History

Aftermarket company, K&N Engineering first offered air intake systems in the late 1980s. Those intakes consisted of rotationally-molded plastic intake tubes and a conical, cotton gauze air filter. In the late 1990s a proliferation of intake manufacturers such as AEM, Airaid and Volant entered the fray. In addition, oversea manufacturers imported their designs lending to the popularity of Japan domestic market (JDM) air intakes in sport compact markets. K&N and many of the other intake companies now offer intake systems in metal tube designs, allowing a greater degree of customization (the tubes can be powder-coated or painted to match a vehicle).

Mechanics

All cold air intakes operate on the principle of increasing the amount of oxygen available for combustion with fuel. Because cooler air has more density for a given volume, cold air intakes generally work by providing cooler air from outside the hot engine bay. However, the term "cold air intake" is often used to describe other methods of increasing oxygen to an engine, which may even increase the temperature of the air coming into an engine.

Some strategies used in designing cold-air intakes are:

  • increasing the diameter of the air intake, allowing increased airflow.

  • smoothing the interior of the intake to reduce air resistance.

  • providing a more direct route to the air intake.

  • tuning the length of the intake to provide the most airflow at certain RPMs.

  • using a more efficient air filter

Application

Intake systems come in many different styles and can be constructed from plastic, metal, rubber (silicone) or composite materials (fiberglass, carbon fiber or Kevlar). Due to the limited time air actually remains inside the intake tubing, the materials often do not impact a kit's ability to deliver cool air.

The most basic cold air intake replaces the stock air box with a short metal or plastic tube leading to a conical air filter, called a Short ram air intake. The power gained by this method can vary depending on how restrictive the factory air box is. The placement of the filter is usually directly in the engine compartment. The overall benefits depend on the specific application. Power may be lost at certain engine speeds, only to be gained at others. Because of the increased airflow and reduced covering, intake noise is usually increased. This effect is usually amplified on applications where a resonator, a part intended to reduce intake noise on some vehicles is replaced by the intake.

Better designed intakes use heat shields to isolate the air filter from the rest of the engine compartment, providing cooler air from the front or side of the engine bay. Carbon fiber can be used for the piping instead of metal, lowering weight and insulating the air from the engine bay in some cases. Carbon fiber and other advanced composites (such as Kevlar) come at significant costs and are often more aesthetic rather than functional (unless the application is a serious race vehicle).

The most extreme designs, sometimes referred to as Complete Cold Air (CCA) intakes, route air from outside the engine bay, usually from the wheel wells (although an extremely poor choice, as the air pressure is low), front grill (high air pressure), or a hood scoop (moderate air pressure). The intake can be placed such that the forward motion of the car pressurizes the air coming in, creating a ram-air intake. These intakes often require additional modifications and can require body modifications or replacement panels, such as a replacement "ram air-style" hood. Complete Cold Air intakes are able to convert to short ram intakes. During the winter season, you can convert your cold air into a short ram intake.

The best cold-air intakes are optimized for a specific engine application, providing increased airflow at ambient temperature and raising power at all engine speeds. However custom air intakes can be created using mandrel bent air intake tubes and aftermarket air filters if there is not currently an air intake on the market for your car or truck. According to SFX Performance, Fuel savings of up to 4 miles per gallon and a gain of 16 horsepower to the wheels can be achieved for most V6 cars.

When using a cold air intake, there is a potential risk when driving in the rain. This is often referred to as "hydro lock", and according to a scientist that once said: "Say it's raining cats and dogs and you're out for a spin in your car. Normally you'd love to rip through puddles without thinking twice, but because your engine is now getting air from inside your bumper you have to be careful. If your engine manages to suck up any amount of water through the intake and into the engine you will probably have little to no horsepower left. In other words, be careful." So, it is important to take the necessary precautions when using a cold air intake so you do not end up getting water in your engine. This may include installing a water shield in your intake or not driving in the rain at all. It is also notable that less damage will occur from water getting in the engine on a rotary engine car, as opposed to a piston engine car. Some cold air intake manufacturers now have hydro-shields which act as water barriers that go over your filter however there can be some minor loss in performance. One particular manufacturer AEM makes air bypass valves that are installed in the cold air intake pipe to prevent hydro locking of the engine