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IQAir GC Series Room Air Cleaner

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Product Code: IQ-IQAIRGCSERIES

IQAir GC Series Model Options

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   GC VOC - best for volatile organic compounds
   GC MultiGas - broad spectrum odor and gas removal
   GC Chemisorber - best for formaldehyde removal
   GC AM - best for ammonia based compound removal

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PRODUCT DETAILS

EDUCATIONAL INFO

There are many portable air cleaner/purification systems in the marketplace today. Unfortunately, the consumer may become confused or misled by the various claims being made on air filter technology, filtration media, odor and chemical adsorbing capability and complete system performance. We believe indoor air quality is vital to health because we spend so much time indoors, therefore buying the correct air cleaner system is crucial. We don't confuse you by offering every air cleaner product made as most available products are ineffective and potentially harmful to your health. Our product line is the result of the review of detailed information on available portable air cleaner systems and technologies and in-depth discussions with product manufacturers.

CADR Testing

Some product manufacturers use a standard called "Clean Air Delivery Rate", also referred to as the CADR test by the Association of Home Appliance Manufacturers, to make an effectiveness claim for their portable air cleaners. The CADR test lacks the detailed information and test protocols to allow a consumer to make an informed decision when purchasing an air filter system to meet their specific needs. When purchasing a portable air filter system for your home, you want to know that the system will provide consistent performance over the life of the filtration media, the efficiency of the system at removing microscopic particles and if the unit is emitting any harmful by-products. The CADR test fails to inform consumers in these critical areas. The CADR test alone should not be used to evaluate a Portable Room Air Cleaner. Here is why:

Test Duration

The true test of air filter media is how it performs over time. Most high quality air filter systems are designed to last 2-5 years before requiring filter replacement. The CADR test takes a brief 20 minute snapshot of filter performance when an air cleaner is new. Some filtration media become more efficient over time and some filtration media become less efficient with continued use. The brief test period of the CADR test does not indicate the performance of a system over time which can be significantly different than when the product is new. The CADR Air Cleaner Certificate Label states the test results "represent performance that can be expected within 72 hours of operation. Subsequent performance may vary with use." Here are two examples.

Poorly designed air cleaners may perform well when new, but as the filters get particle build-up, the static pressure of air trying to go through the filter increases. Air will travel in the direction of least resistance, causing air to bypass the filter and release particles back into the room air.
Some air cleaners use technology with electrostatic charges to attract and capture particles. As particles cover the charged filter media or plates, this electrostatic charge will diminish rapidly and particles will no longer be attracted to the particle capturing mechanism. These types of air cleaners lose substantial efficiency quickly.

Filter Efficiency

The CADR test does not test filter efficiency. This test is a factor of air flow through the air cleaner and filtration. An air cleaner unit with a high air flow rate and low filter efficiency can score the same on the CADR test as a filter system with a low air flow rate and high filter efficiency. Both scenarios are not acceptable. The efficiency of an air cleaner system at removing a particular particle size is unknown with the CADR test. The CADR test uses particles that range in size from 0.10 to 11 microns. Considering that 90% of all particles are below 0.3 microns, which are the most troublesome to health, it is important to know the system efficiency of an air cleaner at trapping sub-micron particles. The CADR test does not test for HEPA efficiencies, which is the capture of 99.97% of all particles down to 0.3 microns.

Particle Sizes

Large particles such as pollen and house dust allergens are heavy and settle out of the air quickly. Smaller particles remain suspended in the air for longer periods. These smaller particles may be problematic to individuals as they are the most difficult to dislodge from the lungs. Most new air filter systems can trap larger particles used in the CADR test, especially during the short 20 minute test period. It is more important to be concerned with low particle sizes. Air cleaner systems designed to capture low particle sizes will also trap larger size particles.

Air Cleaner Type

The CADR test does not test for microbiological control, odor and gas removal or whether the unit emits Ozone, a pollutant emitted by some air cleaners and considered toxic by the Centers for Disease Control and US Environmental Protection Agency. Some air cleaning technologies, such as Ionization, do not capture particles at all, they create an electrostatic charge on the particle so they are attracted to surfaces in a room. The CADR test will show that particles are removed from the air when in fact they are deposited on surfaces throughout a room. Most CADR rated air cleaners do not effectively reduce gaseous pollutants and odors.

Air Filter System Technologies

There are a variety of technologies used in room air cleaners including ionization, ozonation, electrostatic precipitation, ultraviolet light, air washing, incineration, mechanical filtration, photocatalysis, chemisorption and adsorption. Click for a brief review of the different Air Cleaner Technology in our Portable Room Air Cleaner Buyers Guide.

Air Filter System Guidelines

The performance of an air cleaner is dependent on numerous factors such as:

The amount of air flowing through it.
The type and efficiency of the filter media.
The air cleaner construction that affects particle escape around the filter media.
The size and amount of particles present in the air.
The rate at which the filter media losses it effectiveness.
The amount and type of gasses present in the air.
The quantity, depth and type of the gas adsorbent material.
The velocity of the air traveling through the gas adsorbent media.
The room conditions such as air temperature and humidity effecting the capacity of adsorbents to remove odors and chemicals.

Indoor Air Quality Health Effects

We spend up to 90% of our time indoors. Indoor air quality is critical for personal health. People who may be exposed to indoor air pollutants for the longest periods of time are often those most susceptible to the effects of indoor air pollution. Those at the greatest health risk are individuals with compromised immune systems, the chronically ill, the chemically sensitive, those suffering from asthma and allergies, the elderly and children. For example, children breathe more air than do adults relative to their body size and have greater metabolic growth requirements. Also, young children spend more time on the floor where there is an increased opportunity to inhale particles stirred up by activities. .

Indoor air pollution consists of toxic gases and/or particles that can harm your health. These pollutants can build up rapidly indoors to levels much higher than those usually found outdoors. This is especially true if large amounts of a pollutant are released indoors. Indoor air can reach pollutant levels 100 times greater than outside. Research by the California Air Resources Board, the EPA and others has shown that indoor levels of some pollutants such as formaldehyde, chloroform and styrene, range from 2 to 50 times higher than outdoor levels. Exposure to pollutants such as environmental tobacco smoke and radon occurs almost entirely indoors. For most of us, the amount of air pollution that we breathe is primarily determined by what is in the indoor air. While pollutant levels from individual sources may not pose a significant health risk by themselves, most homes have more than one source that contributes to indoor air pollution. There can be a serious risk from the cumulative and synergistic effects of these sources.

People may react differently to air pollutants, depending on factors such as age, preexisting medical conditions and individual sensitivity. Immediate effects can include headache, nausea, asthma symptoms, irritation to the respiratory system or skin, fatigue, and dizziness. Long-term exposure may cause cancer, heart disease, and respiratory disease.

Indoor Air Pollutants

For the purpose of discussing air purification and filtration, we can place pollutants into two categories:

Particles

This matter is composed of very small solid or liquid substances that are light enough to float in the air and also accumulate on household surfaces. These particles can include organic and inorganic substances and biological organisms.

The most common particulate matter can include:

Household dust from the breakdown of materials and fabrics
Animal dander
Skin flakes
Molds
Pollen
Tobacco smoke
Particulates from combustion of wood stoves and appliances
Heavy metals such as lead
Fibers such as from asbestos and insulation
Plant fragments
Bacteria
Viruses
Fungi
Insect body parts
Contaminated soil tracked in from outside

Particle size can determine the effect of the pollutants on health. Small respirable particles can penetrate deep into the lungs where they may stay a long time and cause acute (immediate) or chronic (long term) illness. One study, reported in the Los Angeles Times in April, 2003, "Air Particles Linked to Cell Damage" suggests that very small particles may bypass the body's defense mechanism, travel beyond the lungs and blood stream and penetrate deep inside cells to cause cellular damage that could lead to disease. Larger particles may not penetrate as deep as small particles but can cause allergic reactions and other health problems. Allergic reactions to particulates can include runny nose, watery eyes, sore throat, sneezing, coughing, skin rashes, asthma, headaches, upper respiratory discomfort, and an increased risk of developing an allergy.

Large particles can lead to reduced lung function, restricted breathing and an obstructed airway. Heavy metal exposure can lead to toxin levels in the bloodstream. These health effects from exposure to particulate matter in the air depends on the type and amount of particulate, the frequency and duration of exposure and the sensitivity of the individual.

Examples of various particle sizes:

Viruses 0.01 - 0.05 microns
Bacteria 0.3 - 3 microns
Smoke 0.01 - 5 microns
Cat Allergens 0.05 - 3 microns
Mold Spores 3 - 30 microns
Pollen 10 - 100 microns

Gasses

Gasses in the indoor air are developed from combustion and the release of chemicals into the air. There are hundreds of gasses that can be detected in the home.

Volatile Organic Compounds (V.O.C.'s) are the chemicals that are part of the products we use and are released into the air when the products are drying, aging and deteriorating. The most notable volatile organic compound is formaldehyde, a suspected carcinogen. Other V.O.C.'s exist in plastercizers, stabilizers, solvents and fillers incorporated into the conventional products in our homes such as pesticides, building materials, household cleansers, and personal care items.

Combustion Gasses come into the indoor air from poorly vented appliances, heaters and fireplaces, during cooking with open flame, vehicle exhaust from attached garages and if backdrafting should occur from pressure differentials inside and outside the home forcing air down your chimney flue and spilling combustion gasses into your indoor air. The combustion gasses include carbon monoxide, carbon dioxide, nitrogen oxides and various other compounds.

Radon is a radioactive gas which permeates out of the decay of radioactive rock and enters the home through the lowest level of the building, in water exiting plumbing fixtures, from the use of natural gas and in some building materials.

Controlling Indoor Air Pollutants

Source Control

Source control is a method used to eliminate the contributor to the indoor air quality problem. Usually the most effective way to improve indoor air quality is to eliminate individual sources of pollution or to reduce their emissions. We can provide sealed combustion appliances and heating systems to eliminate the potential of combustion gasses leaking into our homes. We can take out building materials that out gas toxic fumes or buy appropriate building materials and household products that do not emit dangerous volatile organic compounds. We can remove materials that contribute to the development of particulate matter that can become airborne and cause respiratory problems. We can use cleaning systems that eliminate mold and mildew and use household products that prevent the proliferation of allergens.

For example - Carpeting is susceptible to constant wear and the development of particulate matter. It also is a good breeding ground for a variety of allergens and biological contaminants and is known to outgas many volatile organic compounds. The removal of existing carpeting or the use of optional flooring materials will assist in source control of many potentially hazardous contaminants.

Ventilation

Another approach to lowering the concentrations of indoor air pollutants in your home is to increase the amount of outdoor air coming indoors. Indoor air may be exhausted to the exterior and/or less contaminated outdoor air is brought into the indoors. Good ventilation assists in the removal and/or the dilution of indoor air pollutants. Opening windows and doors, operating window or attic fans when the weather permits or running a window air conditioner with the vent control open increases the outdoor ventilation rate. Most home heating and cooling systems, including forced air heating systems, do not mechanically bring fresh air into the house. Local bathroom or kitchen fans that exhaust outdoors remove contaminants directly from the room where the fan is located and also increase the outdoor air ventilation rate. Ventilation is particularly important while you are involved in short-term activities that can generate high levels of pollutants. For example, painting, paint stripping, heating with kerosene heaters, cooking, or engaging in maintenance and hobby activities such as welding, soldering, or sanding. However, ventilation alone does little to control particulate matter and may be a problem when levels of pollutants in the outdoor air exceed indoor levels. A ventilation system can be combined with air filtration to control both particulate matter and gasses.

Air Purification

This method of controlling indoor air pollutants can handle both particulate matter and to some degree, gasses. It is important to understand the configuration of the air filter equipment to know its function and capability to handle particulate matter and gasses. An air filter unit can be part of the whole house heating/cooling system or an integral part of the whole house ventilation system. Portable HEPA Room Air Cleaners can be used to reduce/remove indoor air pollutants in living spaces when a whole house filtration system is unavailable or when meeting the specific needs of an individual such as in a nursery or an allergic individual's room.

The effectiveness of an air cleaner depends on how well it collects pollutants from indoor air (expressed as a percentage efficiency rate), the strength of the pollutant source and how much air it draws through the cleaning or filtering element (expressed in cubic feet per minute). A very efficient collector with a low air-circulation rate will not be effective, nor will a cleaner with a high air-circulation rate but a less efficient collector. Many available air cleaning technologies are ineffective and can potentially be hazardous to your health.

Some important steps you can take to reduce your indoor pollutant and allergen exposure in your home include:

Use a central vacuum system (exhausts outside) or portable sealed HEPA Vacuum Cleaners to prevent air particles and pollutants such as allergens from being dispersed into the air when cleaning.
Encase your bedding with Allergen Control Barriers that prevent dust mite proliferation in an area that you spend 1/3 of your day.
Wash bedding fabrics weekly in hot water (minimum 130° F).
Use surface treatments for Dust Mite Control, Animal Dander Control, Mold Control and Dust Control that will reduce your exposure to these allergens throughout the home.
Don't allow pets in the bedroom.
Reduce your exposure to chemical gasses and vapors with natural ingredient based Household Cleaners and Personal Care Products.
Reduce your exposure to airborne particulates with the use of a portable HEPA Air Purification Unit or a central air filtering system.
Increase low moisture levels in the home and prevent the release of mold into the air when using humidifiers by using Germ-Free Humidifiers that kill mold and bacteria before moist air is released into the room.
Remove the build-up of molds and bacteria and clean your home without irritating chemicals with a home Vapor Steam Cleaning System.
Control excess indoor humidity with adequate ventilation and the use of dehumidifiers and air conditioners as necessary.

Sources and Potential Health Effects of Indoor Air Pollutants

Pollutant	Major Indoor Sources	Potential Health Effects*
Environmental Tobacco Smoke	Cigarettes, cigars, and pipes	Respiratory irritation, bronchitis and pneumonia in children, emphysema, lung cancer, and heart disease
Carbon Monoxide	Unvented or malfunctioning gas appliances, wood stoves, and tobacco smoke	Headache; nausea; angina; impaired vision and mental functioning; fatal at high concentrations
Nitrogen Oxides	Unvented or malfunctioning gas appliances	Eye, nose, and throat irritation; increased respiratory infections in children
Organic Chemicals	Aerosol sprays, solvents, glues, cleaning agents, pesticides, paints, moth repellents, air fresheners, dry cleaned clothing, and treated water	Eye, nose, and throat irritation; headaches; loss of coordination; damage to liver, kidney and brain; various types of cancer
Formaldehyde	Pressed wood products such as plywood and particleboard; furnishings; wallpaper; durable press fabrics	Eye, nose, and throat irritation; headache; allergic reactions; cancer
Respirable Particles	Cigarettes, wood stoves, fireplaces, aerosol sprays, and house dust	Eye, nose and throat irritation; increased susceptibility to respiratory infections and bronchitis; lung cancer
Biological Agents (Bacteria, Viruses, Fungi, Animal Dander, Mites)	House dust; pets; bedding; poorly maintained air conditioners, humidifiers and dehumidifiers; wet or moist structures; furnishings	Allergic reactions; asthma; eye, nose, and throat irritation; humidifier fever, influenza, and other infectious diseases
Asbestos	Damaged or deteriorating insulation, fireproofing, and acoustical materials	Asbestosis, lung cancer, mesothelioma, and other cancers
Lead	Sanding or open-flame burning of lead paint; house dust	Nerve and brain damage, particularly in children; anemia; kidney damage; growth retardation
Pesticides	Products used to kill pests such as insecticides, termiticides and herbicides. Also lawn and garden products.	Irritation of eye, nose and throat. Damage to the central nervous system. Increased risk of cancer
Radon	Soil under buildings, some earth-derived construction materials, and groundwater	Lung cancer
*Depends on factors such as the amount of pollutant inhaled, the duration of exposure and susceptibility of the individual exposed.