UDC 614.844
The subject of the article is modern fire extinguishing technologies based on compression foam. The purpose of the study is to study the means of obtaining and the prospects for using compression foam in firefighting. A diagram of the production of compression foam is presented (the foam concentrate acts as a foaming agent) and a diagram of an autonomous installation for the production of compression foam. It is noted that one of the significant advantages of CAFS is the ability to create a finished product that matches a specific type of fuel or a specific situation. The characteristics of the SmartCAFS product have been defined. A typology of the use of compression foam depending on the type of incident is presented. The results of fire resistance tests of various foams are presented. Fire extinguishing systems based on the use of compression foam are becoming widespread because this technology does not require large amounts of water, allows it to quickly cover large areas, minimizing any damage caused and the risk of further spread of the fire. In addition, compressed air foam systems can be installed in a much smaller footprint than alternative solutions, significantly reducing infrastructure requirements and costs. The prospects for the development of CAFS systems lie in their integration with digital technologies
foam, fire, compression, coating, flow, water, fuel, air
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