence of sources).
Indoor Air Pollutant

Particles and dust, fibers, mists, bioaerosols, and gases or vapors.
Indoor Coils

[Also see Evaporator Coil] Refrigerant containing portion of a fan coil unit similar to a car radiator, typically made of several rows of copper tubing with aluminum fins. A homes comfort system consist of two components: the outdoor unit (air conditioner or heat pump) and the indoor unit (coil or blower coil). Combinations of various units will result in vastly different efficiency ratings. Unreasonably high efficiency ratings can be created by using unrealistic indoor and out door equipment combinations. The term “most popular coil” indicates the actual tested combinations; other ratings may be simulated and unrealistic. Be sure that the efficiency ratings you are comparing are for “most popular coil.” You’ll know the ratings are attainable and close to reality.
Indoor Unit

This is usually located inside the house and contains the indoor coil, fan, motor, and filtering device, sometimes called the air handler.
Induction

Process by which the primary air sets into motion an air volume, called secondary air, in the room.
Induction ratio (i)

Ratio of the total air flow rate to the primary air flow rate.
Industrial

The industrial sector is generally defined as manufacturing, construction, mining, agriculture, fishing, and forestry establishments (Standard Industrial Classification [SIC] codes 01-39). The utility may classify industrial service using the SIC codes, or based on demand or annual usage exceeding some specified limit. The limit may be set by the utility based on the rate schedule of the utility.
Infiltration

Air movement into an enclosed space through cracks and openings. Unintentional movement of outdoor air into a house. Air flow inward into a space through walls, leaks around doors and windows or through the building materials used in the structure. It results from the forces of wind, temperature difference, and HVAC operation.
ISO 9000

A family of international standards for quality management and assurance by the ISO (International Standards Organization).
IWC (Inches of water column)

Commonly used in the USA
Joule

A unit of work or energy. It takes ~ 1,000 joules to equal a British thermal unit. It typically takes ~ 1 million joules to make a pot of coffee.
KBTU (kBtu)

One-thousand (1,000) Btus.
Kilovolt (kv)

One-thousand volts (1,000). Distribution lines in residential areas usually are 12 kv (12,000 volts).
kW (kilowatt or kW)

A kilowatt equals one thousand (1,000) watts. A unit of measure of the amount of electric power production needed to operate given equipment. On a hot summer afternoon a typical home, with central air conditioning and other equipment in use, might have a demand of four kW. An electric power capacity of one kW is sufficient to power ten 100-watt light bulbs.
kWh (kilowatt hour or kWh)

A kilowatt hour (kWh) is the amount of kilowatts of electricity used in one hour of operation of any equipment. The most commonly-used unit of measure telling the amount of electricity consumed over time. It means one kilowatt of electricity supplied for one hour. In 1989, a typical California household consumes 534 kWh in an average month. A typical electric consumer in Pennsylvania currently uses 500 kWh per month of electricity.)
Latent Cooling Load (or Latent Load)

The cooling load caused by moisture in the air. The net amount of moisture added to the inside air by plants, people, cooking, infiltration, and any other moisture source. The amount of moisture in the air can be calculated from a combination of dry-bulb and wet-bulb temperature measurements.
Latent Heat

Heat, that when added or removed, causes a change in state – but no change in temperature. A change in the heat content that occurs without a corresponding change in temperature, usually accompanied by a change of state (as from liquid to vapor during evaporation).
Life Extension

A term used to describe capital expenses which reduce operating and maintenance costs associated with continued operation of electric utility boilers and other equipment. Such boilers usually have a 40 year operating life under normal circumstances.
Life-Cycle Cost

Amount of money necessary to own, operate and maintain a building, system, plant, piece of equipment, etc., over its useful life.
Load

The amount of electric power supplied to meet one or more end user’s needs. The amount of electric power delivered or required at any specific point or points on a system. The requirement originates at the energy consuming equipment of the consumers.
Load Building

Refers to programs that are aimed at increasing the usage of existing electric equipment or the addition of electric equipment. Examples include industrial technologies such as induction heating and melting, direct arc furnaces and infrared drying; cooking for commercial establishments; and heat pumps for residences. Load building should include programs that promote electric fuel substitution. Load building effects should be reported as a negative number, shown with a minus sign.
Load Estimate

A series of studies performed to determine the heating or cooling requirements of your home. An energy load analysis uses information such as the square footage of your home, window and door areas, insulation quality and local climate to determine the heating and cooling capacity needed by your furnace, heat pump or air conditioner. When referring to heating, this is often known as a Heat Loss Analysis, since a home’s heating requirements are determined by the amount of heat lost through the roof, entry ways and walls.
Local Exhaust Ventilation

An industrial ventilation system that captures and removes contaminants emitted from nearby sources before dilution into ambient workplace air can occur.
Make-Up Air

See “Outdoor Air Supply.”
Man-Made Mineral Fibers (MMMF)

Fiber insulation products including glass wool, fiberglass, rock wool, slag wools, as well as refractory ceramic fibers, which are used for fireproofing.
Manometer

An instrument that measures air pressure differences between locations. Tubes are usually attached to a manometer and run to the spaces where pressures are measured.
Manual D

Manual D is the ACCA method for designing duct systems. Contractors often find it a laborious process and most duct systems are just installed, not designed. The amount of time necessary to design a duct system is certainly warranted in tract construction where the design is used repeatedly and for custom homes where the total cost of the home warrants a proper design. In short, designing a duct system is essential for proper equipment performance and customer comfort.
Manual J

Manual J is a widely accepted method of calculating the sensible and latent cooling (and heating) loads under design conditions. It was jointly developed by the Air Conditioning Contractors of America (ACCA) and the Air-Conditioning and Refrigeration Institute (ARI).
Manual S

Manual S is the ACCA method of selecting air conditioning equipment to meet the design loads. It ensures that both the sensible capacity and the latent capacity of the selected equipment will be adequate to meet the cooling load.
Mastic

An adhesive paste used in the fabrication and sealing of thermal insulation on piping fittings, equipment, and duct work. It spreads easily and dries permanently. Its applications include new ducts and old, sheet metal seams, and ductboard. Not all mastics are created equal. Some are toxic, some are water-based, and some take longer to cure, making them more suitable for new construction than retrofit.
Matched System

A heating and cooling system comprised of products that have been certified to perform at promised comfort and efficiency levels when used together, and used according to design and engineering specifications.
Material Safety Data Sheets (MSDS)

Product safety information sheets prepared by manufacturers and marketers of products containing toxic chemicals. These sheets can be obtained by requesting them from the manufacturer or marketer. Some stores, such as hardware stores, may have material safety data sheets on hand for products they sell.
Mechanical System

See HVAC.
Megawatt Hour (MWh)

One thousand kilowatt-hours, or an amount of electricity that would supply the monthly power needs of a typical home having an electric hot water system.
Megawatt (MW)

One thousand kilowatts (1,000 kW) or one million (1,000,000) watts. One megawatt is enough energy to power 1,000 average California homes.
MHPU (Mobile Home Package Unit)

The Mobile Home Package Unit is an air conditioner with electric or gas heat or can be a Heat Pump. This unit has the condenser and air handler all-in-one package. Commonly used in mobile homes and sits outside. (Self-contained unit)
Microbiologicals

See “Biological Contaminants.”
Mildew

A superficial covering of organic surfaces with fungi under damp conditions.
Mitigation

A procedure or strategy aimed at reducing or eliminating an indoor air problem, either through source control, ventilation control, exposure reduction, or air cleaning.
Mixing Ratio (Relative Humidity)

Is often used in drying applications and is the ratio of the mass of water vapor to the mass of dry air with which it is associated. Vaisala products give this output as grams of water per kilogram of dry air (g/kg).
Mold

A fungal infestation that causes disintegration of a substance. Molds are a group of organisms that belong to the kingdom Fungi. In this document, the terms fungi and mold are used interchangeably. There are over 20,000 species of mold.
Multiple Chemical Sensitivity (MCS)

A condition in which a person reports sensitivity or intolerance (as distinct from “allergic”) to a number of chemicals and other irritants at very low concentrations.
mVOC

Microbial volatile organic compound, a chemical made by a mold which may have a moldy or musty odor.
Mycotoxin

A metabolic product generated by certain fungi; includes both useful substances, such as penicillin, and harmful substances, such as aflatoxin.
National Ambient Air Quality Standar (NAAQS)

The US outdoor air quality standard designed to protect public health. Pollutants covered by the NAAQS include ozone, sulfur dioxide, lead, nitrogen dioxide, respirable particulates, and carbon monoxide.
National Institute for Occupational Safety and Health (NIOSH)

The US government agency authorized to research and develop exposure criteria for toxic substances and recommend these standards to OSHA. NIOSH is also authorized to investigate unsafe working conditions.
Natural Ventilation

The supply of outdoor air through passive flow from windows, chimneys, doors, and other infiltration.
Negative Ion Generator

An air cleaning device that uses static charges to remove particulates from indoor air.
Negative Pressure

Condition that exists when less air is supplied to a space than is exhausted from the space, so the air pressure within that space is less than that in surrounding areas. Under this condition, if an opening exists, air will flow from surrounding areas into the negatively pressurized space.
NESHAP

National Emissions Standard for Hazardous Pollutants
New Construction

Energy efficiency program promotion to encourage the building of new homes, buildings, and plants to exceed standard government-mandated energy efficiency codes; it may include major renovations of existing facilities.
Nitrogen dioxide (N02)

A pollutant associated with combustion; a deep lung irritant. The two most prevalent oxides of nitrogen are nitrogen dioxide (NO2) and nitric oxide (NO). Both are toxic gases with NO2 being a highly reactive oxidant, and corrosive. NO gradually reacts with the oxygen in the air to form NO2.
Nozzle

An air terminal device designed to generate a low energy loss and thus produce a maximum throw by minimum entertainment.
Occupational Safety and Health Administration (OSHA)

The regulatory arm of the US Department of Labor, which promulgates safety and health standards, facilitates training programs, and enforces regulations on work sites. OSHA has developed permissible exposure limits for over 600 contaminants present in the industrial workplace.
Ohm

A unit of measure of electrical resistance. One volt can produce a current of one ampere through a resistance of one ohm.
Organic Compounds

Chemicals that contain carbon. Volatile organic compounds vaporize at room temperature and pressure. They are found in many indoor sources, including many common household products and building materials.
Original Equipment Manufacturer (OEM)

Refers to the manufacturers of complete vehicles or heavy­duty engines, as contrasted with remanufacturers, converters, retrofitters, up-fitters, and repowering or rebuilding contractors who are overhauling engines, adapting or converting vehicles or engines obtained from the OEMs, or exchanging or rebuilding engines in existing vehicles.
Outdoor Air Supply

Air brought into a building from the outdoors (often through the ventilation system) that has not been previously circulated through the system. Also known as “Make-Up Air.”
Outdoor Coil

[Also see Condenser Coil] Refrigerant containing portion of a fan coil unit similar to a car radiator, typically made of several rows of copper tubing with aluminum fins.
Outside Air

Air taken from outdoors and not previously circulated through the HVAC system.
Ozone (03)

A kind of oxygen that has three atoms per molecule instead of the usual two. Ozone is a poisonous gas, but the ozone layer in the upper atmosphere shields life on earth from deadly ultraviolet radiation from space. The molecule contains three oxygen atoms (O3). a highly reactive form of oxygen. Ozone exposure an result in mucous membrane irritation and potential pulmonary damage. Some copier machines and laser printers emit noticeable levels.
Ozone Generator

An air cleaning device that produces highly reactive ozone, which reacts with volatile organic compounds to form non hazardous products, remove particulates, and reduce the number of biocontaminants. These devices are controversial because their touted benefits may only be accomplished at ozone levels above recommended exposure levels.
Ozone Hole

Thin place in the ozone layer located in the stratosphere high above the Earth. Stratospheric ozone thinning has been linked to destruction of stratospheric ozone by CFCs and related chemicals. The 1990 CLEAN AIR ACT has provisions to reduce and eliminate ozonedestroying chemicals’ production and use. Ozone holes have been found above Antarctica and above Canada and northern parts of the United States, as well as above northern Europe.
Package Unit or Package System

A self-contained unit or system that has the Air Handler & Condenser in same unit. Normally placed outside the home and connected to a duct system by a penetration through the homes foundation. Except for geothermal which is a self-contained indoor unit that is place in a closet, attached garage, basement, or mechanical room.
PAPR

Powered air purifying respirator.
Particulates

Small airborne particles found in indoor environments which include fibrous materials, solid-state semi-volatile organic compounds, and biological materials.
Pascals (Pa)

A small unit of air pressure. One pound per square inch equals 6,895 pascals.
Passive Smoking

The inhalation of environmental tobacco smoke; also called involuntary smoking.
Pathogen

Any microorganism or substance that causes disease.
PELs

Permissible Exposure Limits (standards set by the Occupational, Saftey and Health Administration).
Permeable

Porous, allowing the passage of air.
Personal Protective Equipment (PPE)

Pesticides

Pesticides are chemicals that are used to kill or control pests which include bacteria, fungi, weeds, and other organisms, in addition to insects and rodents. Most pesticides are inherently toxic. Most contain volatile organic compounds.
Picocurie

A unit of measurement used to describe radon concentration.
Plenum

Air compartment connected to a duct or ducts. Air flow passage made of duct board, metal, drywall, or wood. Joins supply and return ducts with HVAC equipment. The portions of the air distribution system that makes use of the building structure, and the sheet meal that connects distribution ductwork to an air handling unit. Many buildings use the space above a dropped ceiling as a plenum.
Pollutant Pathways

Avenues for distribution of pollutants in a building. HVAC systems are the primary pathways in most buildings; however all building components interact to affect how air movement distributes pollutants.
Positive Pressure

Condition that exists when more air is supplied to a space than is exhausted, so the air pressure within that space is greater than that in surrounding areas. Under this condition, if an opening exists, air will flow from the positively pressurized space, outward to surrounding areas.
Power

The rate at which energy is transferred. Electricity for use as energy is also referred to as power. Electrical power is usually measured in watts. Also used for a measurement of capacity.
PPM (Parts Per Million)

A unit, which may be mass/mass, and hence represents a direct measure of fractional mass, or volume/volume, and represents in this case, a molar fraction at low pressures and high temperatures, commonly used to represent the degree of pollutant concentration where the concentrations are small.
Pressed Wood Products

A group of materials used in building and furniture construction that are made from wood veneers, particles, or fibers bonded together with an adhesive under heat and pressure.
Pressure balancing

The process of neutralizing pressure differences within a home.
Preventive Maintenance (PM)

A program of building maintenance implemented to reduce the possibility of problems, usually through periodic inspection, cleaning, adjustment. calibration. and replacement of functioning, parts of the HVAC system, as well as housekeeping practices to reduce the buildup of potential contaminants. Primarily done on a building’s mechanical systems, this involves a regular and systematic inspection, cleaning, and replacement of worn parts, materials, and systems. Preventive maintenance helps to prevent parts, material, and systems failure by ensuring that parts, materials and systems are in good working order.
Price of Quality, The

There is more to buying a heat pump or air conditioner than ratings. The quality of construction and materials used as well as the reliability of the manufacturer and installing contractor can all affect your long-term satisfaction and comfort. Top quality, high efficiency equipment will cost more initially, but it will save you money on utility bills and service calls for years to come. Be sure to weigh all the factors before choosing your new system.
Primary Air Flow Rate

Volume of air entering a supply air terminal device within a time unit.
Process Heating

Energy Efficiency program promotion of increased electric energy efficiency applications in industrial process heating.
Programmable Controller

A device that controls the operation of electrical equipment (such as air conditioning units and lights) according to a preset time schedule.
Psychosocial Factors

Psychological, organizational, and personal stressors that could produce symptoms similar to those caused by poor indoor air quality.
R-Value

A measure, in Btu/(ft2 F), of the resistance to transmission of heat by an insulating material. The higher the R-value of a material, the greater is its insulating properties and the slower the heat flow through it. The specific value needed to insulate a home depends on climate, type of heating system and other factors.
Radiant

System that uses hot surfaces to radiate or convect heat into the environment. Without the use of fans or blowers
Radiant Barrier

A device designed to reduce or stop the flow of radiant energy.
Radiation

The transfer of heat directly from one surface to another (without heating the intermediate air acting as a transfer mechanism).
Radioactive Decay

The disintegration of the nuclei of the atoms of radioactive (charged) elements with the concomitant release of alpha, beta, or gamma rays.
Radon (Rn) and Radon Decay Products

Radon is a radioactive gas formed and emitted by the decay of radium and uranium in rock. The radon decay products (also called radon daughters or progeny) can be breathed into the lung where they continue to release radiation as they further decay.
Re-Entrainment

Situation that occurs when the air being exhausted from a building is immediately brought back into the system through the air intake and other openings in the building envelope.
Receiver

Tank on the liquid side of a system that holds excess refrigerant in the system that needs to be there for proper operation.
Reclaiming

Processing or returning used refrigerant to the manufacturer or processor for disposal or reuse.
Recool

The sensible cooling of air that has been previously heated by HVAC systems serving the same building.
Refrigerant

Substance used in refrigerating mechanism. A substance that produces a refrigerating effect while expanding or vaporizing. Air conditioning systems use Refrigerant in the Evaporator Coil to cool air as it passes by. Refrigerants absorb heat in evaporator by change of state from a liquid to a gas, and releases its heat in a condenser as the substance returns from the gaseous state back to a liquid state.
Refrigerant Charge

The amount of refrigerant contained within the airc conditioning equipment and required for proper operation.
Refrigerant Lines

Two copper lines that connect the Condenser (Outdoor) Coil to the Evaporator (Indoor) Coil.
Registers

Combination grille and damper assembly covering an air opening or end of an air duct. Coverings for the ducts where they open to the conditioned space. (Same as Grilles)
Reheat

The heating of air that has been previously cooled either by mechanical refrigeration or economizer cooling systems.
Relative Humidity (RH)

Relative humidity is defined as the ratio of the water vapor pressure to the saturation vapor pressure (over water) at the temperature of the gas. RH = Pw/Pws * 100
Relative Risk

The ratio of health impact incidence among exposed individuals to incidence among unexposed individuals.
RELs

Recommended Exposure Limits (recommendations made by the National Institute for Occupational Safety and Health (NIOSH)).
Remediate

Fix
Reservoir

The environmental substrate, or source, of a particular organism. Reservoirs for indoor biocontaminants include stagnant water, moist surfaces, and dust collection sites.
Residential

The residential sector is defined as private household establishments which consume energy primarily for space heating, water heating, air conditioning, lighting, refrigeration, cooking, and clothes drying. The classification of an individual consumer¹s account, where the use is both residential and commercial, is based on principal use.
Resistance (Electrical)

The ability of all conductors of electricity to resist the flow of current, turning some of it into heat. Resistance depends on the cross section of the conductor (the smaller the cross section, the greater the resistance), the material, the length of the flow path, and its temperature (the hotter the cross section, the greater its resistance).
Resistance (Thermal)

The reciprocal of thermal conductance. See R-VALUE.
Respirable Suspended Particulates

Particulates less than 10 µm in diameter that can enter the respiratory tract.
Retrofit

Broad term that applies to any change after the original purchase, such as adding equipment not a part of the original purchase. As applied to alternative fuel vehicles, it refers to conversion devices or kits for conventional fuel vehicles. (Same as 3aftermarket2.)
Return

The ductwork that carries air from the house to the air handler.
Return Air

Air drawn into a heating unit after having been circulated from the heater’s output supply to a room. The air removed from an occupied space and returned to the air handler to be exhausted or recirculated.
RSES

A leading HVAC/R Association – Refrigeration Service Engineers Society – http://www.rses.org/
Saturation Temperature

Also referred to as the boiling point or the condensing temperature. This is the temperature at which a refrigerant will change state from a liquid to a vapor or visa versa.
SEER (Seasonal Energy Efficiency Ratio)

An efficiency measurement that is similar to Miles Per Gallon for cars. The higher this number, the more energy efficient they system is. The amount of cooling your equipment delivers per every dollar spent on electricity. The higher the number the lower the operating cost (not more cooling.) SEER applies to air conditioners and heat pumps. In the past, a unit with a SEER of 8.00 was considered standard efficiency, and a unit with a 10.00 SEER was considered high efficiency. After January 1, 1992, the minimum SEER required by the DOE is 10.00 and 15.00+ SEER is considered high efficiency. EER & SEER can not be compared equally. Air source equipment is rated by SEER and geothermal equipment is rated by EER. New units have SEER ratings from 10 to 17 BTUs per watt. The total cooling of a central unitary air conditioner or unitary heat pump in Btu’s during its normal annual usage period for cooling divided by the total electric energy input in watt-hours during the same period. The Seasonal Energy Efficiency Ratio is a standard method of rating air conditioners based on three tests. All three tests are run at 80 degrees Fahrenheit inside and 82 degrees Fahrenheit outside. The first test is run with humid indoor conditions, the second with dry indoor conditions, and the third with dry conditions cycling the air conditioner on for 6 minutes and off for 24 minutes. The published SEER may not represent the actual seasonal energy efficiency of an air conditioner in your climate. The total cooling output of a central air conditioning unit in Btus during its normal usage period for cooling divided by the total electrical energy input in watt-hours during the same period, as determined using specified federal test procedures. [Title 20, Section 2-1602(c)(11)].
Sensible Cooling Load

The heat gain of the home due to conduction, solar radiation, infiltration, appliances, people, and pets. Burning a light bulb, for example, adds only sensible load to the house. This sensible load raises the dry-bulb temperature.
Sensible Heat

Heat, that when added or removed, causes a change in temperature but not in state. Heat that results in a temperature change.
Sensitization

Repeated or single exposure to an allergen that results in the exposed individual becoming hypersensitive to the allergen.
Setback

A reduction of climate control energy demand in HVAC controls when a building is unoccupied.
Setpoint

The temperature to which a thermostat is set to result in a desired heated space temperature.
Short-Circuiting

Situation that occurs when the supply air flows to return or exhaust grilles before entering the breathing zone (area of a room where people are). To avoid short-circuiting, the supply air must be delivered at a temperature and velocity that results in mixing throughout the space.
Sick building

A building in which the indoor air quality is considered to be unacceptable to a substantial majority of occupants.
Sick Building Syndrome (SBS)

A phenomenon in which building occupants experience a variety of health and/or comfort effects linked to time spent in a particular building, but where no specific illness or causative agent can be identified. Symptoms in sufferers often include headaches, eye irritation, and respiratory irritation. Term that refers to a set of symptoms that affect some number of building occupants during the time they spend in the building and diminish or go away altogether during periods when they leave the building. (Contrast with Building Related Illness.)
Single Package

A year ’round heating and air conditioning system that has all the components completely encased in one unit outside the home.
Sizing

Refers to the procedure a heating contractor goes through to determine how large a furnace (measured in btuh) is needed to heat a house efficiently. Too small a furnace won’t deliver enough heating; too large a furnace increases energy costs and can have an adverse effect on comfort. Sizing depends on the square-footage of the home, the amount of ceiling and wall insulation, the window area, use of storm doors, storm windows, and more.
Smoke stick

A diagnostic tool used to observe air flow. Usually it consists of a chemical in a squeezable container. When squeezed it emits smoke which visibly follows air flow currents.
Sound Attenuators

Components which are inserted into the air distribution system and designed to reduce airborne noise which is propagated along the ducts.
Sound Rating Number (SRN)

Sound is measured in bels (a bel equals 10 decibels). The SRN of a unit is based on ARI test, performed at ARI standard rating conditions. Average sound rating range from 7.0 to 8.0 decibels. The lower the SRN rating, the quieter the unit.
Sound Ratings

Although sound does not affect the efficiency of a unit, it will certainly affect your comfort. If your unit has a low sound level, you will hardly notice it is operating. But if it has a higher sound level, it may mean your good night’s sleep is disturbed every time it runs!
Source Control

A preventive strategy for reducing airborne contaminant levels through removal of the material or activity generating the pollutants.
Sources

Sources of indoor air pollutants. Indoor air pollutants can originate within the building or be drawn in from outdoors. Common sources include people, fixtures and furnishings, photocopiers, plants, food, etc.
Specific Heat

In English units, the quantity of heat, in Btu, needed to raise the temperature of one pound of material one degree Fahrenheit.
Split System

Refrigeration or air conditioning installation, which places condensing unit outside or away from evaporator. These unit are connected together by a supply and return refrigerant lines. Also applicable to heat pump installations. A combination heat pump or air conditioner with indoor components such as a furnace or blower coil. To maximize effectiveness, Split Systems should be matched.
Spore

Molds reproduce by means of spores. Spores are microscopic; they vary in shape and size (2-100 micrometers). Spores may travel in several ways–they may be passively moved (by a breeze or waterdrop), mechanically disturbed (by a person or animal passing by), or actively discharged by the mold (usually under moist conditions or high humidity).
Spread (LS) (for a supply air terminal device)

Maximum distance between two vertical planes tangent to a specified envelope and perpendicular to a plane through the core center. The spread are generally referred to the envelope corresponding to 0.25 m/s for zero supply temperature differential (i.e., under isothermal conditions).
SRN (Sound Rating Number)

Sound is measured in bels (a bel equals 10 decibels). The SRN of a unit is based on ARI test, performed at ARI standard rating conditions. Average sound rating range from 7.0 to 8.0 decibels. The lower the SRN rating, the quieter the unit.
SRN (Sound Rating Number )

Sound is measured in bels (a bel equals 10 decibels). The SRN of a unit is based on ARI test, performed at ARI standard rating conditions. Average sound rating range from 7.0 to 8.0 decibels. The lower the SRN rating, the quieter the unit.
Stack effect

A condition resulting from the rise of heated air, which creates positive pressure near the top of the building and negative pressure toward the bottom. Stack effect pressures have been known to overpower mechanical ventilation systems, disrupting proper circulation and contributing to the infiltration and stagnation of pollutants.
Stack Effect

The overall upward movement of air inside a building that results from heated air rising and escaping through openings in the building super structure, thus causing an indoor pressure level lower than that in the soil gas beneath or surrounding the building foundation.
Standard Industrial Classification (SIC)

A set of codes developed by the Office of Management and Budget, which categorizes business into groups with similar economic activities.
Static Pressure

Condition that exists when an equal amount of air is supplied to and exhausted from a space. At static pressure, equilibrium has been reached.
Statistical Significance

The probability that and degree to which the results of an experimental study describe an actual relationship between two factors beyond that which might be expected by pure coincidence.
Straight Cool

This is an air conditioner that uses different forms of heating such as Natural Gas, LP Gas, Electric Resistance heat and oil.
Stratosphere

Part of the atmosphere, the gases that encircle the Earth. The stratosphere is a layer of the atmosphere 9-31 miles above the Earth. Ozone in the stratosphere filters out harmful sun rays, including a type of sunlight called ultraviolet B, which has been linked to health and environmental damage.
Subcooled Liquid

Liquid refrigerant which is cooled below its saturation temperature.
Superheated Vapor

Refrigerant vapor which is heated above its saturation temperature. If a refrigerant is superheated, there is no liquid present.
Supplementary Heat (Emergency Heat)

The auxiliary or emergency heat provided at temperatures below a heat pump’s balance point. It is usually electrical resistance heat.
Supply

The ductwork that carries air from the air handler to the rooms in the house.
Supply Air

The air flow entering the treated space.
Swamp Cooler

See Evaporative Cooler.
Switchover Valve

A device in a heat pump that reverses the flow of refrigerant as the system is switched from cooling to heating. Also called a reversing valve or four-way valve.
System

A combination of equipment and/or controls, accessories, interconnecting means and terminal elements by which energy is transformed to perform a specific function, such as climate control, service water heating, or lighting.
Systems Control

The control of indoor air pollutants through the use of mechanical means such as ventilation control or air cleaning.
Temperature

Degree of hotness or coldness measured on one of several arbitrary scales based on some observable phenomenon (such as the expansion).
Temperature Differential

The difference between the entering and leaving temperature for a given fluid. For example, a 10-degree evaporator temperature differential for a chiller would describe an operating condition where the entering water temperature is 54 degrees and the leaving is 44 degrees.
Testing, Adjusting, And Balancing (TAB)

The diagnostic and corrective procedures for HVAC controls and operating components to ensure provision of specified airflow rates and environmental conditions.
Therm

Another measurement of heat. One therm equals One hundred thousand (100,000) British thermal units (1 therm = 100,000 Btu).
Thermal (Energy) Storage

A technology that lowers the amount of electricity needed for comfort conditioning during utility peak load periods. A buildings thermal energy storage system might, for example, use off-peak power to make ice or to chill water at night, later using the ice or chilled water in a power saving process for cooling during the day. See THERMAL MASS.
Thermal Mass

A material used to store heat, thereby slowing the temperature variation within a space. Typical thermal mass materials include concrete, brick, masonry, tile and mortar, water, and rock or other materials with high heat capacity.
Thermodynamics

The study of the transformation of energy into other manifested forms and of their practical applications. Commonly encountered forms of the statements of the three principal laws of thermodynamics are: (0) The heat capacity and entropy of every crystalline solid becomes zero at absolute zero (0 degrees Kelvin). (1) The Law of the Conservation of Energy — energy may be transformed in an isolated system, but its total is constant. (2) Heat from a reservoir at a constant temperature cannot be changed completely into work by a cyclic process.
Thermostat

A temperature sensitive switch for controlling the operation of a heater or furnace. Typically found on a wall inside the home, that consists of a series of sensors and relays that monitor and control the functions of a heating and cooling system. A device that allows you to control the temperature inside your home by telling the heating or cooling system how much air to produce. An automatic control device designed to be responsive to temperature and typically used to maintain set temperatures by cycling the HVAC system.
Thermostat, Air-Sensing

Thermostat unit in which sensing element is located in refrigerated space.
Thermostat, Setback (Programmable Thermostat)

A state-of-the-art electronic thermostat with a built-in memory that can be programmed for different temperature settings at different times of the day. A device, containing a clock mechanism, which can automatically change the inside temperature maintained by the HVAC system according to a preset schedule. The heating or cooling requirements can be reduced when a building is unoccupied or when occupants are asleep.
Threshold (IAQ)

The contaminant dose or exposure level below which there is no expected significant effect.
Threshold Limit Value (TLV)

The American Conference of Governmental Industrial Hygienists recommended guideline for exposure limit represented in terms of exposure over a work day (8 hours) or a work week (40 hours).
Threshold Limit Values (TLVs)

Threshold Limit Values (guidelines recommended by the American Conference of Governmental Industrial Hygenists).
Throw (Lt)

The maximum distance between the center of the core and a plane which is tangent to a specified envelope and perpendicular to the intended direction of flow The throw is generally referred to as the envelope corresponding to 0.25 m/s for zero supply temperature differential (i.e., under isothermal conditions).
Tight Building Syndrome (TBS)

A condition in which a building is very tightly insulated against infiltration, its ventilation is reduced for energy conservation, and airborne contaminants are sufficiently elevated to cause health effects in occupants; often used synonymously with sick building syndrome (SBS).
Time Delay

Usually refers to a device that will not allow the condenser to restart for an average of 5 minutes.
Ton or “Ton of Cooling”

A cooling unit of measure. Each ton equals the cooling effect of 12,000 Btuh. Heat pumps and air conditioners are generally sized in tons. Typical sizes for single family residences are between two and five tons. It is important to note that actual capacity is not constant and will change based on outdoor or indoor temperatures. The published capacity rating of air conditioners and heat pumps is based on performance at the ARI standard temperature levels of 95 F outside, 80 F inside, and 50% relative humidity. The number of tons a system has is the total BTU capacity of the system. The size of the area to be cooled will determine the correct size of the system in tons. While an air conditioner may be called a three ton unit, it may not produce 36,000 Btu/h in cooling. There is a wide variety of actual capacities that are called “three tons.”
Total air flow rate (QL)

Sum of the primary and secondary air flow rates which are moved in the treated space.
Total Home Comfort System

The ultimate solution to providing you with consistent, customized home comfort, despite the ever-changing weather.
Total Volatile Organic Compounds (TVOCs)

A measure representing the sum of all VOCs present in the air to provide an approximate indication of pollutant levels. Indoor air typically contains hundreds of different VOCs in very low concentrations, some of which can have additive effects.
Total Volatile Organic Compounds (TVOCs)

Total volatile organic compounds. See “Volatile Organic Compounds (VOCs)”
Toxicant

A substance that can cause tissue damage or otherwise affect organs or systems within the body.
Tracer Gas

An inert compound that is a rare constituent of indoor air which is released into building air and monitored qualitatively and/or quantitatively to characterize airflow characteristics to determine air pathways, infiltration, and ventilation efficiency measurements.
Tracer Gases

Compounds, such as sulfur hexaflouride, which are used to identify suspected pollutant pathways and to quantify ventilation rates. Trace gases may be detected qualitivatively by their odor or quantitatively by air monitoring equipment.
Transformer

A device, which through electromagnetic induction but without the use of moving parts, transforms alternating or intermittent electric energy in one circuit into energy of similar type in another circuit, commonly with altered values of voltage and current.
Transmittance

The time rate of heat flow per unit area under steady conditions from the air (or other fluid) on the warm side of a barrier to the air (or fluid) on the cool side, per unit temperature difference between the two sides.
UA

A measure of the amount of heat that would be transferred through a given surface or enclosure (such as a building envelope) with a one degree temperature difference between the two sides. The UA is calculated by multiplying the U-Value, or overall heat transfer coefficient U, by the area A of the surface (or surfaces).
Unconditioned Space

A space that is neither directly nor indirectly conditioned space, which can be isolated from conditioned space by partitions and/or closeable doors.
Upflow

See “Upflow Furnace”
Upflow Furnace

A furnace that pulls cool return air in from the bottom and blows/expels warm air out the top into the duct work. This type of furnace is usually installed in a basement or an out-of-the-way closet.
Urea Formaldehyde Foam Insulation (UFFI)

A form of insulation no longer in use because of excessive formaldehyde emissions and documented associated health impacts.
Useful Thermal Output

The thermal energy made available for use in any industrial or commercial process, or used in any heating or cooling application, i.e., total thermal energy made available for processes and applications other than electrical generation.
Valves

Components inserted into air ducts or devices which permit modification of the air resistance of the system and consequently a complete shut-off of the air flow (control valves).
VAV System (Variable Air Volume System)

A mechanical HVAC system capable of serving multiple zones which controls the temperature maintained in a zone by controlling the amount of heated or cooled air supplied to the zone.
VAV (Variable Air Volume)

Variable Air Volume.
Ventilation

The process of supplying or removing air by natural or mechanical means to or from any space. Such air may or may not have been conditioned or treated.
Ventilation Air

Defined as the total air, which is a combination of the air brought inside from outdoors and the air that is being recirculated within the building.
Ventilation effectiveness

A measure of the fraction or percentage of outdoor air that reaches the occupied zone of a specified area; an evaluation of air delivery to occupants, regardless of the effectiveness of contaminant removal.
Ventilation efficiency

An evaluation of the pollutant removal capacity of a ventilation system.
Ventilation Rate

The rate at which indoor air enters and leaves a building. Expressed in one of two ways: the number of changes of outdoor air per unit of time (air changes per hour, or “ach”) or the rate at which a volume of outdoor air enters per unit of time (cubic feet per minute, or “cfm”).
Ventilation standard

A specification for the minimum rate of input of outdoor air into indoor spaces.
VFD (Variable Frequency Drive)

Electronic speed control for motors.
Volatile Organic Compounds (VOCs)

One of a class of chemical compounds; indoor sources include tobacco smoke, building products, furnishings, cleaning materials, solvents, and office supplies. In sufficient quantities, VOCs can cause eye, nose, and throat irritations; dizziness; and headaches. Some VOCs are suspected carcinogens. Data for health effects resulting, from exposure to the characteristically low levels of VOCs in the indoor environment are scarce. Compounds that vaporize (become a gas) at room temperature. Common sources which may emit VOCs into indoor air include housekeeping and maintenance products, and building and furnishing materials. In sufficient quantities, VOCs can cause eye, nose, and throat irritations, headaches, dizziness, visual disorders, memory impairment; some are known to cause cancer in animals; some are suspected of causing, or are known to cause, cancer in humans.
Volt

A unit of electromotive force. It is the amount of force required to drive a steady current of one ampere through a resistance of one ohm. Electrical systems of most homes and office have 120 volts.
W (Watt)

A watt is a unit of electricity. A unit of measure of electric power at a point in time, as capacity or demand. It is the rate of energy transfer equivalent to 1 ampere flowing under a pressure of 1 volt at unity power factor. One watt of power maintained over time is equal to one joule per second. Some Christmas tree lights use one watt. The watt is named after Scottish inventor James Watt and is capitalized when shortened to w and used with other abbreviations, as in kWh.
Water vapor

Water vapor can be treated as a gas. At a particular temperature air for example can only hold so much water vapor. The higher the temperature the more water vapor it can hold. When saturated the relative humidity would be 100 % RH, so relative humidity describes how close to saturation the air is. It is important to remember that in a process with a high relative humidity a small drop in temperature will cause the humidity to rise and the environment to saturate. Rapid temperature changes in a an environmental chamber for example could also cause condensation.
Watt-Hour (W-hr)

One watt of power expended for one hour. An electrical energy unit of measure equal to 1 watt of power supplied to, or taken from, an electric circuit steadily for 1 hour. One thousandth of a kilowatt-hour.
WB

Wet Bulb
WC (Water Column)

Common measure of air pressure used in HVAC systems.
Weather Stripping

Specially designed strips, seals and gaskets installed around doors and windows to limit air leakage.
Wet Bulb Temperature

The temperature at which water, by evaporating into air, can bring the air to saturation at the same temperature. Wet-bulb temperature is measured by a wet-bulb psychrometer. Traditionally this was the temperature indicated by a thermometer whose bulb is wrapped in a wet sheath. The wet bulb temperature and the dry bulb temperature (i.e air temperature) would then be used to calculate relative humidity or dewpoint. Alternatively charts or tables can be used.
Wet-bulb Temperature

When a wet wick is placed over a standard thermometer and air is blown across the surface, the water evaporates and cools the thermometer below the dry-bulb temperature. This cooler temperature (called the wet-bulb temperature) depends on how much moisture is in the air.
Whole House Fan

A system capable of cooling a house by exhausting a large volume of warm air when the outside air is cool.
Zonal Control

A method of designing and controlling the HVAC system of a residence so that living areas can be maintained at a different temperature than sleeping areas using independent setback thermostats. If specific requirements are met, zonal control may earn a credit towards compliance with whatever building energy efficiency standards are applicable.
Zone

1) Conditioned space in a house under the control of a thermostat. 2) A space within a house with a distinct pressure compared to other pressure zones. Also see Buffer zone. or 1) In the context of an HVAC system: a space or group of spaces served by an HVAC system or portion of an HVAC system controlled by a single thermostat or other control device; 2) A space or group of spaces within a building with sufficiently similar comfort conditioning requirements so that comfort conditions can be maintained throughout by a single control device.
Zone Heat

A central heating system in a building, designed to allow different temperatures to be maintained in two or more parts of the building.
Zoning

A system in which living areas or groups of rooms are divided into separate spaces and each space’s heating/air conditioning is controlled independently. This can be accomplished by using either multiple independent systems, or a single system using electronic controls and motorized dampers (see Damper). For example, you might prefer to have the kitchen area of your home be slightly cool, while at the same time keeping the temperature in the bedrooms warmer.

History of HVAC Brands

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AAON: Evolved from John Zink/Sunbeam, makes packaged rooftop equipment.

ADDISON PRODUCTS: Now a division of Heat Controller.

AIRQUEST: Name used by International Comfort Products.

AIRTEMP: Became a subsidiary of Fedders Corp. in 1976. See Fedders.

AMANA: Formerly a division of Raytheon, now part of Goodman Manufacturing.

AMERICAN FURNACE [AFCO]: In 1968 became part of the climate control division of the
Singer Co. In 1970 became Singer American Furnace. See Singer.

AMERICAN-STANDARD: Became Tappan Air Conditioning division in 1972. American-Standard
purchased the Trane Company in 1984. American-Standard name revived in 1988.

ARCO: Acquired by SnyderGeneral in 1984 from Atlantic Richfield. Added to Climate Control
unit as Arcoaire. In 1991 became part of Inter-City Products (now International Comfort
Products) with brandmate Comfortmaker. In 1999, ICP was purchased by United Technologies, parent of Carrier.

ARKLA: Division sold to Preway, Inc. Preway sold Servel gas air conditioning to the Dometic
Corp. High efficiency furnace technology sold to Trane. Servel name now sold by Robur.

ARMSTRONG:Founded by Lennox in 1928, became division of the Johnson Corp. in 1957. See Magic Chef. Name revived in 1988 to Armostrong Air after Lennox purchased the climate control line from Magic Chef.

BARD: Bard Manufacturing.

BOHN: A subsidiary of Lennox International.

BRYANT: A division of Carrier Corp-United Technologies.

CARRIER: A wholly owned subsidiary of United Technologies.

CENTURY: Century Engineering Corp, Cedar Rapids, purchased by Heat Controller in 1975.
Century name still used by Heat Controller on products made by OEMs.

COLEMAN: Heating division started in 1958. Bought by MacAndrews & Forbes Group in 1989, by Beacon International using the name Evcon Industries in 1990, by York International in 1994.

COMFORTAIRE: A tradename of Heat Controller. See Century.

COMFORTMAKER: Old AFCO name revived at founding of SnyderGeneral by former Singer
HVAC boss. See Singer. Comfortmaker now owned by Inter-City Products. In 1999, ICP was purchased by United Technologies.

COMMAND-AIRE: Water source heat pump maker now owned by American-Standard.

COOLERATOR, McGRAW-EDISON: Lasted listed as making HVAC products in 1978.

CRANE: Stopped making HVAC products in 1968. Furnace technology sold to Amana.

CUMBERLAND: A brand name used by American-Standard/Trane.

DAIKIN US: Japanese company making mini splits withdrew from the US market in 1988.

DAY & NIGHT: Part of the BDP Co. division of Carrier Corp-United Technologies. Name being
dropped as of late 1997.

DELCO: Old GM appliance division last listed in 1964.

DUCANE: Purchased by Lennox in 1999.

DUNHAM-BUSH: Most divisions sold to Topgroup Holdings Berhad of Malaysia.

DUOMATIC-OLSEN: Canadian maker changed name to DMO Industries with Olsen & Airco as
brand names.

ELECTRIC-FURNACE-MAN: Now known as EFM Company making boilers & furnaces

EUBANK: Texas manufacturer of cooling equipement, also OEM for Heat Controller.

FANDAIRE: Last A/C units manufacturered in 1962.

FASCO: Stopped making HVAC products in 1983.

FRASER-JOHNSTON: Became part of Westinghouse. Name dropped in 1978 with end of
Westinghouse HVAC products. Name now used by York International.

FEDDERS: Left the unitary market around 1980. Sells window units under Fedders, Climatrol, Airtemp, Hunter, Emerson brands.

FRIEDRICH: Residential HVAC acquired by ARCO in early 80s. In 1985 became Friedrich
Climate Master Inc. selling water source heat pumps. Friedrich name dropped from
tradename in 1987. Friedrich HVAC products evolved into Arcoaire. Friedrich name still used
on window units & mini splits after purchase of Zoneaire from ICP.

GAFFERS & SATTLER: In 1969 became a subsidiary of Magic Chef. Name no longer used.

GENERAL ELECTRIC: HVAC division purchased by the Trane Company in 1982.

GREEN COLONIAL: Des Moines company stopped making HVAC products in 1975.

HALL-NEAL FURNACE: Indianapolis company last listed in 1966.

HASTINGS: Last listed in 1964, now manufacturers unit & duct heaters.

HEIL-QUAKER: Purchased by Inter City Gas, Toronto, from Whirlpool Corp. Tempstar name
added to replace Whirlpool name. HVAC division now part of International Comfort Products. In 1999, ICP was purchased by United Technologies.

HENRY FURNACE [MONCRIEF]: Purchased by Luxaire, Inc. Now part of York International.

HOME FURNACE: Became Home Furnace division, Lear-Siegler Inc. Became Miller Heating &
Air Conditioning in 1986 after being acquired by Nortek Inc. Now listed as Nordyne. See
Intertherm.

INTERNATIONAL HEATER: In 1965 controlling interest acquired by Weil-McLain. Became
International Heating & Air Conditioning division in 1973. Last listed in 1974. Weil-McLain
now owned by United Dominion.

INTERNATIONAL OIL BURNER: Founded in St. Louis in 1919. Became Intertherm in 1969.

INTERTHERM: Became Nordyne company in 1987. Brandmate Miller. In 1998, Nordyne started marketing under White-Westinghouse brands Frigidaire, Philco, Tappan, Kelvinator & Gibson. Nordyne is OEM for Thermal Zone.

IRON FIREMAN: Now a tradename of Dunham-Bush.

ITT: Stopped making HVAC products in 1983.

JANITROL: Division of Surface Combustion Co. became division of Midland-Ross in 1960,
division of Tappan in 1977. Janitrol name sold to Goodman Mfg. in 1982. Also sold as
Goodman, Hamilton, Johnstone, Sears Kenmore.

JOHNSON, AIR-EASE: Founded in 1958 by C.A. Olsen (who started Luxaire) and brother-in-law Johnson. Became part of Magic Chef in 1972. Now owned by Lennox. Air Ease brand now part of Armstrong Air division of Lennox.

LENNOX: Lennox Industries.

LUXAIRE:Founded in 1939, purchased by Westinghouse in 1955, was purchased by York in 1981.

MAGIC CHEF: In 1986, Magic Chef was acquired by the Maytag Co. Air conditioning division
was sold to Lennox in 1988 and renamed Armstrong Air. See Johnson.

MAYFLOWER: St. Paul furnace company last listed in 1962.

McQUAY: Formerly a division of SnyderGeneral, now owned by Hong Leong Group Malaysia. Sister division is AAF International.

MILLER: Was Miller the Home Furnace Company started in 1916. Now part of Nordyne with brandmate Intertherm.

MITCHELL: Last listed in 1958.

MONCRIEF: Division of York International. See Luxaire.

MUELLER CLIMATROL: In 1964 became Climatrol Div. Worthington Air Conditioning.
Eventually bought out by Fedders. See Worthington and Fedders.

NATIONAL U.S. RADIATOR (Capitolaire): Acquired by Crane in 1960.

NESBITT: Acquired by ITT in 1963. Divested by ITT in 1979 and filed for bankrupcy in 1980.
Now a tradename of Mechanical Specialties, Inc.

NIAGRA: Acquired by Rybolt in 1961.

OLSEN: In 1965 became Luxaire, Inc. with brand names Luxaire & Moncrief. Acquired by
Westinghouse then sold to York Div. Borg-Warner in 1981. Olsen name no longer in use by
York.

ONEIDA-ROYAL: Purchased by Utica Boilers Inc. in 1990.

PAYNE: A division of Carrier Corp-United Technologies. The name is used on the economy line of Carrier equipment.

PEERLESS: In 1964 became Peerless Division, Space Conditioning Systems. Eventually
acquired by Dunham-Bush with names dropped in mid 1970s.

PEERLESS HEATER: Boiler manufacturer since 1908.

PERFECTION: Became Perfection Division, Hupp Industries in 1964. In 1965, Perfection name
dropped. Later known as Typhoon Div, Hupp Industries. Hupp in bankrupcy in 1991.

RHEEM: Rheem Manufacturing is owned by Japanese water heater manufacturer Paloma.

ROUND OAK: Last listed in 1963. See Peerless.

RUUD: Part of Rheem Manufacturing. See Rheem.

RYBOLT: Last listed in 1973.

SILENT AUTOMATIC: Last listed in 1961. See Iron Fireman.

SINGER: In 1982 became climate control unit of SnyderGeneral Corp. with name dropped. In
1984 SnyderGeneral operations included Arcoaire, Comfortmaker, McQuay. In 1988
SynderGeneral bought American Air Filter. In 1991, sold Arcoaire & Comfortmaker to Inter-City Products.

SOUTHWEST MFG: Became Heatwave International in 1984, later going bankrupt.

SPACE CONDITIONER: Became Dunham-Bush division in 1968.

SQUARE D: Production resumed as Sun Dial Manufacturing then stopped in the 1980s.

STEWART-WARNER: Last listed in 1976.

TAPPAN: Became SJC Corp. in 1979 with name Frigiking Tappan. In 1982, SJC sold Janitrol
line to Goodman Mfg. Tappan name revived by Nordyne in 1998 under license from White-Westinghouse.

THERMOPRODUCTS: Indiana manufacturer of ThermoPride brand furnaces & air condtioners, now owned by Burnham Corporation

TRANE: The Trane Company purchased GE’s climate control division in 1982. Trane was
purchased by American-Standard in 1984.

TORRIDHEET: Last listed in 1972.

WATERBURY: Last listed in 1962.

WEATHERKING: Former trade name of Addison Products, sold to Rheem in 1989.

WESTINGHOUSE: In 1981, sold to Borg-Warner [York}. Sale rights included names Moncrief,
Luxaire, Fraser-Johnston all now used by York International.

WHIRLPOOL: In 1972 became Whirlpool Div. of Heil-Quaker, a subsidiary of Whirlpool Corp.
Tempstar name replaced Whirlpool after Inter-City Gas Co. bought Heil-Quaker in 1986. See Heil-Quaker.

WILLIAMS OIL-O-MATIC: Last listed in 1972.

WILLIAMSON: Purchased by Hupp Industries which went bankrupt in 1991. Williamson name
was purchased by Metzger Machine (Milwaukee Thermoflo) and used on furnace line. Late 1999, purchased by United Dominion (Weil-McLain’s parent)

WORTHINGTON: Became Mueller Climatrol in 1970 after being acquired by Fedders.

YORK: Formerly a dvision of Borg-Warner, York International is now spun off. York also makes Fraser-Johnson, Luxaire, Moncrief, Winchester, Coleman-Evcon, AirPro

HVAC Preventive Maintenance

Just like a vehicle needs preventive maintenance, HVAC systems need a regular maintenance
schedule. Having maintenance performed on your air conditioner now can help you avoid costly repairs
in the future. Air Conditioning preventive maintenance also pays for itself by
making the unit more efficient and reliable. Often, a technician can spot a ten dollar part
that needs replacing now where if it is let go and not replaced, can cost you hundreds of
dollars more in the future. The old phrase is true, “pay me a little now, or a lot later.”

Filter Reminder

Changing your filters is very important to proper airflow for both the air conditioning and
heating systems. Not only does having a clean filter in your air conditioning and heating system contribute to
a higher efficiency of the unit, it also improves indoor air quality.

Humidifier Information

In the summer, a lot of the energy consumed by your air conditioner is used to de-humidify the air.
In most geographical locations in the U.S. and Canada there is an abundance of moisture in the air.
The process of heating your home in the winter time, especially for heat pumps, dries the air out in your home.
It then becomes necessary to humidify the air (unless you choose to ignore it) to keep a comfortable
level of moisture in the air. Ideally, you want the humidity level in your home to be around 30 to 35
percent. In the summer this is not a problem. In the winter it is a problem. This level of humidity
will also help you feel more comfortable. If the humidity level in your home is high in the summer
you will not feel cool. If the humidity level is low in the winter you will not feel warm. A properly
designed and installed system will keep the proper levels of humidity in your home.

Dust, Dust Mites, Pollen, Viruses, Bacteria, and Humidity

Aside from the comfort factors of having the proper humidity levels in our homes, there is another aspect of
having proper levels of humidity in the home. Humidity affects what is in our air also and this is why a humidifier
is an integral part of a system that maintains optimum indoor air quality standards. Too much humidity promotes the
growth of molds and mildews. Low humidity levels promotes bacteria, viruses, and other organic and
non-organic things that can be hazardous to our health. Below is a chart that will help you see that keeping the proper
humidity levels in your home will also keep out things that can affect our health and our home.

Hot Water Boilers and Steam Boiler Consumer Information

People who use boilers for their main source of heat report that they love
the kind of heat that it provides. If you were thinking that there really is only one type of heat,
you may want to reconsider. All you have to do is add adjectives to the beginning of the word heat.
There is dry heat, wet heat, drafty heat, even heat, and uneven heat just to mention a few. The heat
provided by a boiler will give you even, draftless heat. That is opposed to drafty, uneven heat many
forced air systems provide.

There are many different combinations and configurations for boilers.
There are gas boilers and oil boilers and a combination of the two that are called dual fuel boilers. A boiler is simply a pressure vessel where water is heated for the purpose of providing
heat somewhere for something. There are high pressure boilers and low pressure boilers.
The focus of the boiler page is not on high pressure boilers or the type of fuel used to heat the
water, but on the mechanics of how the loops work and hot water and steam controls on low pressure
residential boilers. Many of the same controls found on gas boilers and oil boilers
are the same controls used on furnaces and water heaters. Refer to the furnace page for more info.
on gas controls. Oil controls will be introduced later.
Boilers can either be hot water or steam (either of those can be gas boilers or oil boilers)
and the piping systems are different for each type. The hot
water system boiler uses a pump to circulate the hot water while the steam boiler uses it’s own
pressure to circulate the steam throughout the system. They also have some similar and some
different controls to run the boiler. Welcome to hot water boilers and steam boiler consumer information.

Aquastats

Aquastats are like thermostats except they control the temperature of the water inside the boiler. Again there are many different configurations for the way the aquastat is hooked up so we are going to stay with the basics. The aquastat has a sensing bulb that is inserted into a well
in the side or front of the boiler. This bulb senses the temperature of the water inside the
boiler. When the temperature drops below a certain set point (usually 140 degrees F.) it
turns the burner on so that the water can be heated to the maximum temperature setting on the
aquastat. The burners are then shut off until the temperature again drops below the set
temperature. These temperature settings are usually manual and are different from one type of
boiler to the next. When you turn your thermostat up you are turning the circulator pump on
(on hot water systems) so the hot water can circulate through the pipes. The hot water leaves
the boiler and makes the loop. By the time it gets back to the boiler it has lost some heat
through the heat exchange process in your radiators or baseboards (and any uninsulated pipes
under the house or in the loop). The cold return water is sensed by the bulb in the aquastat
and the aquastat again turns the burner on to reheat the return water so it may make the trip
through the loop again when the thermostat calls for heat.

The Boiler Water Source

Hot water boilers and steam boilers alike need a water source. This can either be city
water or well water supplied by a pump. This is the source for water that is fed into the boiler.
Barring any leaks, drips, or weeping in your system, the supply from the well or city is
necessary to keep the water level up in the boiler. A dry fired boiler is very dangerous and it is important to keep the water in the boiler at proper levels. For hot water systems
the boiler should be full. Steam systems are different. To much water and the mains flood.
The steam boiler will not function properly with flooded mains. A control at the supply should
keep the proper water levels in the system. At the beginning of the supply (city or well) there
should be a gate or ball valve to turn the water off to the boiler for maintenance and/or to
stop major leaks. When this is shut off the power and fuel source for the boiler should be shut
down also. After the shut off valve there should be a backflow preventer, however there may
be some older boilers that do not have backflow preventers. Current local and national codes
require backflow preventers to keep the supply water from being contaminated by back flow
water from the boiler. Older boilers are grandfathered so they do not require a backflow
preventer. After the backflow preventer there should be a pressure reducer valve. Many city
water sources (and well sources) have pressures exceeding 40 psi. A residential boiler should
not operate at pressures over 20 psi. The pressure reducer valve reduces the supply water
pressure down to 12 psi. After the pressure reducer, the source supply water should be fed into
the return loop.

The Boiler Loop

The beginning of the loop is inside the boiler at the water jackets where the water is heated.
The pump kicks on when the thermostat calls for heat and the heated water is pumped up the
loop supply line where it flows through the basebords, radiators, or coils. As it flows through
these heat exchange devices the water loses heat and flows back to the boiler in the return
line. As it gets near the boiler the water goes through the impellor which is part of the
circulator pump. Most boilers in a hot water system have the circulator pump on the
return side of the loop.

The boiler isolation valves can be turned off so that the
circulator pump can be changed without bleeding the entire loop. Maintenance can be performed
on the boiler without introducing air into the systems loop. Additionally, the air purge drains
eliminate the need to bleed air from all the baseboards or radiators.

New Furnaces

The standing pilot gas furnace

You go to the thermostat and turn the
temperature setting up. Your cold and fully expect the house to warm
to your desired comfort level.
You go back to what you were doing and forget about the heat. A half
hour later you start to feel really cold and go back to the thermostat.
For most people that is the extent of their knowledge about their
heating or cooling system. The thermostat. Besides changing the filter
every once in a while and storing your things next to the old beast
in the closet, that is the only time we ever see or think about the
furnace. And now you are getting cold and your concern is rising.
Whether you are mechanically inclined or not, the best advice we can
offer at this point is to pick up a phone and call a professional.
Okay, so you are the fix-it-myself-type. Here are the things
you need to check first:

• Check the thermostat and make sure it is in the on position and
  turned up.
• Check the filter. A dirty filter can and will cause your furnace
  to malfunction.
• Check the main power. Start at the fuse or circuit
  breaker box and then go to the emergency cutoff switch. These switches
  usually
  look like a regular wall switch except the cover is usually red (but
  not always, sometimes they have white cover plates). So you check
  and everything is good, all the switches are on and no fuses
  blown.
• Make sure there is gas. Did you forget to pay the gas bill? If
  this happens the gas company will put a lock on the meter. Check
  the meter and make sure this hasn’t happened to you. Some gas companies will lock your meter if there is a suspected gas leak. They’ll leave
  a red tag and a lock on the meter. If the meter is okay go to the
  furnace. There should be a valve on the gas line next to the furnace.
  Make sure the valve is on. This valve is called a gas cock and the
  position of the knob should be parallel to the line. This will indicate
  that it is on. If the gas cock is on the next step is to check the
  gas valve itself. This is located inside the panel where the burners
  are. Look at the top of the valve. Is it in the on position? If it
  is, move on to the next step.

Warning: There are some furnaces with pilots that are electronic ignition.
These are called intermittent pilots. Do not attempt to light an intermittent pilot. If you have intermittent pilot and it doesn’t
work, call a professional. To tell if you have an intermittent pilot
look at the gas valve. It will not have a pilot position on the knob.
Now that you’re inside the panel check to see if the pilot is lit.
If it is, and your furnace still won’t start, then the best thing
to do is call a professional. Your problems are most likely beyond
the scope of your ability and really needs the attention of a person
trained in the repair of gas furnaces. If you decide to continue,
proceed at your own risk. If the pilot is not lit, you’ll need some
matches or a lighter. Preferably matches or a lighter with a long
reach. Once you have obtained a source of fire turn the knob to the
pilot position. Make sure there is not a gas smell present. Remember
natural gas is lighter than air and will rise. Always
read the manufacturers safety and operating instructions.

Propane or manufactured gases are heavier than air and tend to accumulate
in lower spaces. Many eyebrows, beards, mustaches, and hairdos have
been singed because the person lighting the pilot forgot this fact.
If you do smell gas, call a professional after you turn all knobs
supplying gas to your furnace to the off position. Okay back to lighting
the pilot. Turn the knob to the pilot position and press down on the knob. Light the match or lighter and place the flame at the pilot.
The pilot should light. Continue holding the knob down for about
a minute. After the minute goes by release the knob. The pilot should
remain lit. If it doesn’t, try lighting it again. If after several
attempts at lighting the pilot and it refuses to stay lit, call a
professional. You most likely need a new thermocouple or thermopile
depending on whether your pilot system is powered by either a thermopile
or thermocouple.

In the flash presentation above, a flame is burning continuously on
the tip of a thermocouple. As long as the flame is present on the tip
of a properly functioning thermocouple, the primary valve (inside the
gas valve) will remain open. If the flame goes out or the thermocouple
malfunctions, the primary valve will close off rendering the valve
inoperable and preventing any gas from escaping.

Modern Electronic Furnaces

The next step up from the standing pilot furnace is the electronically
controlled furnaces. These furnaces are more efficient than the standing
pilot furnaces but more complex in design. There are two types of electronic
furnaces: the intermittent pilot and the hot surface ignition furnaces.
While the two are different they both offer higher efficiencies and
are both controlled by solid-state circuit boards. Many of these furnaces
also have higher efficient heat exchangers. When the intermittent pilot
or hot surface ignition controls are combined with improved and more
efficient heat exchangers, the result is a furnace that can be 80 percent
or more efficient versus the older standing pilot furnaces which average
only 60 to 70 percent efficient.

Intermittent Pilot

 

The intermittent pilot furnace, upon a call for heat
(when the thermostat closes), will go through a trial for ignition.
(Note that the spark generated in this process can exceed 10,000 volts).
When a pilot flame is proven (normally through
flame rectification) the electronic module or circuit board sends
a signal to the main valve, in the gas valve, to open. The pilot
lights the main burner and it burns until the thermostat is satisfied.
When the thermostat is satisfied, the electronic module or circuit
board stops all ignition processes including the pilot.

Hot Surface Ignition

The Hot Surface Ignition Furnace has no pilot light.
It lights the burners direct. Therefore it is also referred to at times as Direct
Ignition. The igniter is made of silicon-carbon and glows red hot
when power is applied to it. The igniter is positioned above the
burner. Upon a call for heat, the furnace enters a sequence of operation.
Normally, after the purge cycle, power is applied to the igniter.
It glows red hot the gas valve opens allowing gas to flow. When the
gas makes contact with the igniter, ignition occurs. Once flame is
proven (usually with flame rectification), power to the igniter
is discontinued. The burners continue to burn until the thermostat
satisfies when the furnace goes into shutdown mode and shuts itself
down until the next call for heat.

Efficiency Defined

The percentage of efficiency as described here means that if a furnace
is 80 percent efficient then 80 percent of the heat it produces is
usable heat beneficial to the home and the other 20 percent is vented
into the atmosphere through the flue with the noxious gases that are
a result of the combustion process. Thus, the higher the efficiency
of a furnace the lower the temperature of the flue gases simply because
much of the usable heat produced by the furnace is used in the home
instead of vented into the atmosphere. This causes two separate functions
that must be overcome by mechanical means.

Number one, since the temperature of the vent gases is negligible
and gas typically contains approximately five percent moisture content,
the moisture is condensed through the process of combustion and needs
a place to drain. Normally, this drain is tied into the same drain
that drains the Air Conditioning condensation but could be drained
in another location.

Number two, because so much heat is removed and used in the home,
the pressure or force needed to exhaust the flue gases is too small
to force the noxious gases outside. This is the main reason why all
high efficiency furnaces have induced draft motors attached to them.
The inducer motor forces a draft through the entire system from the
beginning of the combustion process to the end where the noxious gases
are exhausted.

Modern electronic furnaces are more efficient because
you don’t
need to keep a pilot light burning 24/7 and there has been major changes
made in heat exchangers. Changing your current furnace from a standing
pilot furnace to a modern electronic furnace can make a difference
in your comfort and the amount you pay on your fuel bill next winter.

Characteristics and Behaviors of the Furnace Flame

The Flame that your furnace or boiler produces can effect the performance
and efficiency if it is not properly burning the fuel. A professional
HVAC Technician will have high tech tools so that your furnace can
be tuned to where the mixture, fuel and air, is proper ensuring the
furnace is getting the maximum amount of efficiency possible. This
is super important considering that the cost of fuels, whether it is
natural gas, propane, or oil, is continually rising.

The first test that can be performed is simple and requires no tools,
but does require a knowledge of what a proper flame should look like.
Natural Gas should have blue flame with a very minimum amount of yellow
tips on the top of the flame. Too much yellow tips would mean there
is not enough primary air or a combination of some other problems where
a simple adjustment can be made to correct the problem and get the
most out of the combustion problem. Problems other than yellow tipping
are rollout, flashback, lifting flames, and floating flames. All these
problems should be corrected to get the most out of your furnace or
boiler.

The next test that can be performed is the combustion analyzer test.
An expensive tool must be used for this test. An electronic device
that is capable of reading and analyzing several processes of combustion
can give the technician clues about any potential problems so that
some sort of action can be taken to correct it. A combustion analyzer
will tell the technician the stack temperature, carbon monoxide level,
carbon dioxide level, and oxygen levels in the exhaust gases leaving
the furnace. This test should also be done in conjunction with a
draft pressure test. It is important that all the byproducts of the
combustion process are exhausted outside the home. A draft test can
determine this will happen. A visual test using a mirror can also
be done to ensure there are no blockages of the chimney or the flue.
All the byproducts of the combustion process are analyzed and measures
taken to correct any abnormal readings by making adjustments according
to manufacturers recommendations.

Finally, the last test that can performed is a gas pressure test.
These pressures are different from one furnace or boiler to another
and from natural gas to propane to oil. Propane and Natural Gas are
measured in water column inches using a manometer. It is important
that the proper fuel pressures are present in the furnace or boiler
not only for efficiency purposes but also for complete combustion. Annual combustion testing is especially important for oil burners.</

All these tests can be performed by a qualified HVAC technician and can
make a big difference in the amount you pay for the heating fuel you
use over the colder months.

Condensing Units

The condensing unit is a simple yet technical piece of equipment. It sits out in the back
(or side) of your house and kicks on and off almost by itself. At least it seems that way to
most people. In this box made of sheet metal, is the heart of your cooling system. Or for those
with a heat pump, it is the heart of your heating and cooling. The condensing unit houses the
compressor or the heart of your system. It is the pump that is moving heat to the outside and
bringing the refrigerant (which absorbs the heat) to the inside of your home. Vice versa for a
heat pump in the winter. For those of us inside the heating and
cooling business who work on these units, we understand them to be the transferers of heat.
This transferer of heat, the compressor, is hermetically sealed and non-servicable. There is not
much you can do with a burned up compressor except replace it with a new one. However, there is
much you can do to maintain the equipment to give it a longer than average life and keep it
running as smoothly and efficiently as the day it was new. Other components inside the
condensing unit include the coils, the outdoor fan motor, and several controls.

Checking the Condenser Fan Motor
In late winter or early spring it is a good practice to check the condenser fan motor to make sure
it turns. Unplug or turn off the condensing unit at the disconnect and then set the thermostat to cool.
Go back outside and restore power to the condensing unit. Watch the condenser fan motor to make sure
it turns. The fan should be blowing plenty of air up. If the motor fails to start it is recommended
that it be replaced. There is probably a bearing going bad in the motor. Whatever the reason
there is no need to take chances having this motor fail and cause problems or damage the
compressor. If the condenser fan motor fails on a hot day, the unit stops cooling and the pressures
in the condenser rises until a high pressure switch (not all units are equipped with high pressure
switches) trips or the compressor overload shuts the compressor down. There is a possibility, with a failed
condenser fan motor, that the compressor fails for good never to run again. A condenser fan motor is
a lot cheaper than a compressor. Make sure the condenser fan motor is turning or running before
the hot weather arrives.

The question you are probably asking now is “What can I do to keep it running smoothly and
efficiently?” First you can keep the coils clean of grass, dirt, and mud. Over time, these things
build up inside the coils and block the coils. This accumulation of debris reduces the designed
surface area of the coils. Reducing that surface area causes the compressor to work harder
because there is less heat being exchanged from the coils to the atmosphere. The less heat
being displaced to the outside air the more heat that stays inside the unit and the refrigerant.
This causes the pressures to rise inside the unit. For the typical AC or heat pump the pressures
should not exceed 300 psig on the hottest day of the year. (Recent HFC refrigerants out on the
market operate at higher design pressures.) If your unit has dirty coils and the thermometer
outside is above 70 degrees then your unit is most likely running at a higher pressure than it
is designed to run at. The solution is to clean the coils.

Before you drag the water hose over to the unit and start spraying, you’ll want to secure the
unit. This begins at the thermostat and ends at the disconnect box located at the unit. Turn the
thermostat to the off position and pull the plug inside the disconnect box. Some disconnects have
a switch like a circuit breaker located inside them. Turn the power off.

After the power is off and the unit is secure, break out the water hose with a good nozzle
that will allow you to spray water at a high pressure. A little soap will help clean the dirt
and other debris off the coils also. Apply the soap and let it soak for a few minutes. Then
spray the coils. Be careful not to use too much pressure as you may bend some of the fins
that surround the coils. For best results, it will help if you spray the water from the inside
of the coils out. This may require you to take the top of the unit off. If you are not
mechanically inclined do not attempt this procedure. Simply spray all the dirt and debris off
the coils as you can possibly spray off.

Delay Timers and the Compressor

Air Conditioners are big refrigerators. Air Conditioners
use the refrigeration cycle to transfer heat from a place where it is
not
wanted to a place that makes no difference. The heart of any air conditioning
or refrigeration system is the compressor which pumps the refrigerant
through the system. The following diagram will help explain the refrigeration
cycle. When the refrigerant leaves the compressor it is compressed
and therefore a higher pressure than it was before it entered the compressor.
This pressure remains constant (give or take under certain conditions)
until it passes through the metering device where the pressure and
temperature are reduced. This low pressure remains constant (again
give or take under certain conditions) until it again reaches the compressor
and is compressed again. When you turn the air conditioner off these
pressures equalize within five minutes. The equalized pressure is often
referred to as static pressure to HVAC professionals. The high side
pressure on a hot day can be as high as 300 psi in some systems. If your
system is not equipped with a delay timer and you turn the system on
within five minutes of turning it off, the compressor must start against
that higher pressure. That is not good for the compressor and could
possibly damage it. The air conditioner should not be started unless
the system is at the static pressure. I have responded to calls where
the
unit was not equipped with a delay timer and the system was inadvertently
started before the pressures were allowed to become static. Often the

compressor is locked up, the capacitor is shot, a fuse is blown, the
compressor is damaged mechanically or electrically beyond repair, or
a
combination of any of these things mentioned.

Compressor
Mechanics

If the homeowner is lucky, the only thing wrong is the
capacitor or fuse. The capacitor for your compressor can be replaced
for approximately $10.00 to $30.00 (depending on the microfarad rating)
plus the service call. If the compressor is locked up there is a chance
that it can be unlocked (note the word chance). A hard start kit and
a good rap with a hammer can sometimes do the trick. If this doesn’t
unlock the compressor then you will have to replace the compressor or
the unit. It is often in the homeowners best interest to replace the
condensing unit. Before this happens to you, call the company you often
deal with to maintain and repair your HVAC system(s). Ask to speak with
the service manager or technician that has worked on your equipment.
Ask them if your unit is equipped with a delay timer. They should be
more than happy to answer your question, and if they are
not sure check to see if the unit is equipped with a delay. You
may want to have the model number, serial number (for both the condenser
and air handler), and type of thermostat you have. Most modern digital
and programmable thermostats have delay timers built into them.

Programmable Thermostats

Programmable thermostats can save you more than ten percent on
your homes utility bills. For that reason a programmable can pay for
itself within a few years depending on the type and expense of the
type you purchase. Among others, you can expect good quality from Honeywell products.
If you are or someone else is at home most of the day and night,
you most likely do not need a programmable. Programmables are
designed for the family on a regular schedule. Those that wake at a
certain time, leave the home at a certain time, return at a certain time,
and go to bed at a certain time (on a regular basis), will benefit
from a programmable thermostat. Read the following information and
see if it applies to you for your benefit.

How the programmable thermostat
works

You have four settings on the programmable thermostat.

• Wake – this is the setting you want the temperature to be
  at when you wake. If you wake at 6 a.m. you probably want to set the wake time
  and temperature for 5:30 a.m. and whatever the desired temperature is for you.
• Leave – this is the time the last person leaves the home
  for the day. If that person usually leaves at 8 a.m. then the thermostat
  can be set to change the temperature
  at 7:30 a.m.
• Return – this is the time that the first person arrives
  home for the day. If that person arrives home at 4 p.m. then the
  time and temperature can be set at 3:30
  p.m. That way when the person arrives home, the home is at the desired
  temperature.
• Sleep – this is the time when everyone goes to bed for the night.
  If everyone is in bed by 10:00 p.m. then the thermostat can be set to
  change the temperature to a lower setting
  for the night.

Most programmable thermostats have settings for
both the weekdays and weekends so on Saturday and Sunday you can
tailor the settings according to your comfort level and usual schedule
for those days. All of them have options to over-ride the program for
manual settings and an additional benefit to owning a programmable is
that most are equipped with a compressor delay to protect your compressor
from short cycling.

Installing a New Thermostat

The first thing you should do before changing the thermostat is to select
the proper thermostat for your system. If you are retired or if someone is at home
most of the time during the day you most likely do not need a programmable
thermostat. If this is the case the only benefit you will get from a
programmable is at night.
Once you have made the selection you can proceed to the next step.

Thermostat Installation Advisory: If you decide
to install your own thermostat you do so at your own risk. There are
many incidences where the homeowner installed their own thermostat
and were successful. There are also many incidences were the homeowner
was unsuccessful. The ones that were unsuccessful wasted part of their
day, ruined a thermostat or two, and caused the malfunction of an integral
part of their system. That is not mentioning the fact that they ended up
calling a professional HVAC Technician to fix the problems caused by
improperly installing a thermostat. The ones that are unsuccessful end up paying
three to four times what they would have paid had they called a professional
in the first place. Factor this in to your decision and if there is
any doubt call a professional to install the new thermostat.

• Get the tools
  together that you will need to do the job right. You will need:
  • A small straight-slot (or flathead) screw driver
  • A small phillips screw driver
  • A pair of needle nose pliers
  • A utility knife or wire strippers (for small wire)
  • Plastic wall anchors (sometimes provided with the thermostat)
  • A drill with a bit to make the holes for the plastic wall anchors
  • A small level
  • Two pencils or pens
  • A small paper bag and some masking tape (tape the bag
    below the area where the thermostat is so that any trash or dust
    will fall into the bag and not onto the floor)
  • Some touch up paint
  • Clean hands (don’t do a great job changing the thermostat and
    leave all those prints all over the wall)
  • Plenty of light

• Turn the power off to the unit at the circuit
  breaker or the emergency cutoff switch. After doing that make sure
  the power is off by turning the thermostat to the on position
  and going to the unit to make sure it is not on. Not all circuit
  breakers are labeled correctly and not all emergency switches are
  hooked up. Just make double sure that you have killed power to the
  unit not only for your safety but also to keep from blowing the
  transformer.

• Pull the cover off the front of the thermostat.
  If it is a mechanical thermostat there should be a little adjuster tab
  in the center of it. This is your heat anticipator. It should have
  numbers ranging from 1.5 to .1. Take note of this setting and remember
  to set the new thermostat to this same setting if you are replacing a
  mechanical thermostat with another mechanical thermostat. You probably
  want to do this now before you proceed further. If you are replacing
  a mechanical with a digital, the digital should set itself automatically.
  If not read the instructions on the new thermostat for instructions on
  how to set the anticipator. This is very important. An improperly set
  anticipator will cause your heater to run improperly. The thermostat
  is also equipped with a cooling anticipator. Cooling anticipators are
  most often on the sub-base and are non-adjustable.

• Unscrew the thermostat from the sub-base. Take
  note of each wire. The following list should match the wires and terminals
  on your thermostat.
  • Red to the RH or RC terminal with a jumper wire
    between RH and RC. Or Red to the R terminal which is shared with both
    the heating and cooling. It has an internal jumper built in to the
    sub-base. The red wire is the hot wire. All other wires are common wires.
  • Green to the G terminal. This is for the fan.
  • Yellow to the Y terminal. This is for air conditioning.
  • White to the W terminal. This is for heating.

  These are the four wires that
  you need to control the heat, cooling and the fan. If
  the colors of the wires do not match the colors described here
  make sure you mark the wires with masking tape. If there are more
  wires that are not hooked up don’t worry. This is common. Thermostat wire
  comes in many different varieties and the contractor who installed the
  system probably used 5 wire or 8 wire thermostat wire. They used what
  they needed and simply twisted or cut the other wires off.

• Remove the wires from the terminals on the sub-base.
  The power should be off so you shouldn’t have to worry about being shocked.
  Be careful not to let the wires fall back into the wall. Sometimes there
  is just enough wire to reach the terminals and that’s it. Try pulling the
  wires a bit to see if there is more wire behind the wall. Most of the time
  there is some slack and you can pull the wire out more. Unscrew the sub-base
  from the wall while holding the wires. When you get the sub-base off wrap the wires
  around the pencil or pen. This will keep the wires from falling back into the wall.

• Get the new sub-base and compare it to the old one.
  Hold it up to the wall in the position you want it. Is the old paint
  that was covered by the old sub-base going to be covered by the new
  sub-base? If any of the old paint is going to show you may want to make
  some touch ups now. After finishing with that, put the new sub-base back
  on the wall in the position you want it. Make sure it is as level as possible.
  You can use a level to do this.
  (This is very important especially for mechanical
  thermostats. It must be level or the mercury switch will not keep the
  proper temperature settings in the house. Make sure it is level.)
  Mark the new holes through the sub-base where the screws will go into the
  wall to fasten the sub-base.

• It is important in this step to have the proper drill bit
  size for the size of wall anchors you have. Some wall anchor kits come with
  a bit in them. We recommend the wall anchor kits with the bits in them
  because it is the perfect size drill bit for the anchors. The bit should be
  slightly smaller than the anchor. If the bit is bigger the wall anchor will
  not hold and the possibility exists that the thermostat will fall off the wall.
  Drill the mounting holes you made for mounting the sub-base. Insert the wall anchors
  and push them hard with your thumb. Approximately 1/16th of an inch on the lip of
  the anchor will remain sticking out of the hole. If it is more than that use the
  butt-end of the screw driver and push it in until just the lip of the anchor
  remains visible.

• Undo the wires from the pencil or pen and run them through
  the center of the sub-base. Insert the screws and screw them only snug tight.
  Get the level and make sure the sub-base is level. When you are sure
  that it is level, tighten the screws. Be careful not to allow the sub-base
  to move when you are tightening the screws.

• Using the color code of the wires (or if they didn’t match,
  the color markings you made with masking tape), attach each wire to their proper
  terminal. Some people like to loop the wire around the terminal screws. This is
  not necessary. What is necessary is that the wires are attached to the terminals
  and they are tight. Additionally, make sure that none of the bare wire is touching
  anything except the terminal. Once the wires are attached you are almost finished
  completing the task of installing the thermostat. The hard part is over!

• Attach the thermostat to the sub-base. The screws for this
  are built in the the thermostat. Tighten these screws and check to make sure the
  heat anticipator is set to the same setting as the old anticipator setting.

• Attach the front cover to the thermostat and restore power.
  Start and check the heating, air conditioning, and with the heating and air
  conditioning off, the fan only sequence. All systems should be working properly
  at this time (if you did the task properly) and you are the proud owner of a brand
  new, properly installed thermostat.