A fine-water-mist fire-suppression device developed at John H. Glenn Research Center can be discharged uniformly in any orientation via a high-pressure gas propellant. Research in recent years has shown that fine water mist can be an effective alternative to ozone-destructive Halons.
Rechargeable system discharges 100 percent of its contents regardless of extinguisher orientation.
A fine-water-mist fire-suppression device has been designed so that it can be discharged uniformly in any orientation via a high-pressure gas propellant. Standard fire extinguishers used while slightly tilted or on their side will not discharge all of their contents. Thanks to the new design, this extinguisher can be used in multiple environments such as aboard low-gravity spacecraft, airplanes, and aboard vehicles that may become overturned prior to or during a fire emergency. Research in recent years has shown that fine water mist can be an effective alternative to Halons now banned from manufacture.
Currently, NASA uses carbon dioxide for fire suppression on the International Space Station (ISS) and Halon chemical extinguishers on the space shuttle. While each of these agents is effective, they have drawbacks. The toxicity of carbon dioxide requires that the crew don breathing apparatus when the extinguishers are deployed on the ISS, and Halon use in future spacecraft has been eliminated because of international protocols on substances that destroy atmospheric ozone. A major advantage to the new system on occupied spacecraft is that the discharged system is locally rechargeable. Since the only fluids used are water and nitrogen, the system can be recharged from stores of both carried aboard the ISS or spacecraft. The only support requirement would be a pump to fill the water and a compressor to pressurize the nitrogen propellant gas. This system uses a gaseous agent to pressurize the storage container as well as to assist in the generation of the fine water mist.
The portable fire extinguisher hardware works like a standard fire extinguisher with a single storage container for the agents (water and nitrogen), a control valve assembly for manual actuation, and a discharge nozzle. The design implemented in the proof-of-concept experiment successfully extinguished both open fires and fires in baffled enclosures.
The proof-of-concept design weighs less than 20 lb (9 kg) and can be easily scaled up or down in size depending on the application. The design is fully selfcontained and modular with no complex piping to thread through a crowded habitation module, and mounting is simplified.
The liquid agent is water, or water with additives to enhance the fire suppression capability for specific fire hazards. Compatible gases include nitrogen, argon, or other common nonflammable gases. Each fluid constituent is held in the container by a valve. Design features inside the storage tank make it possible to easily discharge all of the fluid as a uniformly dispersed fine water mist regardless of gravity or system orientation.
When the system is operated, the gas pressure forces the liquid from the extinguisher. The gas and liquid constituents are also mixed to deliver a multiphase flow to the discharge nozzle to generate fine water-mist droplets, which extinguish the fire.
This work was done by James R. Butz, Craig S. Turchi, and Amanda Kimball of ADA Technologies Inc. and Thomas McKinnon and Edward Riedel of Colorado School of Mines for Glenn Research Center.
Inquiries concerning rights for the commercial use of this invention should be addressed to ADA Technologies Inc, Attn: Nick Knowlton, 8100 Shaffer Pkwy, suite 130, Littleton, CO. 80127-4107, (303) 874- 7377. LEW-18190-1