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Flame arrester

From Wikipedia, the free encyclopedia
A flame arrester during testing
A flame arrester made for a 91 cm (36 inch) pipe weighing 10 tons

A flame arrester (also spelled arrestor), deflagration arrester,[1] or flame trap[2] is a device or form of construction that will allow free passage of a gas or gaseous mixture but will interrupt or prevent the passage of flame. It prevents the transmission of flame through a flammable gas/air mixture by quenching the flame on the high surface area provided by an array of small passages through which the flame must pass. The emerging gases are cooled enough to prevent ignition on the protected side.[3]

Principles

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Flame arresters are safety devices fitted to openings of enclosures or to pipe work, and are intended to allow flow but prevent flame transmission. A flame arrester functions by absorbing the heat from a flame front thus dropping the burning gas/air mixture below its auto-ignition temperature; consequently, the flame cannot survive. The heat is absorbed through channels (passages) designed into an element. These channels are chosen and measured as the MESG (maximum experimental safe gap) of the gas for a particular installation. These passages can be regular, like crimped metal ribbon or wire mesh or a sheet metal plate with punched holes, or irregular, such as those in random packing.[1]

The required size of the channels needed to stop the flame front can vary significantly, depending on the flammability of the fuel mixture. The large openings on a chain link fence are capable of slowing the spread of a small, slow-burning grass fire, but fast-burning grass fires will penetrate the fence unless the holes are very small.[4] In a coal mine containing highly explosive coal dust or methane, the wire mesh of a Davy lamp must be very tightly spaced.

For flame arresters used as a safety device, the mesh must be protected from damage due to being dropped or struck by another object, and the mesh must be capable of rigidly retaining its shape during the propagation of a flame front. Any shifting of the individual wires that make up the mesh can create an opening large enough to allow the flame to penetrate and spread beyond the barrier.

On a fuel storage vent, flame arresters also serve a secondary purpose of allowing air pressure to equalize inside the tank when fuel is added or removed, while also preventing insects from flying or crawling into the vent piping and fouling the fuel in the tanks and pipes.

Usage and applications

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The uses of a flame arrester include:

  • Installed in combustor/burner air intakes with no pipe or bends before the intake to stop confined and unconfined, low pressure deflagrations, preventing an ignited atmospheric vapor cloud from propagating beyond the Flame Arrestor, outside of a burner/flare intake.
  • Prevent the spread of ignited flammable vapor within an enclosed system, such as a piping network.
  • Preventing potentially explosive mixtures from propagating after ignition by lightning, static electricity or other sources in a vent to atmosphere.
  • Stopping the propagation of a flame traveling at subsonic velocities

Some common objects that have flame arresters are:

Safety

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Flame arresters should be used only in the gas group and conditions they have been designed and tested for. Since the depth on an arrester is specified for certain conditions, changes in the temperature, pressure, or composition of the gases entering the arrester can cause the flame spatial velocity to increase, making the design of the arrester insufficient to stop the flame front ("propagation"). The deflagration may continue downstream of the arrester.[1]

Flame arresters should be periodically inspected to make sure they are free of dirt, insects using it as a nest, or corrosion. The U.S. Chemical Safety and Hazard Investigation Board concluded that an uninspected and badly corroded flame arrester failed to prevent a 2006 explosion at a wastewater treatment plant in Daytona Beach, Florida.[7]

See also

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References

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  1. ^ a b c Arpentinier, Philippe; Cavani, Fabrizio; Trifiro, Ferrucio (2001). The Technology of Catalytic Oxidations. Vol. 2. Paris: Editions TECHNIP. p. 748. ISBN 2-7108-0777-7. Archived from the original on 2020-09-18. Retrieved 2020-09-18.
  2. ^ a b McManus, Neil (1998). Safety and Health in Confined Spaces. CRC Press. p. 147. ISBN 1-56670-326-3. Archived from the original on 2020-09-18. Retrieved 2020-09-18.
  3. ^ Flame Arresters in Piping Systems (PDF) (Report) (3rd ed.). American Petroleum Institute. February 2002. Retrieved 2023-11-17.
  4. ^ Murphy, James L.; Schimke, Harry E. (1965). "Do Wire Fences Stop Ground Fires?" (PDF). U.S. Forest Service Research Note PSW-70. Pacific Southwest Forest & Range Experiment Station. Archived from the original (PDF) on 2010-12-14.
  5. ^ Stevick, Glen (2011). "Failure Analysis and Prevention of Fires and Explosions with Plastic Gasoline Containers". Journal of Failure Analysis and Prevention. 75 (11): 455–465. doi:10.1007/s11668-011-9462-z. S2CID 56269455. Retrieved 2023-11-17.
  6. ^ ASTM F3326 Standard Specification for Flame Mitigation Devices on Portable Fuel Containers (PDF) (Report). doi:10.1520/F3326-21. Retrieved 2023-11-17.
  7. ^ The United States Chemical Safety and Hazard Investigation Board (2007), Investigation Report: Methanol Tank Explosion and Fire, Bethune Point Wastewater Treatment Plant, City of Daytona Beach, Florida, January 11, 2006 (PDF), The United States Chemical Safety and Hazard Investigation Board, p. 29, archived (PDF) from the original on 2014-01-09, retrieved 2014-04-10