The subject matter disclosed herein relates to a fire extinguisher actuator. More specifically, the subject matter disclosed relates to a fire extinguisher actuator that activates the release of a fire extinguishing agent.
In an aircraft environment, hermetically sealed fire extinguishers are typically activated by direct explosive impingement energy using a pyrotechnic trigger device, such as a pyrotechnic cartridge or squib. The impingement energy is focused on a dome-shaped fire extinguisher outlet burst disc such that the fire extinguisher outlet burst disc will rupture as a result of the impingement. The fire extinguisher outlet burst disc is typically fabricated from corrosion resistant steel. Normally, the pyrotechnic trigger device is retained in a discharge head in such a manner that it directly faces the fire extinguisher outlet burst disc. The discharge head is attached to an outlet of the fire extinguisher and is typically used to direct the flow of extinguishing agent to an aircraft interface, such as plumbing or tubing, which directs the extinguishing agent to a desired location. A filter screen is located within the discharge head to catch any large fire extinguisher outlet burst disc fragments created as a result of the explosive impingement energy.
The use of pyrotechnic trigger devices can be effective; however, pyrotechnic trigger devices require special handling procedures and training that add to overall aircraft management and maintenance costs. Additionally, pyrotechnic trigger devices may have a limited expected life span and thus require periodic replacement.
According to one aspect, a fire extinguisher actuator assembly for a fire extinguisher is provided. The fire extinguisher includes a fire extinguisher reservoir and a fire extinguisher outlet burst disc that forms a discharge barrier between the fire extinguisher reservoir and a discharge head to retain a pressurized fire extinguishing agent within the fire extinguisher reservoir. The fire extinguisher actuator assembly includes a cutter positioned within the fire extinguisher proximate the fire extinguisher outlet burst disc. The fire extinguisher actuator assembly also includes a motorized activation device having a drive shaft. The motorized activation device is operable to rotate the drive shaft and push the cutter to pierce the fire extinguisher outlet burst disc, thereby releasing the pressurized fire extinguishing agent through the discharge head.
According to another aspect, a method of installing a fire extinguisher actuator assembly in a fire extinguisher is provided. The fire extinguisher includes a fire extinguisher reservoir and a fire extinguisher outlet burst disc that forms a discharge barrier between the fire extinguisher reservoir and a discharge head to retain a pressurized fire extinguishing agent within the fire extinguisher reservoir. The method includes positioning a cutter within the fire extinguisher proximate the fire extinguisher outlet burst disc. A motorized activation device including a drive shaft is mounted within the fire extinguisher such that the motorized activation device is operable to rotate the drive shaft and push the cutter to pierce the fire extinguisher outlet burst disc, thereby releasing the pressurized fire extinguishing agent through the discharge head.
The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:
In an exemplary embodiment, a fire extinguisher actuator assembly for a fire extinguisher is provided that is activated without a pyrotechnic trigger device. The fire extinguisher actuator assembly includes a motorized activation device that drives a cutter to release a pressurized fire extinguishing agent from the fire extinguisher. The cutter pierces a fire extinguisher outlet burst disc that retains the pressurized fire extinguishing agent in the fire extinguisher. The cutter may be detachably coupled to a pusher on a drive shaft of the motorized activation device such that upon piercing of the fire extinguisher outlet burst disc, the pressure of the pressurized fire extinguishing agent drives the cutter rapidly through the fire extinguisher outlet burst disc. Using a cutter to open a fire extinguisher outlet burst disc of a fire extinguisher may remove the need to include a debris screen in a discharge head of the fire extinguisher system, as loose fire extinguisher outlet burst disc fragments typically resulting from pyrotechnic trigger device ignition are no longer present.
Turning now to
The fire extinguisher actuator assembly 200 also includes the motorized activation device 220 having a drive shaft 222 that drives a pusher 208. The drive shaft 222 may include helical threading to mesh with the pusher 208, and thus the drive shaft 222 may also be referred to as a helical drive shaft. The drive shaft 222 can also include a shaft end cap 209 to retain the pusher 208 on the drive shaft 222. The motorized activation device 220 is operable to rotate the drive shaft 222 and push the cutter 204 to pierce the fire extinguisher outlet burst disc 108, thereby releasing the pressurized fire extinguishing agent 212 through the discharge head 104. As can be seen in the
As will be understood, the fire extinguisher actuator assembly 200 can include other structure elements to support and stabilize the motorized activation device 220, as well as electrical connections, which are not depicted to simplify the drawings. The fire extinguisher reservoir 106 can be sized to accommodate a wide variety of installations. For example, the fire extinguisher reservoir 106 can range in size from 40 cubic inches (655.5 cm3) to 2,500+ cubic inches (40,968+ cm3). Pressure changes within the fire extinguisher reservoir 106 can occur due to ambient temperature variations. For example, in an aircraft environment, the fire extinguisher 102 may be at 240 degrees F. (115.6 degrees C.) on the ground on a hot day and after takeoff be at −65 degrees F. (−53.9 degrees C.) at altitude. These temperature changes cause substantial changes to the internal fire extinguisher pressure 214. Example nominal pressure values of the internal fire extinguisher pressure 214 can range from between about 300 pounds-per-square-inch (2,068 kPa) to about 800 pounds-per-square-inch (5,515 kPa) at 70 degrees F. (21.1 degrees C.), with higher pressures at higher temperatures and lower pressures at lower temperatures. Upon piercing the fire extinguisher outlet burst disc 108, the internal fire extinguisher pressure 214 can drive the cutter shuttle assembly 202 to disengage with the pusher 208 and the anti-rotation guides 215 to fully open the fire extinguisher outlet burst disc 108.
With reference to
While the invention has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the invention is not limited to such disclosed embodiments. Rather, the invention can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the invention. Additionally, while various embodiments of the invention have been described, it is to be understood that aspects of the invention may include only some of the described embodiments. Accordingly, the invention is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.
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