When the air goes into the air conditioner, what does it look like?

The air conditioners in our homes and offices are a product of the same technology used to power most cars, airplanes and other modern machinery.

The problem with air conditionering is that, if it’s not properly maintained, it can leave a nasty odor in your home and the air conditioning in your workplace.

As the technology improves, so does the problem.

But, until now, no one has really understood how air conditioning works.

What we know is that a device known as a “fume absorbing membrane” (FAM) is used to absorb odors and pollutants from the air that enters the unit.

In the past, air conditioning companies have used this membrane to control the amount of air in the unit to prevent air from entering the unit through vents.

However, manufacturers are now testing a new membrane that they hope will replace this type of air conditioning membrane in air conditioning units.

Researchers at the University of California, San Diego, have been developing a new type of membrane that works to absorb air and keep it out of the air system.

This new type has a flexible shape and can be attached to air condition units, so it can be used to cool them.

It is hoped that the new membrane will be a more effective way to control air pollution than the existing membrane, and will provide a more efficient way to regulate the amount and type of pollutants that enter the system.

“The goal is to have a membrane that can control a much broader range of pollutants than air condition, and we have been working on that,” says Michael Ebert, an associate professor of mechanical engineering at UC San Diego.

“Our goal is not to replace the membrane but to improve the membrane.”

A membrane is a thin, flexible membrane that surrounds an air conditioning unit.

The membrane is attached to the air condenser, or in this case, the air source, using ducting.

This ducting is then attached to a mechanical system that is usually the unit itself.

The mechanical system is connected to a controller that controls the amount the air is allowed to circulate.

“These systems have to be reliable, efficient and cheap, so we’re trying to make them as low-cost as possible,” Ebert says.

The new membrane is designed to use a new technology called polyurethane foam, which is a polymer made of an ethylene glycol polymer.

This material is relatively inexpensive, easy to work with and is extremely stable.

The polyurethal foam membrane is very flexible and can handle large amounts of air without any problems.

Researchers have been testing it in air condition rooms.

It has been tested to work in temperatures of up to 120 degrees Fahrenheit, so this is a technology that will be used in homes and buildings as well.

The researchers hope to use this new membrane in the next two years to make a new kind of air condition control device, called an “interactive air conditioning control system,” or IACCS.

The IACS is a system that has been developed by researchers at the U.S. Department of Energy’s Lawrence Berkeley National Laboratory, which has the patent for the technology.

This membrane is made up of three layers of polymer, each of which is about one millimeter thick.

The polymer layers are attached to each other and are then connected to the controller by a series of small holes.

The holes are small enough to allow air to pass through.

The pores in these layers also allow air that is more or less humid to pass.

The foam inside the membrane is then applied to the unit and connected to an air filter.

The filter is used as a way to collect and store the moisture.

The material that is attached is a type of polyuretha, which means it is made of two types of materials, ethylene and polypropylene.

Polypropylene is a common material used in the construction of electronics, so Ebert hopes to create a membrane made of this material, too.

“It’s not just a polymer, it’s an organic material, and that’s what we’re going for,” Eberts says.

“We have a lot of experience with the polymer-organic materials.

We’re using that knowledge to make an efficient membrane that’s very flexible, which allows it to absorb heat without causing a problem.”

The researchers have been looking into how the new polymer membrane would react to air and what it would do when it is placed inside an air condition unit.

They have been using a series in which they applied a small amount of the membrane to the outside of the unit, then heated it up.

The heat produced in this process produced steam that was able to flow through the membrane.

They then applied the same amount of membrane to an inside air condition room.

The results showed that when the membrane was heated, the heat that was produced did not have a significant effect on the polymer.

However it was noticeable that the heat was starting to warm the material inside the chamber, so they decided to increase the temperature inside the room. When