The Compressed Air Foam System, or CAFS, is a technology used to generate compressed air foam. Unlike traditional methods, where the foam concentrate is mixed into the water stream and then aerated using a nozzle and ambient air, CAFS mixes all three components (air, water, and foam concentrate) in a mixing chamber. This approach differentiates CAFS from conventional foam generation techniques, such as the free intake of air typical for heavy foam nozzles or air blending with fans as seen in light foam generators. In CAFS technology, the mixture of all three media (air, water, and foam concentrate) occurs in a mixing chamber. The independent control of all three media streams allows for highly flexible manipulation of the foam properties. Foam can be made wet, soft, and flowing, or dry, stiff, and highly adhesive.

Wetting agents are additives mixed with water in very small amounts (<0.5%) that significantly enhance the extinguishing effect of the water. Wetting water has a greatly reduced surface tension, which decreases the interfacial tension between water and solid materials. This breaks the droplet form of the water, creating a thin, spreading film of water on the surface of the burning material.

Inside Air Foam (IAF) is generated with special foam concentrates and light foam generators in enclosed spaces, such as warehouses or engine rooms. IAF systems use the hot, combustion-product-laden gases from the fire event for foaming. This immediately binds the smoke gases and cools the surrounding atmosphere. This firefighting method does not require an external air supply or exhaust openings, making the structural requirements for IAF systems potentially more cost-effective compared to conventional light foam systems.

This method places specific demands on the extinguishing agent, as heat, smoke particles, acidic combustion gases, and other pyrolysis products are highly destructive to foam. Therefore, only special IAF foam extinguishing agents can be used for this process; conventional foam agents are not suitable. The suitability of foam extinguishing agents must be proven for each project with the respective fuels through a hot test. Special medium-expansion foam generators, developed for industrial fire protection, operate with approximately 25- to 35-fold expansion in the lower medium-expansion foam range and can achieve throw distances of up to around 35 meters.

High-expansion foam has an enormous foam volume yet is very light. It contains a very high air content, resulting in coarse bubbles and a particularly "dry" appearance. Due to its large volume and low weight, high-expansion foam cannot be "thrown." Its extinguishing effect is primarily based on its separation, insulation, and displacement effects. These extinguishing effects are further enhanced by the relatively high foam destruction rate (bursting of the foam bubbles). This releases tiny water droplets, which immediately evaporate due to the high combustion temperatures, forming 1,700 times their volume of water vapor. The surrounding air is cooled accordingly. High-expansion foam is produced using high-expansion foam generators.

Depending on the expansion ratio, "wet" fine-bubbled foam or "dry" coarse-bubbled foam with low weight and high volume is produced. The extinguishing effect is primarily based on separation, cooling, and displacement effects. Medium-expansion foam is generated using medium-expansion or combination nozzles. In the nozzle, the foam concentrate solution mixes with the induced air, impacts a screen mesh installed in the nozzle under pressure, and is further foamed. This process quickly produces a large amount of foam, which can be built up to a considerable height.