The present invention is directed to fire suppression systems for vehicles and industrial applications. More specifically, the present invention is directed to actuators for use in fire suppression systems for vehicles and industrial applications.
Known fire firefighting systems for vehicles and industrial applications include a fire fighting agent supply coupled to one or more fixed nozzles to protect a hazard or area in which an ignition source and fuel or flammable materials may be found. The firefighting agent supply preferably includes one or more storage tanks or cylinders containing the firefighting agent, such as for example a chemical agent. Each storage tank cylinder includes a pressurized cylinder assembly configured for pressurizing the storage tanks for delivery of the agent under an operating pressure to the nozzles to address a fire in the hazard. The pressurized cylinder assembly includes an actuating or rupturing device or assembly which punctures a rupture disc of a pressurized cylinder containing a pressurized gas, such as for example nitrogen, to pressurize the storage tank for delivery of the firefighting agent under pressure.
In order to operate the rupturing device, the system provides for automatic actuation and manual operation of the rupturing device to provide for respective automated and manual delivery of the chemical agent in response to a fire for protection of the hazard. The rupturing device includes a puncturing pin or member that is driven into the rupture disc of the pressurized cylinder for release of the pressurized gas. The puncturing pin of the rupturing device may be driven electrically or pneumatically to puncture the rupture disc of the pressurized cylinder. A preferred device for driving the puncturing pin is a protracting actuation device (PAD), which includes an electrically coupled rod or member that is disposed above the puncturing pin. When an electrical signal is delivered to the PAD, the rod of the PAD is driven into the puncturing pin which punctures the rupture disc of the pressurized cylinder. In pneumatic manual operation of the rupturing device, pressurized gas from a separate source is delivered to the rupturing device to act on the puncturing pin and drive it into the rupture disc.
One problem with the configuration of prior rupturing assemblies is that the electrical operating components or connectors are exposed either to the harsh environment in which the fire protection system operates or to the pressurized gas which pneumatically operates the assembly. These configurations can increase the maintenance requirements of the system. Moreover, the configuration of the existing rupturing assemblies can cause pressure losses across the device, which can prohibit operation of multiple devices connected serially with a single source of pressurized gas for pneumatic actuation.
Another problem with existing rupturing assemblies is that the puncturing pin can present a hazard when connecting the device to or removing the device from a pressurizing cylinder. More specifically, if the puncturing pin is extended to its actuated position, the pin can cause injury to personnel and the pressurizing cylinder, which can result in accidental discharge of the pressurizing gas.
Accordingly, it would be desirable to have a rupturing assembly that addresses the known difficulties of existing systems, and provides for both electrical and pneumatic actuation, electrical components sealed from the operative environment, serial interconnection with other rupturing assemblies for operation by a single source of pressurized gas, and a configuration that facilitates safe handling and installation of the rupturing assembly.
The present invention is directed to rupturing assemblies for use in a fire suppression system for vehicles and industrial applications. A preferred embodiment of the rupturing assembly of the present invention is an actuator assembly configured for electrical and pneumatic actuation for rupturing a seal of a cartridge of pressurized gas. The preferred assembly includes a housing having a proximal end and a distal end with a passageway extending axially from the proximal end to the distal end along an actuator axis. The passageway preferably defines a first chamber and a second chamber with the second chamber disposed distally of the first chamber. The housing preferably includes at least one inlet port formed between the first and second chambers in communication with the passageway for coupling to a pressurized gas source. An electrically operated protracting actuation device having an electrical connector and a rod member is preferably disposed within the housing such that the electrical connector is disposed in the first chamber and the rod member is disposed in the second chamber with the first chamber being sealed from the second chamber and the inlet port. A puncturing assembly including a head with a puncturing pin has an actuated position and a retracted position within the passageway with the head in the second chamber. The puncturing assembly translates from the retracted position to the actuated position upon either electrical operation of the protracting actuation device or the pressurized gas delivered to the at least one inlet acting on the head.
In another preferred embodiment of an actuator assembly, the assembly includes an electric component; a puncturing assembly; and a housing having a proximal end and a distal end with a passageway extending axially from the proximal end to the distal end to define an actuator axis. The passageway defines a pneumatic chamber for pneumatically displacing the puncturing assembly within the pneumatic chamber; and an electric component chamber sealed from the pneumatic chamber for housing an electrically operated component that axially displaces the puncturing assembly within the pneumatic chamber. The electric component chamber is preferably sealed against moisture and dust to define an IEC rating of IP67 under the International Electrotechnical Commission (IEC) Standard 60529 (2013 ed. 2.2).
Preferred embodiments of the actuator assembly control the manner in which the assembly engages a cartridge of pressurized gas. The preferred assembly includes a puncturing assembly and a housing having a proximal portion with the puncturing assembly disposed within the passageway for axial displacement from a retracted position. The distal portion of the housing includes a receptacle for preferably axially receiving the sealed cartridge such that axial displacement of the puncturing assembly from the retracted position ruptures the sealed cartridge. A bracket is preferably engaged with the housing that defines a guide path having a first transverse portion and second axial portion to control engagement between the cartridge and the distal portion of the housing. In one preferred aspect, the guide path provides that, when the puncturing assembly is in the retracted position, the cartridge can be axially aligned with the receptacle so that the cartridge is engaged with the housing and, when the puncturing assembly has been axially displaced from the retracted position, the puncturing assembly prevents alignment of the cartridge with the receptacle, and thus prevents engagement of the cartridge with the housing. In another preferred aspect, the guide path provides that, when the puncturing assembly is in the retracted position, the discharged cartridge can be axially disengaged and offset from the receptacle so that the cartridge can be disengaged from the housing; and when the puncturing assembly has been axially displaced from the retracted position, the puncturing assembly prevents disengagement of the cartridge from the receptacle and the housing.
The preferred actuator assemblies provide for preferred fire protection systems in which the preferred actuator assemblies are coupled to an electrical actuation signal source; a plurality of pressurized gas cartridges; and a plurality of storage tanks of firefighting suppressant. In another embodiment of the preferred system, a plurality of the preferred actuator assemblies are interconnected in a chain with a pressurized gas supply coupled to a first actuating device to deliver pressurized gas to the first actuator assembly and a last actuator assembly in the chain so as to provide operation of the plurality of actuators of the assemblies with a one second maximum time interval between the first actuator assembly and the last actuator assembly. Preferably, the plurality of actuator assemblies comprises up to ten actuator assemblies and the connection tubing comprises a total length of up to 150 feet of ¼ inch pneumatic tubing.
While the Summary describes preferred embodiments of an actuator assembly for use in fire suppression systems that overcome difficulties of known rupturing assemblies and associated fire protection systems, including but not limited to, providing for electrical and pneumatic actuation with electrical components that are sealed from the operative environment of the actuator assembly, serial interconnection of multiple actuator assemblies for operation by a single source of pressurized gas, and a configuration that facilitates safe handling and installation of the actuator assembly, the Summary is provided as a general introduction to some embodiments of the invention, and is not intended to be limiting to any particular configuration or system. It is to be understood that various features and configurations of features can be combined in any suitable way to form any number of embodiments of the invention. Some additional example embodiments including variations and alternative configurations are provided herein.
The accompanying drawings, which are incorporated herein and constitute part of this specification, illustrate exemplary embodiments of the invention and, together with the general description given above and the detailed description given below, serve to explain the features of the exemplary embodiments of the invention.
Coupled to the pressurized cartridge 16 is a preferred actuator assembly 100 which punctures the sealed cartridge 16 to release the pressurized gas contained therein. The preferred actuator assembly 100 is connected or piped to the storage tank 14 to convey the released pressurized gas and pressurize the storage tanks 14 for delivery of the firefighting agent under pressure to the one or more nozzles 12. The preferred actuator assembly 100 is structured to provide selective electrical and/or pneumatic actuation for puncturing the rupture disc of the sealed pressurized cartridge 16.
Referring to
Disposed within the passageway 116 is a preferred puncturing assembly 126 that includes an enlarged head 126a and a puncture pin 126b engaged with the head 126a. Upon actuation, the puncture assembly 126 is axially and distally displaced along the passageway 116 so that the puncture pin 126b penetrates and ruptures the seal or rupture disc 18 of the pressurized gas cartridge 16 coupled to the distal portion 114 of the actuator assembly housing 110. The head 126a is preferably housed in the second chamber 120 and sized to define a surface upon which a pneumatic pressure can act to displace the actuating assembly 126. Accordingly, the second chamber 120 is preferably configured as a pneumatic chamber 120 for pneumatic actuation and displacement of the puncturing assembly 126. The preferred pneumatic chamber 120 is placed in fluid communication with the pneumatic ports 122a, 122b and pressurized by the pressurized gas delivered to the inlet ports 122a, 122b. The gas pressure within the chamber 120 acts on the upper or proximal surface of the enlarged head 126a to axially displace the puncturing assembly 126 and its puncturing pin 126b. To facilitate the pneumatic actuation, the pneumatic chamber 120 is dimensioned to form a fluid tight seal with the enlarged head 126a of the puncturing assembly. The enlarged head can include a peripheral gasket 126c to form a fluid tight and sliding engagement with the internal surface of the housing defining the pneumatic chamber 120.
The puncturing assembly 126 has a preferred retracted position in which the assembly 126 is biased in the proximal direction within the pneumatic chamber 120. The actuator assembly 100 preferably includes a spring member 125 to proximally bias the puncturing assembly 126 within the pneumatic chamber 120. The preferred spring member 125 can be a compression spring centered about the puncturing pin 126b abutting the enlarged head 126a of the puncturing assembly. The compression spring member 125 is preferably seated within a seat 127 formed along a portion of the pneumatic chamber 120 such that the uncompressed state of the spring 125 biases the puncturing assembly 126 proximally to its retracted position within the passageway 116. More preferably, the uncompressed state of the spring member 125 biases the enlarged head 126a to the retracted position distal of the inlet ports 122a, 122b. Upon pneumatic actuation of the actuator assembly 100, the gas pressure within the pneumatic chamber 120 acts on the enlarged head 126a to compress the spring member 125 and locate the puncturing assembly in its displaced actuated position within the passageway 116. The head 126a and pneumatic chamber 120 are appropriately sized and dimensioned to define a preferred operation pressure sufficient to fully displace the puncturing assembly 126. For example, the head 126a and pneumatic chamber 120 can be sized and dimensioned to define an operating pressure of about 100 pounds per square inch (psi.). The operating pressure can range to be greater or smaller than 100 so long as it is sufficient to displace the puncturing assembly 126. Moreover, the desired operating pressure can vary or range up to a preferred maximum of about 300 psi, and more preferably to a maximum of less than 300 psi. and even more preferably up to a maximum of 265 psi.
In addition to its pneumatic operation, the actuator assembly 100 provides for electrical actuation to axially displace the puncturing assembly 126. Further preferably disposed in the passageway 116 of the housing 110 is an electrically operated device or component for displacing the puncturing assembly 126. More preferably, disposed in the passageway 116 is an electrically operated protracting actuation device (PAD) 128 for driving the puncturing assembly 126 into the rupture disc. The PAD 128 generally includes a proximal electrical connector 128a for receiving an electric actuation signal. Extending distally from the electrical connector 128a is a rod member 128b. The rod member 128b is electrically coupled to the electrical connector 128a so that, when the connector 128a receives an appropriate electric actuating signal, the rod member 128b is axially displaced from a retracted position or configuration within a sheath 128c. The displaced rod member 128b acts against the enlarged head 126a and the bias of the preferred compression spring member 125 to drive and axially displace the puncturing assembly 126 from its retracted position to its actuated position as shown in
The preferred PAD 128 is preferably positioned in the passageway 116 such that the electrical connector 128a is completely housed within the first chamber with the rod member 128b and the outer sheath 128c extending distally toward the second chamber 120. Accordingly in one preferred embodiment, the first chamber 118 is preferably configured as a housing or enclosure for an electric component. Given the vehicle and industrial applications of the preferred actuator assembly, it is anticipated that the actuator assembly is to be exposed to a harsh environment of moisture, fluids, dirt, dust, noise and vibration. The first chamber 118 is thus preferably configured as an electric component chamber or enclosure that is sealed against moisture, liquid and/or dust for housing the electrical connector of the preferred internal PAD 128. More preferably, the electric component chamber 118 is configured to provide a fluid tight seal from the preferred pneumatic chamber 120 and the inlet ports 122a, 122b. For the preferred embodiments, the electric component chamber is preferably water and dust tight so as to satisfy one or more electric industry standards for electrical enclosures. More particularly, the actuator assembly 100 is configured so as to satisfy one or more codes under the International Electrotechnical Commission (IEC) Standard 60529 (2013 ed. 2.2), which characterizes the ability of an electrical enclosure to protect against entry or ingress by, for example, moisture, dust or dirt. In one preferred aspect, the electric component chamber 118 satisfies the IEC Standard to provide for an IP67 rating, which means that the chamber is protected against dust and the effects of immersion between 15 cm and one meter. The assembly can be further preferably configured to satisfy other industry accepted standards for protection against noise, vibration, and/or shock. By providing the preferred sealing of the electric component chamber 118 and the electric component(s) contained therein, the actuator assembly 100 is believed to be more robust or stable when operated electrically.
The proximal portion 112 of the housing 110 preferably defines an inlet 118a in communication with the electric component chamber 118 and through which the PAD 128 is inserted. Axially spaced and formed distally of the inlet 118a is a floor 118b upon which the electrical connector 128a of the PAD 128 sits. Further preferably formed along the floor 118b is a seat for seating a sealing member 130. The sealing member 130 preferably circumscribes an axially aligned outlet 118c of the electric component chamber 118. Upon insertion of the PAD 128 into the electric component chamber 118, the rod member 128b and outer sheath 128c preferably extend axially through the outlet 118c of the electric component chamber 118 and into the pneumatic chamber 120. Accordingly, the preferred sealing member 130 is an annular gasket disposed about the sheath 128c of the PAD 128 and engaged with the electrical connector 128a. With the PAD and its electrical connector 128a axially secured in the electric component chamber 118, the electrical connector 128a compresses the sealing member 130 in its seat to seal the electric component chamber 118 from the distally disposed inlet ports 122a, 122b and pneumatic chamber 120.
The actuator assembly 100 is shown in
In order to provide the preferably sealed electric component chamber 118 when electrically connected to the terminal connector 400, the inlet 118a at the proximal end of the housing 110 defines a preferred inlet diameter for receiving the plug 404 to form an appropriate fluid/dust tight seal. In the illustrative embodiment of
By sealing the electric component chamber 118 from the pneumatics and their operation, the actuator assembly 100 can more efficiently use the delivered pressurized gas to operate and displace the puncturing assembly 126. More specifically because the electric component chamber 118 is sealed, the pressurized gas delivered to the inlet ports 122a, 122b is completely delivered to the pneumatic chamber without any significant loss in pressure or flow from the inlet ports 122a, 122b. The low or minimal loss in pressure or flow across the preferred actuator assembly 100 can facilitate its interconnection in a preferred daisy-chain or linear connection.
Referring again to the illustrative system 10 of
In one preferred embodiment of a system incorporating the preferred actuator assembly 100, the system preferably includes up to ten actuation assemblies 100. Illustrated in
To facilitate assembly and installation of the actuator assembly 100 itself, the preferred embodiments of the housing 110 preferably include a first housing portion 110a and a second housing portion 110b that are connected to one another in a desired orientation about the actuation axis A-A to define the preferred passageway described herein. The first housing portion 110a is preferably unitary or integrally formed having the proximal portion 112 of the housing including the first preferred sealed electric component chamber 118 and pneumatic ports 122a, 122b. The second housing portion 110b is a separate preferably unitary or integrally formed housing to provide the distal portion 114 of the housing including the discharge port 124. The second housing portion 110b preferably includes a proximal portion for engaging a distal portion of the first housing portion 110a. The proximal portion of the second housing portion 110b preferably defines an annular projection 132 and the distal portion of the first housing portion 110a preferably defines an annular seat 134 for receiving the annular projection to selectively orient the first housing portion 110a with respect to the second housing portion 110b about the actuator axis A-A. A securing nut 136 is preferably disposed about each of the first and second housing portions 110a, 110b to secure the first housing portion 110a to the second housing portion 110b once the housing portions are brought together in their desired relative orientation. Additionally or in the alternative, the first housing portion can define the projection and the second housing portion can define the seat of any geometry provided that the engagement of the housing portions 110a, 110b provides for the desired connection and relative orientation to form the assembly 100.
In the preferred embodiment of the assembly, the preferred second pneumatic chamber 120 is defined by the connection between the first and second housing portions 110a, 110b. For example, the first housing portion 110a can define the proximal portion of the pneumatic chamber to permit insertion and installation of the puncturing assembly 126 therein. The second housing portion 110b can define the distal portion of the pneumatic chamber 120 including the preferred seat 127 for the spring member 125 and the outlet of the pneumatic chamber circumscribed by the seat 127 through which the puncturing pin 126b extends. The passageway 116 defined by the second housing portion can be formed or configured to house other elements to either center or act as a bearing surface to the axially displaced puncturing pin 126b. For example, to center and seal about the puncturing pin 126b, the preferred assembly can include a sealing O-ring and more preferably an O-ring U-cup 129, a retaining ring 133 with a pipe plug 131 sandwiched in between and disposed about the puncturing pin 126b within the passageway 116. In addition, the second housing portion 110b preferably defines a receptacle 138 for axially receiving and securing the sealed fire suppressant cartridge 16. The proximal portion of the receptacle 138 preferably seats a gasket member and more preferably seats a flat gasket ring 19. The receptacle 138 is preferably configured with an internal female thread for engaging a corresponding male thread on the cartridge 16 and bringing the end of the cartridge into contact against and more preferably compress the flat gasket 19. The thread of the receptacle 138 is preferably configured to locate the cartridge 16 at a depth within the receptacle such that axial displacement of the puncturing assembly 126 from the retracted position ruptures the sealed cartridge. The second housing portion 110b includes an outer surface 140 of the housing to define a preferred peripheral geometry that is disposed about the passageway 116 and extend parallel to the actuator axis A-A. The outer peripheral surface 140 preferably includes one or more flat or planar surfaces and more preferably defines a hexagonal peripheral geometry about the actuator axis. The second housing portion 110b also defines a distal end surface 142 of the actuator assembly 100 that is disposed perpendicular to the actuator axis and surrounds the entrance to the receptacle 138.
In preferred embodiments of the actuator assembly 100, the PAD 128 and its rod member 128b remain protracted following electrical actuation and therefore maintain the puncturing assembly 126 in its distally displaced actuated position. Generally, it is desirable to return the puncturing assembly 126 to its initial or retracted position before disconnecting the actuator assembly 100 from an expended cartridge 16 and connecting it to a new pressurized gas cartridge 16. For the preferred assembly 100, the PAD 128 is preferably configured for single use and is to be replaced after an electrical operation in order to return the puncturing assembly 126 to its retracted position. Once the used or actuated PAD 128 is removed, the preferred spring element 125 biases the puncturing assembly 126 to its retracted position. By limiting a preferred removal and installation of a cartridge 16 to require that the puncturing assembly 126 is in its retracted position, the safety of the actuator assembly 100 is enhanced.
In a separate aspect of a preferred actuator assembly, a control element is provided to prevent attachment of a sealed pressurized cartridge to the actuator assembly when the puncturing assembly 126 is in its actuated, axially displaced position. Moreover, the preferred control element is configured to prevent removal of a spent or discharged cartridge before the puncturing assembly 126 is returned to its retracted position. Accordingly, the preferred control element described herein is configured to control the manner in which a pressurized cartridge is coupled to or decoupled from an actuating device. Although the preferred control element is shown and described with respect to the preferred embodiments of an actuator assembly 100 described herein, it should be understood that the control element and its operation is applicable to other actuation assemblies including previously known actuation assemblies in which it is desired to control or limit the manner in which a pressurized or other energized source is coupled to an actuating device. Moreover, the preferred control element is shown and described with respect to a fire system protection application; however, it should be understood that the control element can be used in other applications such as, for example, in the chemical or food processing industries.
Referring now to
In one preferred embodiment of the control element 200, the control element preferably includes a bracket having a first bracket member 200a and at least a second bracket member 200b disposed about the housing 110 and its receptacle 138. Each of the first and second bracket members 200a, 200b have a first bracket portion 204a engaged with the peripheral outer surface 140 of the housing. Each of the bracket members 200a, 200b also preferably includes a second bracket portion 204b angled with respect to the first bracket portion 204a to extend toward and terminate about the actuator axis A-A to define a width X of the first transverse portion of the guide path 202a to limit receipt therein to the grooved coupling portion 16b of the suppressant cartridge 16.
Shown in
Referring to
Again, the preferred guide path 202 only permits the cartridge 16 to be inserted into the receptacle if the puncturing assembly 126 is in its retracted position. Referring now to
While the present invention has been disclosed with reference to certain embodiments, numerous modifications, alterations, and changes to the described embodiments are possible without departing from the sphere and scope of the present invention, as defined in the appended claims. Accordingly, it is intended that the present invention not be limited to the described embodiments, but that it has the full scope defined by the language of the following claims, and equivalents thereof.
This application is a continuation of U.S. application Ser. No. 15/300,767, filed Sep. 29, 2016, which is a national phase application of International Application No. PCT/US2015/023796, filed Apr. 1, 2015, which claims the benefit of priority to U.S. Provisional Application No. 61/974,286, filed Apr. 2, 2014, each of which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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20190358479 A1 | Nov 2019 | US |
Number | Date | Country | |
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61974286 | Apr 2014 | US |
Number | Date | Country | |
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Parent | 15300767 | US | |
Child | 16439397 | US |