Patent Application
20170120089
Fire suppression systems often comprise a detecting element, an electronic control board, and an extinguishing system. For example, the detecting element monitors an area for a condition associated with a fire. When the detecting element detects a condition associated with a fire, it sends a signal to the electronic control board. Then, the electronic control board typically sounds an alarm, and triggers the extinguishing system in the area monitored by the detecting element. Generally, electronically-based fire suppression systems are complex, require significant installation time, and require a constant source of electrical power. In addition, in the event of malfunction or loss of power, these systems may be susceptible to failure. Also, certain types of electronically-based fire suppression systems may not be particularly well-suited for use on portable structures, such as transportation or cargo containers used on aircraft and boats.
A fire suppression system according to various aspects of the present technology is configured to deliver a fire suppressant material in response to a detected fire condition in a transportable container. In one embodiment, the fire suppression system comprises a detection system adapted to generate a detection signal when exposed to a fire condition that triggers a deployment valve to release a fire suppressant material into the transportable container. The fire suppression system is also be configured to be selectively disarmed to prevent actuation of the deployment valve in the event of an inadvertent signal generated by the detection system.
A more complete understanding of the present technology may be derived by referring to the detailed description and claims when considered in connection with the following illustrative figures. In the following figures, like reference numbers refer to similar elements and steps throughout the figures.
Elements and steps in the figures are illustrated for simplicity and clarity and have not necessarily been rendered according to any particular sequence. For example, steps that may be performed concurrently or in a different order are illustrated in the figures to help to improve understanding of embodiments of the present technology.
The present technology may be described in terms of functional block components and various processing steps. Such functional blocks may be realized by any number of hardware or software components configured to perform the specified functions and achieve the various results. For example, the present technology may employ various vessels, sensors, detectors, control materials, valves, and the like, which may carry out a variety of functions. In addition, the present technology may be practiced in conjunction with any number of hazards, and the system described is merely one exemplary application for the technology. Further, the present technology may employ any number of conventional techniques for delivering control materials, sensing hazard conditions, controlling valves, and the like.
Methods and apparatus for a pneumatically actuated fire suppression system for a transportable container according to various aspects of the present technology may operate in conjunction with any suitable mobile and/or stationary container device. Various representative implementations of the present technology may be applied to any system for suppressing fires or controlling other hazardous conditions, such as chemical spills. Certain representative implementations may include, for example, portable and/or non-portable containers, unit load devices for aircrafts, cargo containers, intermodal containers, and fixed storage units.
Referring now to
Detection System
The detection system 104 generates a detection signal in response to a detected hazard condition. The detection system 104 may comprise any appropriate system for detecting one or more specific hazards and generating a corresponding detection signal, such as system for detecting smoke, heat, open flames, poisonous gas, radiation, and the like. For example, the detection system 104 may be adapted to detect a fire by sensing heat by any suitable method such as a discrete point heat detector or an ultraviolet or infrared sensor. The detection system 104 may generate an appropriate detection signal that is sent to the suppression system 102. The detection signal causes the suppression system 102 to actuate and release an appropriate hazard control material, such as a fire suppressant, into the enclosed volume 110 of the transportable container 100 to suppress, extinguish, or otherwise dispose of the hazard condition.
Referring now to
Detection Tube
In a first embodiment, the detection signal may comprise a pneumatic signal generated in response to the detection of a fire inside of the transportable container 100. Referring now to
The detection tube 1202 may comprise any appropriate materials that degrade when exposed to the trigger event, such as: Firetrace® detection tubing, aluminum, aluminum alloy, cement, ceramic, copper, copper alloy, composites, iron, iron alloy, nickel, nickel alloy, organic materials, polymer, titanium, titanium alloy, rubber, and the like. The detection tube 1202 may be formed to any appropriate shape or dimension and may further comprise a coating resist corrosion, deformation, fracture, or other damage unrelated to the trigger event.
The internal pressure that the detection tube 1202 is pressurized to may be determined by a temperature or energy level at which degradation of the tube is desired to occur. For example, the detection tube 1202 may comprise a material that degrades differently when subjected to various combinations of ambient temperature and internal pressure thereby allowing a user to select what conditions must be met by the trigger condition. The detection tube 1202 may demonstrate an inverse relationship between the internal pressure of the detection tube and the temperature that causes the detection tube to degrade, leak, and/or burst. For example, as the detection tube 1202 is pressurized to a higher level the detection tube 1202 may burst when exposed to a lower temperature. Alternatively, the detection tube 1202 may demonstrate a direct relationship between the internal pressure of the detection tube 1202 and the temperature that causes the detection tube 1202 to degrade, leak, burst, or otherwise lose internal pressure.
The detection tube 1302 may be pressurized with a higher or lower internal pressure than an ambient pressure in the enclosed volume 110 of the transportable container 100. The internal pressure of the detection tube 1202 may be achieved and sustained in any suitable manner, such as by pressurizing and sealing the detection tube 1202; connecting the detection tube 1202 to an independent pressure source such as a compressor or pressure bottle; or connecting the detection tube 1202 to a pressure vessel and using a portion of a pressurized fluid and/or gas within the pressure vessel to pressurize the detection tube. The detection tube 1202 may be pressurized with any fluid that is sensitive to changes in temperature or pressure. For example, a substantially inert fluid such as air, nitrogen, or argon may be used to pressurize the detection tube 1202 to a predetermined internal pressure.
The detection tube 1202 may also be configured to be sealed on each end while maintaining the predetermined internal pressure. The detection tube 1202 may be sealed by any suitable method. For example, referring now to
The detection tube 1202 may be pressurized to a level substantially equivalent to a pressure of a pressure vessel 204 that holds the hazardous control material. Alternatively, the detection tube 1302 may be pressurized to a level higher than that of the pressure vessel 204, creating a pressure differential at the deployment valve 202 that may range between 50-600 pounds per square inch (psi). To reduce the potential for pressure leakage from the detection tube 1302 through the deployment valve 202 and into the pressure vessel 204, the detection tube 1202 may be configured with a one-way valve (not shown). The one-way valve may be suitably adapted to prevent the higher pressure in the detection tube 1202 from bleeding into the lower pressure side of the pressure vessel 204.
Referring now to
Linear Detection System
In a second embodiment, the detection signal may comprise an electric signal generated in response to the detection of a fire inside of the transportable container 100. Referring now to
After the heat sensitive coating 1608 melts in response to the trigger event, the first and second conductor wire 1602, 1604 come into contact with each other and form a circuit. The circuit generates the detection signal and causes the solenoid 1504 to actuate the suppression system 102.
Any suitable source of electrical power may be used to power the linear heat detector 1502 connected and the solenoid 1504. For example, in one embodiment, a battery may be used to provide power. In an alternative embodiment, the detection system 104 may be configured to be selectively coupled to an external power source such as an electrical outlet or an onboard system such as an auxiliary power unit.
Suppression System
The suppression system 102 is suitably adapted to respond to the detection signal by releasing an appropriate hazard control material into the enclosed volume 110 to mitigate the detected hazard. The suppression system 102 may comprise any suitable device or components for affecting a hazard or suppressing a fire. For example, referring now to
The pressure vessel 204 may also be coupled to the deployment valve 202, wherein the pressure vessel 204 is suitably configured to store the hazard control material. The suppression system 102 may be further coupled to a discharge system 206 and the detection system 104.
The pressure vessel 204 may comprise any suitable type of container or device for housing the hazard control material under pressure. The pressure vessel 204 may comprise any suitable system for storing and/or providing the hazard control material, such as a pressurized tank or bottle. The pressure vessel 204 may be suitably configured to contain a mass or volume of any suitable hazard control material such as a liquid, gas, or powder material. The pressure vessel 204 may also be configured to withstand various operating conditions including: temperature variations of up to 600 degrees Fahrenheit, vibration, impact, and environmental pressure changes. The pressure vessel 204 may be made of any suitable material, with the material selected according to any appropriate criteria, such as requirements to resist corrosion, deformation, fracture, and/or the like. The pressure vessel 204 may further comprise any suitable shape or dimension. For example, an internal volume of the pressure vessel 204 may be selected to hold a sufficient amount of hazard control material to effectively suppress or extinguish a fire condition that may occur within the interior volume 110 of the transportable container 100.
The pressure vessel 204 may also be suitably configured to hold the hazard control material under any suitable internal pressure. For example, in one embodiment, the pressure vessel 204 may hold or maintain the hazard control material at a pressure of up to about 360 psi. In a second embodiment, the pressure vessel 204 may be configured to hold the hazard control material at a pressure of up to about 800-850 psi.
The hazard control material may be selected according to the particular hazard and/or environment that the container 100 will be used in. For example, if the pneumatically actuated fire suppression system is configured to suppress a fire in the enclosed volume 110 by maintaining a low oxygen level, the control material may be selected from any suitable chemical or compound adapted to absorb or dilute oxygen levels when transmitted into the enclosed volume 110. As another example, if the pneumatically actuated fire suppression system is configured to suppress a fire by inhibiting the chemical reaction of the fire, the hazard control material may be selected from an appropriate agent. In yet another embodiment, the hazard control material may be selected from materials adapted to suppress a fire by reducing the heat of the fire.
For example, one hazard control material may comprise a fire suppressant suitably adapted for transient events such as explosions or other rapid combustion. Alternatively, the hazard control material may comprise a fire suppressant suitably adapted to change from a liquid state inside of the pressure vessel 204 to a gaseous state when ejected into the enclosed volume 110. The hazard control material may alternatively comprise a common dry chemical suppressant such as ABC, BC, or D dry powder. In another embodiment, the hazard control material may comprise a fire suppressant mixture such as potassium acetate and water. In yet another embodiment, the hazard control material may comprise a suppressant material further comprising additional chemicals or compounds such as various forms or combinations of lithium, sodium, potassium, chloride, graphite, acetylene, oxides, and magnetite.
The hazard control material may also be adapted to have more than a single method of controlling the hazard. For example, the hazard control material may comprise multiple elements or compounds, wherein each compound has a different property such as being reactive or unreactive to heat, acting to deprive a fire of oxygen, absorbing heat radiated from the fire, and/or transferring heat from the fire to another compound.
Valve
The deployment valve 202 provides a seal to the pressure vessel 204 allowing the hazard control material to be held within the pressure vessel 204 under pressure. The deployment valve 202 may comprise any suitable system for maintaining a pressurized volume of the hazard control material and for releasing that volume upon demand. For example, the deployment valve 202 may be actuated in response to the detection signal to allow the hazard control material to be released in the event that a hazard condition creates the trigger event. The deployment valve 202 may also comprise a fill system configured to allow the pressure vessel 204 to be pressurized after the deployment valve 202 is coupled to the pressure vessel 204.
The deployment valve 202 may be responsive to the detection signal from the detection system 104 and may be suitably adapted to actuate to open or otherwise remove the seal on the pressure vessel 204 in response to the detection signal. In one embodiment, once the deployment valve 202 actuates the entire volume of the control material may be released to the discharge system 206. In another embodiment, the deployment valve 202 may be suitably configured to control the rate of release of the hazard control material. For example, the deployment valve 202 may comprise a selectively activated opening such as a ball, piston, push, or gate valve that is configured to release a predetermined mass flow rate of fire suppressant material. The rate of release may be dependent on a given type of transportable container 100 or size of the enclosed volume 110 to be protected and may be related to the pressure within the pressure vessel 204 relative to the ambient pressure of the surrounding environment in the transportable container 100.
The deployment valve 202 may also be configured to release the hazard control material over a specific period of time. For example, the deployment valve 202 may be sized such that a total release of the hazard control material occurs over a period ranging from about twenty to sixty seconds. Alternatively, the deployment valve 202 may be suitably adapted to release the hazard control material over a relatively short period of time such as 0.1 seconds. The deployment valve 202 may also be configured to disperse a substantially constant level of hazard control material in a given volume.
Referring to
Valve Body
The valve body 302 may be coupled to the valve cap 304 by any suitable method such as mechanically, adhesively, welding, fusion, or the like. In one embodiment, the valve body 302 may comprise a set of threads 610 suitably configured to mate to a matching set of threads on the valve cap 304 to allow the two sections to be screwed together. One or more o-rings may be used to provide an enhanced seal between the threaded connection of the valve body 302 and the valve cap 304.
Internal Pressure Chamber
Referring now to
The discharge port 308 may be disposed in a mid-portion of the valve body 302 and be suitably configured to couple to the discharge system 206 to provide a path for the released hazard control material to exit the pressure vessel 204 and the deployment valve 202 when the deployment valve 202 is actuated in response to the detection signal. The discharge port 308 may comprise an opening of any suitable size or shape that extends outward from an inner portion of the deployment valve 202 through the valve body 302. The discharge port 308 may be configured to couple to the discharge system 206 by any suitable method. For example, a wall section of the discharge port 308 may comprise a set of recessed threads suitably configured to receive a set of matching threads on the discharge system 206 to allow the two sections to be screwed together.
Piston
A piston 602 may be positioned within the internal chamber 604 and be configured to seal off the discharge port 308 from the internal chamber 604 and the side channel 612 when the deployment valve 202 is in an unactuated state. The piston may comprise any suitable device configured to move between a first position and a second position to selectively seal off the discharge port 308. Referring now to
The piston 602 may be suitably configured to allow the pressure to equalize in the internal chamber 604 and the pressure vessel 204 and still allow for a pressure loss in the internal chamber 604 to cause the piston 602 to move upwards under force of the pressure in the pressure vessel 204. For example, referring now to
In the event of a sudden pressure loss in the internal chamber 604, the pressure force acting on the bottom surface of the piston 602 will become greater than the pressure force on the top surface of the piston 602 and the piston 602 will be forced upwards. The pressure hole 1002 may be sized such that the conduit path through the piston 602 is not large enough to allow the pressure from the pressure vessel 204 to escape through the piston 602 quick enough to overcome the overall pressure force acting on the bottom surface of the piston 602. As the piston moves upward unsealing the discharge port 308, the hazard control material may flow upward from the inlet port 314 through the side channel 612 and be directed into the discharge port 308 by the bottom surface of the piston 602 (shown by the white line). The hazard control material may then exit the deployment valve 202 and continue on to the discharge system 206 under the force of the pressure in the pressure vessel 204.
Referring now to
Valve Cap
Referring now to
Fill Port
Referring now to
Bleed Port/Inlet
The valve cap 304 may further comprise a bleed port 420 configured to allow the detection system 104 to be coupled to the deployment valve 202. The bleed port may comprise an opening extending through the valve cap 304 and may be comprise a plug or fitting configured to seal the valve cap 304 to prevent any leakage of pressure.
The bleed port 420 may also be configured to allow the pressure in the internal chamber 604 to be bled from the deployment valve 202 in a manner that prevents the piston 602 from moving upwards causing the actuation of the deployment valve 202 and the release of the hazard control material. For example, the bleed port 420 may comprise a fitting configured to allow a controlled release of pressure through the valve cap 304 that equals the rate at which pressure can move through the pressure hole 1002 such that the pressure forces acting on the top and bottom surfaces of the piston 602 do not differentiate sufficiently to cause the piston 602 to unseat and move upwards rapidly enough to cause the deployment valve 202 to actuate.
Fill Channel
In one embodiment, the bleed port 420 may be fluidly coupled to the fill channel 702 such that a pressure in the fill channel 702 may be equal to that of the detection tube 1202. The fill channel 702 may also provide a flow path for a fluid between the detection tube 1202 and the internal chamber 604. For example, referring now to
Due to the fluid link between the detection tube 1202 and the internal chamber 604, when the detection tube 1202 generates the detection signal resulting from a loss in pressure, the detection signal is detected in the internal chamber 604. For example, if a trigger event causes the detection tube 1202 to burst, the detection tube 1202 will depressurize. This loss in pressure will be translated through the bleed port 420, the fill channel 702, and into the internal chamber 604. Once the internal chamber 604 loses pressure, the piston 602 will move upwards and the deployment valve 202 will be actuated to release the hazard control material.
In an alternative embodiment, the fill channel 702 may be fluidly coupled to the solenoid 1504 through the bleed port 420 fill channel 702. When the linear heat detector 1502 responds to the trigger event the detection signal may be communicated to the solenoid 1504 causing it to open the bleed port 420 and release the pressure in the fill channel 702. The loss in pressure in the fill channel 702 will be translated to the internal chamber 604 causing a loss in the pressure to the internal chamber 604 which causes the piston 602 to move upwards actuating the deployment valve 202 to release the hazard control material into the enclosed volume 110.
Locking System
Referring now to
Push Valve
The push valve 608 may comprise a body configured to move or slide within the fill channel 702. For example, referring now to
When the push valve 608 is in the disarmed position, the pressure within the detection system 104 and the bleed port 420 (shown as cross-hatched lines 802) is separated from the pressure within the internal chamber (shown as angled lines 804). In the disarmed position, a pressure loss in the detection system 104 or the bleed port 420 will not be translated into the internal chamber 604 and the piston 602 will remain in place and the deployment valve 202 will not actuate. Positioning the push valve 608 in the disarm position allows the detection system 104 to be serviced or inspected after the pneumatically actuated fire suppression system has been installed without causing an inadvertent actuation of the deployment valve. This may increase both the overall safety of the pneumatically actuated fire suppression system for users and may also reduce costs associated with loss of hazard control material due to an accidental or inadvertent actuation of the deployment valve 202.
Lever/Pin
Referring now to
A locking pin 614 may be utilized to fix the position of the lever arm 606. For example, when the push valve 608 is positioned in the disarmed position, the locking pin 614 may be coupled to the lever arm 606 and the valve cap 304 to prevent the lever arm 606 from being moved. This may act as a security feature during service of the pneumatically actuated fire suppression system to provide a visual indication that the system is disarmed and the detection system 104 has been decoupled from the deployment valve 202.
Discharge System
The discharge system 206 is configured to deliver the control material to the enclosed volume 110 after it is released from the pressure vessel 204. The discharge system 206 may comprise any suitable system for delivering a control material such as a detection tube, a pipe, a duct, a perforated hose, a nozzle, or a sprayer. The discharge system 206 may comprise any suitable material such as metal, plastic, or polymer and may be suitably adapted to withstand elevated temperatures associated with fires or exposure to caustic chemicals.
For example, referring now to
The nozzle body 408 may comprise any suitable device or system for dispersing the hazard control material into the enclosed volume. In one embodiment, the nozzle body 408 may comprise a series of ejector holes 418 arranged along a portion of the nozzle body 408 to separate the hazard control material into multiple streams directed towards one or more areas of the enclosed volume 110. For example, if the discharge system 206 is positioned in a corner of the enclosed volume 110, the ejector holes 418 may be arranged to disperse the hazard control material into a substantially ninety degree pattern such that the hazard control material is evenly dispersed into the enclosed volume 110.
The ejector holes 418 may comprise any suitable shape or size and may be determined according to any suitable criteria such as the type of hazard control material being used or the size of the enclosed volume 110. For example, if the transportable container 100 is longer along one side than another, there may be more ejector holes 418 facing the longer side or the ejector holes 418 may be larger to allow more of the hazard control material to be directed into the desired direction.
In another embodiment, the discharge system 206 may also be configured to act as the detection system 104. The discharge system 206 may also be pressurized or be configured to withstand pressures of up to 800 psi. For example, in one embodiment, the discharge system 206 may comprise the detection tube, wherein the detection tube is adapted to rupture or otherwise break in response to an applied heat load such as a fire. For example, rupturing of the detection tube may trigger the deployment valve 202 to release the control material. The released control material is then routed through the discharge system 206 to the location of the rupture where it exits and is dispersed into the transportable container 100.
Referring now to
Referring now to
In operation, the pneumatically actuated fire suppression system is initially configured such that the detection system 104 monitors an enclosed volume 110 for the existence of a fire condition. For example, in the event of a fire condition inside the transportable container 100, the ambient temperature inside the transportable container 100 will increase at a rate determined by the intensity of the fire. Once the temperature reaches a predetermined threshold value, a detection tube may burst creating a detection signal that is sent to the suppression system 102 causing a fire suppressant to be released into the enclosed volume 110 of the transportable container 100.
These and other embodiments for methods of controlling a hazard may incorporate concepts, embodiments, and configurations as described with respect to embodiments of apparatus for controlling a hazard as described above. The particular implementations shown and described are illustrative of the technology and its best mode and are not intended to otherwise limit the scope of the present technology in any way. Indeed, for the sake of brevity, conventional manufacturing, connection, preparation, and other functional aspects of the system may not be described in detail. Furthermore, the connecting lines shown in the various figures are intended to represent exemplary functional relationships and/or physical couplings between the various elements. Many alternative or additional functional relationships or physical connections may be present in a practical system.
The technology has been described with reference to specific exemplary embodiments. Various modifications and changes, however, may be made without departing from the scope of the present technology. The description and figures are to be regarded in an illustrative manner, rather than a restrictive one and all such modifications are intended to be included within the scope of the present technology. Accordingly, the scope of the technology should be determined by the generic embodiments described and their legal equivalents rather than by merely the specific examples described above. For example, the steps recited in any method or process embodiment may be executed in any order, unless otherwise expressly specified, and are not limited to the explicit order presented in the specific examples. Additionally, the components and/or elements recited in any apparatus embodiment may be assembled or otherwise operationally configured in a variety of permutations to produce substantially the same result as the present technology and are accordingly not limited to the specific configuration recited in the specific examples.
Benefits, other advantages and solutions to problems have been described above with regard to particular embodiments; however, any benefit, advantage, solution to problems or any element that may cause any particular benefit, advantage or solution to occur or to become more pronounced are not to be construed as critical, required or essential features or components.
As used herein, the terms “comprises”, “comprising”, or any variation thereof, are intended to reference a non-exclusive inclusion, such that a process, method, article, composition or apparatus that comprises a list of elements does not include only those elements recited, but may also include other elements not expressly listed or inherent to such process, method, article, composition or apparatus. Other combinations and/or modifications of the above-described structures, arrangements, applications, proportions, elements, materials or components used in the practice of the present technology, in addition to those not specifically recited, may be varied or otherwise particularly adapted to specific environments, manufacturing specifications, design parameters or other operating requirements without departing from the general principles of the same.
The present technology has been described above with reference to a preferred embodiment. However, changes and modifications may be made to the preferred embodiment without departing from the scope of the present technology. These and other changes or modifications are intended to be included within the scope of the present technology, as expressed in the following claims.
