1. Field of the Present Invention
The present invention relates generally to self-contained breathing apparatuses, and, in particular, to means for quickly and reliably connecting a cylinder valve to a pressure reducer in such an apparatus.
2. Background
Self-contained breathing apparatuses (“SCBA's”) are commonly worn by individuals when carrying out activities in hazardous environments, such as when fighting fires and in other smoke- or gas-filled environments, in order to provide the wearer with breathable air. Conventional SCBA's generally include a facepiece, one or more pressurized cylinder or tank, and a hose. The facepiece, which covers the wearer's nose, mouth and eyes and includes a lens for external viewing, is supplied with air from the tanks via the hose. The tanks are secured to the wearer's body by a harness.
Each tank has a rated capacity that is typically a standard value, such as 2216 p.s.i.g or 4500 p.s.i.g., meaning that the pressure in the tank, when full, is approximately the rated capacity. A cylinder valve is attached to each tank to permit pressurized air to be released from the tank when desired. An outlet of the cylinder valve is connected to a first stage pressure reducer which typically reduces the pressure of the air from the then-current pressure (which will be the same or lower than the rated capacity) to a lower level, such as 100 p.s.i.g., and from there through the hose to a second stage pressure reducer, often referred to as a breathing regulator, where the pressure is further reduced to a breathable level. However, some designs utilize only a single pressure reducer for reducing the pressure all the way from the high pressure level of the tank to a breathable level.
Tanks are typically stored fully loaded, or charged, with a cylinder valve in place. However, the rest of the components of the SCBA, including the first stage pressure reducer, normally reside on a user's backframe. When the user needs a new tank, he selects one from storage and installs it on his backframe. The cylinder valve is then connected to the first stage pressure reducer by threading a female CGA fitting, which may be located at the end of a hose that is connected to the first stage pressure reducer, or may be mounted on the first stage pressure reducer itself, to a corresponding male CGA fitting of conventional design, such as a CGA 346 or CGA 347 fitting, on the cylinder valve. Such a fitting is present on virtually all cylinder valves because of various safety standards promulgated by NIOSH, NFPA and the like. Once fully threaded, this connection provides an airtight seal that permits fluid communication between the cylinder valve, and thus the tank, and the first stage pressure reducer.
Unfortunately, the fittings typically include a large number of tightly-spaced threads that require a considerable amount of time and effort to rotate fully into place. This has several drawbacks. First, the process of changing a tank becomes time-consuming, even under the best of circumstances. In the emergency situations that the wearers typically operate in, however, this extra time may be critical to saving life or property. Even worse, if a wearer runs out of air while in a hazardous environment, his safe return may depend on being able to connect to another SCBA wearer's tank, or to a spare tank brought by a rescuer. Not only does the amount of time required to change tanks become particularly critical in such a situation, but such an operation often must take place in heavy smoke or other conditions in which the relatively simple process of threading two fittings together becomes quite difficult. For all of these reasons, a quicker, easier connection means for connecting the cylinder valve of a pressure vessel to the pressure reducer of an SCBA is needed.
Of course, if a different type of fitting or connection means is used to provide the connection between the cylinder valve and the pressure reducer, then it may be useful to provide an additional connection point and fluid access to the interior of the cylinder valve and from there to the pressure vessel, the quick connect fitting, or both. Such a fitting and path could be used to connect an auxiliary air tank to the user's pressure vessel, or to reload the user's regular pressure vessel, without having to disconnect the vessel and cylinder valve from the pressure reducer or remove the SCBA or pressure vessel from his back. Such a connection could bypass the handwheel-controlled valve of the quick connect fitting, making it easier to create air flow into the cylinder valve. In addition, the existence of fittings of two different types provides extra flexibility in connecting the cylinder valve, and further maintains a conventional connection point even if a quick connect fitting is provided. Unfortunately, because known pressure vessels have not heretofore faced such issues, no known pressure vessels provide such an auxiliary fitting.
Another significant consideration when connecting a loaded pressure vessel to a pressure reducer is the pressure present in the vessel. It is important to ensure that a vessel of the proper capacity is connected to the pressure reducer. Conventional pressure reducers are equipped to handle only a single pressure capacity, or have additional functionality that becomes inoperative or improperly operated when used with a pressure vessel of the wrong capacity. In some cases, a higher-than-expected pressure may cause damage to the pressure reducer, while a lower-than-expected pressure may fool the user into thinking that he has more air left than he does. For these reasons and others, a need exists for either a mechanism that prevents a cylinder valve connected to a pressure vessel of a given capacity from being connected to a pressure reducer unless the capacity of the pressure vessel matches the pressure reducer, or a mechanism for permitting a pressure reducer to operate properly with pressure vessels of differing capacities.
Modern SCBA's are increasingly making use of electronics to carry out additional functionality. An example of such an electronics system is disclosed in the commonly-assigned U.S. patent application Ser. No. 10/744,901, entitled “PERSONAL MULTIMEDIA COMMUNICATION SYSTEM AND NETWORK FOR EMERGENCY SERVICES PERSONNEL,” the entirety of which is incorporated herein by reference. Unfortunately, existing cylinder valve/pressure reducer connections are unable to communicate with any such electronics system because they include no mechanical/electrical interface for signaling a successful connection to the electronics system. Similarly, even if a pressure reducer capable of handling pressure vessels of more than one different capacity were available, there is no known means of signaling the electronics system as to which type of pressure vessel were connected to the pressure reducer. Of course, on an even simpler level, it may be important to signal the wearer or another user directly as to whether a successful connection has been made between the cylinder valve and the pressure reducer, particularly if a quick connect mechanism such as the one described herein is used. Thus, a further need exists for a simple interface for signaling an SCBA electronics system as to whether a successful connection has been made or as to the capacity of the tank that has been connected to the pressure reducer, or for triggering an audible or visible alarm based on whether a successful connection has been made.
In general, then, a need exists for a quick connect pressure reduction assembly and cylinder valve that may be utilized more quickly and more easily than existing designs and that provides additional functionality over that available with such designs.
The present invention comprises a quick connect cylinder valve and pressure reducer for use in a self-contained breathing apparatus, and includes a cylinder valve and a pressure reducer. The assembly further includes a probe, preferably disposed in the cylinder valve, that has a probe tip and a circumferential notch, and an inlet/latch assembly, preferably disposed in the pressure reducer, that includes a probe tip receptacle for accommodating the probe tip, a pair of latches, each having a shoulder at one end, a grip at the other, and an opening disposed therebetween, and a pair of latch lock pins, operable, in response to a threshold fluid pressure, to be slidably positioned within the openings in the latches. The probe tip may be retained in the probe tip receptacle by positioning the latch shoulders in the circumferential notch, and once the cylinder valve is opened and pressurized gas of a threshold level is flowing therethrough, the latch lock pins prevent the latches from being opened, thereby preventing the probe tip from being withdrawn from the probe tip receptacle.
The present invention further includes an electrical assembly having a pushbutton switch for activating an electronics system, which may include or consist of an audible alarm generator, in the self-contained breathing apparatus. The pushbutton switch is arranged in the inlet/latch assembly such that when the probe tip is latched properly in the probe tip receptacle, the pushbutton switch is depressed, thus activating the electronics system. When the probe tip is not latch properly in the probe tip receptacle, the pushbutton switch is not depressed, thus deactivating the electronics system. In its simplest embodiment, the electronics system is simply an audible alarm generator. However, much more complex electronics may be available, such as that described in the aforementioned U.S. patent application Ser. No. 10/744,901.
Broadly defined, the present invention according to one aspect is a quick connect cylinder valve and pressure reducer for use in a self-contained breathing apparatus, including: a cylinder valve that connects to a pressure vessel; a pressure reduction assembly; a probe having a notch in the side thereof and a threadless probe tip, the probe defining an axis; and an inlet/latch assembly, having a probe tip receptacle for accommodating the probe tip, and a latch, having a shoulder adapted to fit into the notch in the side of the probe and arranged to move transversely relative to the axis of the probe; wherein the probe tip may be retained in the probe tip receptacle, thereby creating an air path between the cylinder valve and the pressure reduction assembly, by positioning the latch shoulder in the notch.
In features of this aspect, the notch is a circumferential notch; the at least one latch is a pair of latches, each having a shoulder adapted to fit into the circumferential notch; the inlet/latch assembly further includes a spring that biases the latch shoulder toward the notch; the probe tip is tapered so as to force the spring-biased latch aside as the probe tip is inserted into the probe tip receptacle; the at least one spring-biased latch includes a grip adapted for manipulation by a user to release the probe tip from the latch shoulder; the inlet/latch assembly further includes an additional spring that forces the probe tip at least partly out of the probe tip receptacle upon release of the probe tip from the latch shoulder; the latch has an opening disposed therein, and wherein the inlet/latch assembly further includes a latch lock pin operable, in response to a threshold fluid pressure, to be slidably positioned within the opening in the latch; the latch lock pin is subjected to the pressure of air entering the reducer through the inlet; the latch lock pin is biased away from the opening in the latch, thereby releasing the latch when the pressure of the air entering the reducer through the inlet is insufficient to overcome the biasing force; and the threshold fluid pressure is approximately 50 p.s.i.g.
According to another aspect, the present invention is a method of coupling a pressure vessel into a self-contained breathing apparatus, including: providing a cylinder valve attached in fluid communication with a pressure vessel; providing a pressure reduction assembly; providing a probe, attached in fluid communication with either the cylinder valve or the pressure reduction assembly, having a notch in the side thereof and a threadless probe tip, the probe defining an axis; providing an inlet/latch assembly, attached in fluid communication with the other of the cylinder valve and the pressure reduction assembly, having a probe tip receptacle, with an entrance, for accommodating the probe tip, and a latch, with a shoulder adapted to fit into the notch in the side of the probe and arranged to move transversely relative to the axis of the probe; and positioning the probe tip at the entrance of the probe tip receptacle; with the latch shoulder in an open position, inserting the probe tip into the probe tip receptacle; and once the probe tip is fully inserted into the probe tip receptacle, moving the latch shoulder toward the probe until the latch shoulder is positioned in the notch, thereby retaining the probe tip within the probe tip receptacle and establishing fluid communication between the pressure reduction assembly and the cylinder valve.
In features of this aspect, the movement of the latch shoulder toward the probe occurs in a first direction, and the method further includes, before inserting the probe tip into the probe tip receptacle, moving the latch shoulder in a second direction, the second direction being opposite the first direction, to the open position; the method further includes, upon establishing fluid communication between the pressure reduction assembly and the cylinder valve, opening the cylinder valve, thereby supplying pressurized air to the pressure reduction assembly; and the method further includes, upon supplying pressurized air to the pressure reduction assembly, applying air pressure to a latch lock pin, thereby overcoming a counteracting bias and causing the latch lock pin to move into an interlocked relationship with the latch.
In another aspect, the present invention is a universal cylinder valve and pressure reducer for use in a self-contained breathing apparatus, including: a cylinder valve that connects to a pressure vessel; a pressure reduction assembly; a first probe having a probe tip of a first length; a second probe having a probe tip of a second length, the second length being different from the first length; and an inlet/connector assembly, having a probe tip receptacle adapted to receive the probe tip of the first probe at a first depth therein and to establish a fluid connection therewith, and further adapted to receive the probe tip of the second probe at a second depth therein and to establish a fluid connection therewith, and a connector adapted to retain the first probe at the first depth when the first probe is inserted in the probe tip receptacle, and adapted to retain the second probe at the second depth when the second probe is inserted in the probe tip receptacle.
In features of this aspect, the first probe and the second probe are each mountable to the cylinder valve, and the inlet/latch assembly is connected to the pressure reducer; the connector is a latch; each of the first and second probes includes a notch, and the latch includes a latch shoulder configured to fit into the notch of the probe that is inserted in the probe tip receptacle; each notch is disposed in the side of the respective probe, the probe defines a central axis, and the latch shoulder is movable in a direction transverse to the central axis of the probe; the connector is a threaded fitting; the inlet/latch assembly includes an inlet nozzle disposed in the probe tip receptacle; the first and second probes each include a hollow in the respective probe tip thereof, each hollow being adapted to receive the distal end of the inlet nozzle when the respective probe is inserted into the probe tip receptacle; the inlet/latch assembly further includes a disk coaxially arranged around the inlet nozzle; and the disk is spring-loaded.
In another aspect, the present invention is a method of coupling a pressure vessel into a self-contained breathing apparatus, including: designating a first probe size for use with pressure vessels of a first rated capacity; designating a second probe size for use with pressure vessels of a second rated capacity, the first and second probe sizes being different from one another; providing a pressure vessel having a known rated capacity, the known rated capacity being either the first rated capacity or the second rated capacity; providing a cylinder valve having a probe of a size selected to correspond with the rated capacity of the pressure vessel; and providing a pressure reducer that includes an inlet assembly, having a probe tip receptacle, adapted to receive the probe tip of the probe, regardless of whether the size of the probe is the first probe size or the second probe size, and to establish a fluid connection therewith.
In features of this aspect, the method further includes receiving, in the probe tip receptacle, the probe tip of the provided probe, regardless of whether the size of the probe is the first probe size or the second probe size; and establishing a fluid connection between the pressure reducer and the pressure vessel via the inlet assembly and the probe; the method further includes automatically controlling the operation of the pressure reducer at least partly on the basis of the size of the probe whose tip is received in the probe tip receptacle; providing a cylinder valve having a probe includes providing a cylinder valve having a probe that has a threadless probe tip; the pressure vessel is of the first rated capacity and the probe is of the first probe size; the probe is a first probe and the pressure vessel is a first pressure vessel, and the method further includes removing the first probe from the probe tip receptacle of the inlet assembly, providing a second pressure vessel, the second pressure vessel being of the second rated capacity, providing a cylinder valve having a second probe of the second probe size, receiving, in the probe tip receptacle, the probe tip of the second provided probe, and establishing a fluid connection between the pressure reducer and the second pressure vessel via the inlet assembly and the second probe; providing a cylinder valve having a second probe includes providing a cylinder valve having a second probe that has a threadless probe tip; and the pressure vessel is of the second rated capacity and the probe is of the second probe size.
In yet another aspect, the present invention is a universal pressure reducer for a self-contained breathing apparatus, including: an inlet adapted to couple the universal pressure reducer to a cylinder valve connected to a pressure vessel of a rated capacity; a primary reducer module in fluid communication with the inlet; a pneumatic alarm mechanism; a pneumatic transfer valve assembly that controls the actuation of the alarm mechanism by controlling the flow of pressurized air thereto, wherein the transfer valve assembly is arranged to actuate the alarm mechanism when the pressure of air entering the reducer through the inlet drops to a trigger level that is automatically selected from at least a first predetermined level and a second predetermined level, the trigger level being set to the first predetermined level if the inlet is coupled to a cylinder valve connected to a pressure vessel of a first rated capacity, and being set to a second predetermined level if the inlet is coupled to a cylinder valve connected to a pressure vessel of a second rated capacity, the first and second rated capacities being different from one another and the first and second predetermined levels being different from one another.
In features of this aspect, the universal pressure reducer further includes a selector valve assembly that automatically controls the actuation of the transfer valve assembly on the basis of the rated capacity of the pressure vessel connected to the cylinder valve to which the inlet is coupled; the selector valve assembly controls the actuation of the transfer valve assembly by controlling the flow of pressurized air thereto; the selector valve assembly is arranged to permit the flow of pressurized air from the inlet to the transfer valve assembly at a first flow volume if the pressure vessel is of the first rated capacity and at a second flow volume if the pressure vessel is of the second rated capacity, the first and second flow volumes being different from one another; the universal pressure reducer further includes a secondary reducer module; the selector valve assembly is controlled mechanically; the selector valve assembly is adjustable between at least two positions, and wherein operation of the selector valve assembly to control actuation of the transfer valve assembly is based on the position of the selector valve assembly; adjustment of the position of the selector valve assembly is caused by coupling the inlet to the cylinder valve; the selector valve assembly is controlled electrically; movement of the selector valve assembly is caused by a motor; the motor is controlled by a pushbutton switch triggered when the inlet is coupled to the cylinder valve; the first predetermined level is ¼ of the first rated capacity, and the second predetermined level is ¼ of the second rated capacity; the transfer valve assembly is controlled electrically; the universal pressure reducer further includes a motor operable to assist pneumatic control of the transfer valve assembly.
In another aspect, the present invention is a method of coupling a pressure vessel into a self-contained breathing apparatus, including: designating a first probe size for use with pressure vessels of a first rated capacity; designating a second probe size for use with pressure vessels of a second rated capacity, the first and second probe sizes being different from one another; providing a pressure vessel having a known rated capacity, the known rated capacity being either the first rated capacity or the second rated capacity; providing a cylinder valve having a probe, having a threadless probe tip, of a size selected to correspond with the rated capacity of the pressure vessel; and providing a pressure reducer that includes an inlet assembly, having a probe tip receptacle, configured to receive the probe tip of a probe of one or the other of the first probe size and the second probe size, but not both, and establish a fluid connection therewith, and further configured to prevent the establishment of a fluid connection with a probe of the other probe size.
In features of this aspect, the method further includes sliding the probe into the probe tip receptacle, thereby establishing the fluid connection between the pressure reducer and the probe; and the method further includes latching the probe in place in the probe tip receptacle.
In still another aspect, the present invention is a self-contained breathing apparatus, including: a tank having an outlet; a cylinder valve mounted at the outlet of the tank; a pressure reducer; a probe having a probe tip; an inlet/latch assembly having a probe tip receptacle; and an electrical assembly having a pushbutton switch arranged in the inlet/latch assembly and actuated by the insertion of the probe tip into the probe tip receptacle.
In features of this aspect, the pushbutton switch controls the transmission of at least one electrical signal to an electronics system when the probe tip is successfully latched in the probe tip receptacle; the probe is carried on the cylinder valve; wherein the inlet/latch assembly is carried on the pressure reducer; the inlet/latch assembly further includes a contact member, disposed within the inlet-latch assembly and adapted to be inwardly displaced, thereby actuating the pushbutton switch, when the probe tip is inserted into the probe tip receptacle; the contact member is a disk having a skirt; the inlet/latch assembly further includes an inlet nozzle, and the disk is coaxially arranged around the inlet nozzle; the disk is spring-loaded; the spring-loaded disk causes the probe tip to be outwardly biased when inserted into the probe tip receptacle; and the pushbutton switch and the contact member are configured such that the pushbutton switch is actuated only when the contact member is inwardly displaced by a predetermined distance, the predetermined distance corresponding to the displacement caused when the probe tip is successfully latched in the probe tip receptacle.
In another aspect, the present invention is a self-contained breathing apparatus, including: a tank having an outlet and a rated capacity for pressurized air; a cylinder valve mounted at the outlet of the tank; a pressure reducer; an electronics system; and an electrical assembly that transmits a signal to the electronics system when the cylinder valve is connected to the pressure reducer.
In features of this aspect, the signal transmitted by the electrical assembly to the electronics system is indicative of a successful connection between the cylinder valve and the pressure reducer; the electrical assembly is arranged to transmit a signal only when the cylinder valve is successfully connected to the pressure reducer; the electrical assembly is arranged to transmit a first signal when the cylinder valve is successfully connected to the pressure reducer, and a second signal when the cylinder valve is not successfully connected to the pressure reducer; the electrical assembly includes a pushbutton switch that is actuated by the cylinder valve; the cylinder valve includes a probe that actuates the pushbutton switch when the cylinder valve is successfully connected to the pressure reducer; the signal transmitted by the electrical assembly to the electronics system is indicative of the capacity of the tank; the electrical assembly is arranged to transmit a signal only when the tank to which the cylinder valve is mounted is of a first capacity, and is arranged not to transmit a signal when the tank to which the cylinder valve is mounted is of a second capacity, the first and second capacities being different from one another; the electrical assembly is arranged to transmit a first signal when the tank to which the cylinder valve is mounted is of a first capacity, and a second signal when the tank to which the cylinder valve is mounted is of a second capacity; the electrical assembly includes a pushbutton switch that is actuated by the cylinder valve; the cylinder valve includes a probe that actuates the pushbutton switch when the cylinder valve is successfully connected to the pressure reducer; and the electronics system includes an audible alarm generator activated and deactivated by the pushbutton switch.
In still another aspect, the present invention is a breathing air tank and valve assembly for use in a self-contained breathing apparatus, including: a pressure vessel; and a cylinder valve for connection to the pressure vessel, the cylinder valve including a valve body having an interior; a first fitting adapted to connect the valve body directly to the pressure vessel, thereby creating a fluid connection to the interior of the valve body; a second fitting, the second fitting being an outlet adapted to connect the valve body to a pressure reducer assembly; a valve assembly adjustable between at least an open state and a closed state, wherein in the open state, an air path exists from the pressure vessel through the interior of the valve body to the second fitting, and in the closed state, no air path exists from the pressure vessel through the interior of the valve body to the second fitting; and a third fitting, the third fitting being an inlet, having a check valve, adapted to connect the valve body to an external source of pressurized air, thereby providing a direct air path from the external source of pressurized air through the interior of the valve body to the pressure vessel.
In features of this aspect, the second fitting is a quick-connect probe for threadless connection to a pressure reducer assembly; the third fitting includes a conventional threaded fitting for connection to the external pressurized air source; the third fitting is a CGA-type fitting; the direct air path from the external pressurized air source through the interior of the valve body to the pressure vessel exists regardless of whether the valve assembly is in its open state or its closed state; the valve assembly includes a handwheel for adjusting the valve assembly between its open state and its closed state; the quick-connect probe includes a probe tip and a notch interposed between the probe tip and the valve body; the notch is a circumferential notch; the quick-connect probe may be temporarily connected to the valve body by a threaded fitting; and the quick-connect probe is permanently connected to the valve body.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
Further features, embodiments, and advantages of the present invention will become apparent from the following detailed description with reference to the drawings, wherein:
Referring now to the drawings, in which like numerals represent like components throughout the several views, the preferred embodiments of the present invention are next described. The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
In addition, the SCBA preferably includes an electronics system (not shown). In its simplest embodiment, the electronics system is simply an audible alarm generator. The audible alarm generator may be triggered under certain conditions, such as described hereinbelow. However, much more complex electronics may be available, such as that described in the aforementioned U.S. patent application Ser. No. 10/744,901.
The CGA assembly 30 includes a threaded male fitting 44, best seen in
As perhaps best shown in
As perhaps best shown in
Also as shown in
Referring again to
The dimensions of the probe 86 and its various features may be varied as desired. However, changes in the dimensions or design of the probe 86 may need to be coordinated with corresponding changes in the dimensions or design of portions of the pressure reducer 24, as will become apparent below. Optionally, a set of probes 86 having different dimensions may be developed such that each differently-sized or -shaped probe 86 is intended for use only with tanks 12 of a particular capacity or pressure level. For example, a longer, narrower probe could be intended for use with a 4500 p.s.i.g.-rated tank 12, while a shorter, thicker probe 86 could be intended for use with a 2216 p.s.i.g.-rated tank 12. These dimensional changes may be coordinated by dimensional changes in particular elements of the pressure reducer 24 for a purpose more fully described hereinbelow.
Referring again to
The quick charge assembly 140 provides an alternative means for supplying high pressure breathing gas to the central supply conduit 112 to be distributed through the pressure reducer 24 to the user. It is anticipated that such a feature would typically be used during emergency situations, where the tank 12 connected to the cylinder valve 22 is empty or malfunctioning and there is no time to replace or repair it. As perhaps best shown in
Referring again to
Referring again to
The latches 192, 193 are arranged transversely within the inlet/latch assembly 190 and include respective latch shoulders 198, 199 adapted to fit within the circumferential notch 96 in the probe 86. Springs 189 are provided to bias the two latches 192, 193 toward each other. Bearings 48, preferably formed from a self-lubricating material, are provided on the latches 192, 193. In addition, as perhaps best seen schematically in FIGS. 18–21, an opening is disposed in the body of each latch 192, 193 to accommodate one of the latch lock pins 204 as next described.
The latch lock pins 204 are oriented perpendicularly relative to the latches 192, 193 and arranged to be coaxial with correspondingly-shaped and -sized openings in the latches 192, 193 when the latches 192, 193 are in their normal biased positions. However, a compression spring 206 is arranged around each latch lock pin 204 in order to bias the pins 204 away from the latches 192, 193, thereby permitting the latches 192, 193 to be moved transversely when sufficient forces are exerted thereon. The latch lock pins 204 reside in bores in the inlet/latch assembly 190 which are in fluid communication with the central supply conduit 112 via connector conduits 114, 115, thus permitting the distal ends of the latch lock pins 204 to be subjected to the same gas pressure as is supplied to the central supply conduit 112. The latch lock pins 204 are equipped with a packing 210, held in place by a packing retainer 208 and coated with a lubricant, in order to ensure a tight seal. The compression springs 206 are preferably selected and installed so as to be overcome when a relatively nominal threshold pressure, which for example may be 50 p.s.i.g., is applied to the distal ends of the pins 204. Thus, when a gas pressure of more than the threshold exists in the central supply conduit 112, the proximate ends of the pins 204 are forced into the openings in the latches 192, 193, thus preventing the latches 192, 193 from being moved. As a result, the latches 192, 193 are locked in place whenever the threshold gas pressure exists in the system, thus providing an important safety feature in the operation of the probe 86 and latches 192, 193.
The inlet/latch assembly 190 is further equipped with a spring-loaded nipple disk 196 adapted to provide an additional seal between the probe tip 93 and the inlet nozzle 194. The nipple disk 196 preferably includes an integral skirt, perhaps best seen in
The shape and dimensions of the elements of the various elements of the inlet/latch assembly 190 are selected to correspond to the shape and dimensions of the probe 86. However, as described previously, it may be desirable to develop a set of probes 86 having different dimensions or shape such that each differently sized or shaped probe 86 is intended for use only with tanks 12 of a particular capacity or pressure level. In this case, changes in the size or shape of the probe 86 are preferably coordinated with corresponding changes in the arrangement of the inlet/latch assembly 190. The dimensional variations in both probes 86 and inlet/latch assemblies 190 for different tank capacities are preferably significant enough such that a probe 86 intended for use with one capacity level cannot be used in an inlet/latch assembly 190 that is intended for use with a different capacity level. For example, referring back to the exemplary probes 86 described previously, the long, narrow probe 86 may be too long to be latched between the latches 192, 193, while the short, thicker probe 86 may be too wide to fit in the probe tip receptacle 197. Such a feature prevents a tank 12 of the wrong capacity from being used accidentally. This may prevent damage to the pressure reducer 24 or injury to a user, and may further prevent a user from believing that the tank 12 being utilized in his SCBA 10 has a higher capacity than it does.
Although perhaps less desirable because of the increased connection time involved, it will be apparent that the use of probes of different dimensions, corresponding to different pressure vessel capacities, may also be applied to other types of probe connectors. For example, instead of a circumferential notch retained between two spring-loaded latches, a probe (not shown) could utilize a more conventional threaded male CGA fitting from which extends a probe tip similar to those described herein, and a probe tip receptacle could be provided with a corresponding threaded female CGA fitting. Probe tips of different lengths could then be configured to extend a greater or lesser depth into the probe tip receptacle, depending on the placement of the threaded fitting relative to the probe tip. Such a configuration would permit the use of the “universal pressure reducer” concept described herein, but would make it more difficult to connect or disconnect the probe from the inlet/latch assembly.
Referring to
The button on the switch 212 is positioned relative to the cavity containing the nipple disk 196 such it lies at the periphery of the path of motion taken by the nipple disk 196 as it moves back and forth along the inlet nozzle 194. Thus, when the nipple disk 196 is forced rearward by the probe tip 93, the skirt of the disk 196 makes contact with the button on the switch 212, thereby depressing the button and actuating the switch 212. Preferably, the switch 212 and nipple disk 196 are arranged such that when the probe tip 93 is fully inserted in the probe tip receptacle 197, the nipple disk 196 remains in contact with the button on the switch 212, thus keeping the switch 212 actuated. A signal indicating that the probe tip 93 is engaged in the inlet/latch assembly 190 is thus transmitted along the switch wire 129, the cable connector assembly 131 and a corresponding cable (not shown) to the SCBA electronics system. When the probe tip 93 is removed from the receptacle 197, the spring 200 forces the disk 196 back forward, releasing the switch button and deactuating the switch 212.
To use the quick connect valve and pressure reducer 20, the cylinder valve 22 is first installed on a breathing air tank 12 by threading the male fitting 41 into a corresponding female fitting on the tank 12 and charging (pressurizing) the tank 12. For convenience, a plurality of loaded tanks 12 may be stored with cylinder valves 22, each with an appropriately-sized probe 86, already installed. When a tank 12 is needed, the assembled tank 12 and cylinder valve 22 may be positioned such that the probe 86 is aligned with the probe tip receptacle 197, and then the probe tip 93 may be inserted therein. As the probe tip 93 encounters the latch shoulders 198, 199, the latches 192, 193 tend to be forced outward, thereby permitting the probe tip rim 94 to pass between the latch shoulders 198, 199. Additional resistance is encountered when the probe tip 93 encounters the nipple disk 196, which is biased by the compression spring 200. When force sufficient to overcome the spring 200 is applied to the probe 86, the probe tip 93 may move deeper into the inlet/latch assembly 190 until the tip rim 94 passes the latch shoulders 198, 199, thereby permitting the shoulders 198, 199 to snap into place in the circumferential notch 96. The latches 192, 193 are held in place in that position by the force of the latch springs 189, thus capturing and retaining the probe 86 within the probe tip receptacle 197.
As long as the probe tip 86 is retained in the probe tip receptacle 197 as described above, the nipple disk 196 is maintained in continuous contact with the activation button on the switch 212 of the electrical assembly 130, thereby activating it. The switch 212 thus provides the SCBA electronics system with an electrical indication that a probe 86, and implicitly an assembled air tank 12 and cylinder valve 22, are installed in the pressure reducer 24. The SCBA electronics system, whether it may be a simple audible alarm generator or a more complex electronic device, may then operate accordingly.
Once the pressure reducer 24 has been connected to the cylinder valve 22, the entire assembly is ready for operation. The tank 12, quick connect valve and pressure reducer 20 and other equipment are loaded on the user's back using a backpack, harness and the like, and the facepiece 16 is placed over the user's face such that it covers the user's mouth, nose or both, in conventional fashion. The hose assembly 18 is arranged to extend comfortably between the pressure reducer 24 and the facepiece 16, without interfering with the user's natural movements. The cylinder valve 58 may be opened by manually turning the handle 49 of the valve assembly 32 as described above, thereby permitting breathing gas to flow through the cylinder valve 22 and into the inlet nozzle 194 of the pressure reducer 24.
Breathing gas passes through the pressure reducer 24 as follows.
Further operation of the pressure reducer 24 may proceed according to conventional principles.
It is extremely desirable, and is in fact required by NIOSH and NFPA standards, for an alarm to be generated once pressure in the tank 12 drops below a predetermined level, which is preferably ¼ of the maximum capacity. This alarm may use the audible alarm generator described previously, or may be a separate alarm. Use of the transfer valve 160 to trigger such an alarm may be easily accomplished by designing the various components of the pressure reducer 24, and particularly the transfer valve assembly 124, such that the transfer valve 160 opens at the desired pressure level. This may be accomplished using a conventional balanced piston with cylinder pressure on one side and reducer pressure on the other. When pressure in the tank 12 depletes to ¼ capacity, the transfer valve 160 shifts allowing secondary reducer pressure to flow to an alarm mechanism.
The SCBA 10 may be used as described above until either the tank 12 is empty (or at least empty enough that the pressure in the system drops below the predetermined nominal pressure) or until the cylinder valve 22 is closed by turning the handle 49 as described above, thereby shutting off the flow of air from the tank 12. Once the pressure in the central supply conduit 112 drops below the threshold level described above, the compression springs 206 on the latch lock pins 204 force the pins 204 away from the openings in the latches 192, 193, thereby unlocking them. The probe 86 may then be removed from the probe tip receptacle 197 by grasping the latches 192, 193 and pulling them apart with sufficient force to overcome the latch springs 189, thereby releasing the probe 86 from the latch shoulders 198, 199. Upon its release from the latches 192, 193, the probe 86 is then ejected by the force of the compression spring 200 acting on the nipple disk 196. Once the probe 86 has been withdrawn from the pressure reducer 24, the cylinder valve 22 and tank 12 may, if desired, be replaced by a full tank 12 and valve 22 so as to permit the user to continue working with a fresh supply of air, or the components may be cleaned, stored, repaired or the like.
Alternatively, the tank 12 may be recharged without removing the probe 86 from the pressure reducer 24. This may be accomplished via the CGA assembly 30 by simply connecting a supply line having a corresponding female CGA fitting to the CGA assembly. The check valve opens, and air may be forced directly into the tank 12 with the valve assembly 32 in its closed position. Alternatively, if the valve assembly 32 is adjusted to its open position, pressurized air may be forced directly through the probe 86 into the pressure reducer 24.
The transfer valve assembly 361 includes a collection of conventional components, including a valve 360 and a valve sleeve 362. As described below, the size and pressurization of the transfer valve assembly 361 determines when a predetermined alarm will sound to alert the wearer that only ¼ of the original capacity of the pressure vessel 12 remains. The valve 360 includes two sections or stages 364, 365, wherein the second valve stage 365 has a larger cross-section than that of the first valve stage 364 for a purpose made evident below.
The manifold assembly 380, which is generally similar in design and function to the previously described manifold assembly 180, is attached to the pressure reduction assembly 310 with a plurality of screws 391. The inlet/latch assembly 390, which may be attached to the front of the pressure reduction assembly 310 via a plurality of screws 391, primarily includes a probe tip receptacle 397, a pair of latches 392, 393, an inlet nozzle 394 and a nipple disk 396. Each latch 392, 393 has a respective latch shoulder 398, 399. The function and design of inlet/latch assembly 390 is likewise generally similar to that of inlet/latch assembly 190.
Referring to
On the other hand, when a probe 86 of a second set of predetermined dimensions (designated, for example, for specific use with a 4500 p.s.i.g. pressure vessel 12) has been inserted, it also contacts and displaces the nipple disk 396, as described previously, but the displacement is not as great as with the probe 86 of the first dimensions. As a result, the disk 396 does not make contact with the switch 312 or the pushrods 350. Because the pushrods 350 do not move, the selector valve assembly 332 remains seated. Thus, the second conduit 316 is vented to atmosphere, and only the first conduit 315 and one stage 364 of the transfer valve 360 are pressurized. Therefore, pressure is only supplied to the first transfer valve section 364, which shifts once pressure in the tank 12 drops to ¼ of the 4500 p.s.i.g. capacity, which in turn allows secondary reducer pressure to flow to the alarm mechanism mentioned previously. In other words, the selector valve assembly 332 ensures that the pressure reducer 324 automatically recognizes the tank capacity and causes the proper stage or stages of the transfer valve 360 to shift, thus triggering the alarm mechanism, at ¼ of the tank capacity regardless of whether the capacity is 2216 p.s.i.g. or 4500 p.s.i.g.
In addition, because the disk 396 does not make contact with the switch 312, no signal is sent to the electronics system. The absence of a signal thus indicates to the electronic system that a probe 86 corresponding to a 4500 p.s.i.g. pressure vessel 12 has been inserted. Of course, the pressure levels may be varied, and the active signal may be used to represent a higher capacity and the absence of a signal the lower capacity. However, if it is desired that an active signal (rather than the absence of a signal) is always used to indicate the capacity level of the pressure vessel 12, it will be apparent to those of ordinary skill in the art that a second switch may be included, or the switch 312 may be replaced with a more complicated switch, in order to trigger such a signal. It will also be apparent that such a scheme may be further expanded to include more than two different pressure capacities, such as a 2216 p.s.i.g. capacity, a 3000 p.s.i.g. capacity, and a 4500 p.s.i.g. capacity. Finally, it will be apparent that the switch 312 may also be used to electronically trigger operation of the transfer valve assembly 361 through the inclusion of a small motor (not shown) or the like. Such an approach may either be used to assist pneumatic control of the transfer valve assembly 361 directly, or may be used to control operation of the selector valve assembly 332, thereby controlling the transfer valve assembly 361 indirectly. The mechanical approach, however, is preferred because of its ruggedness and simplicity of operation and service.
Based on the foregoing information, it is readily understood by those persons skilled in the art that the present invention is susceptible of broad utility and application. Many embodiments and adaptations of the present invention other than those specifically described herein, as well as many variations, modifications, and equivalent arrangements, will be apparent from or reasonably suggested by the present invention and the foregoing descriptions thereof, without departing from the substance or scope of the present invention. Accordingly, while the present invention has been described herein in detail in relation to its preferred embodiment, it is to be understood that this disclosure is only illustrative and exemplary of the present invention and is made merely for the purpose of providing a full and enabling disclosure of the invention. The foregoing disclosure is not intended to be construed to limit the present invention or otherwise exclude any such other embodiments, adaptations, variations, modifications or equivalent arrangements; the present invention being limited only by the claims appended hereto and the equivalents thereof. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for the purpose of limitation.
This application is entitled to the benefit of, and claims priority to, provisional U.S. Patent Application Ser. No. 60/485,211 filed Jul. 4, 2003 and entitled “QUICK CONNECT PRESSURE REDUCER FOR SELF-CONTAINED BREATHING APPARATUS,” the entirety of which is incorporated herein by reference.
Number | Name | Date | Kind |
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2288565 | Green | Jun 1942 | A |
2406888 | Meidenbauer, Jr. | Sep 1946 | A |
3744526 | MacNiel | Jul 1973 | A |
4328798 | Isaacson | May 1982 | A |
4714077 | Lambert | Dec 1987 | A |
4974584 | Goodnoe | Dec 1990 | A |
5213095 | Dague | May 1993 | A |
5687712 | Semeia | Nov 1997 | A |
5738088 | Townsend | Apr 1998 | A |
6484724 | Sloan | Nov 2002 | B1 |
6901958 | Taylor | Jun 2005 | B2 |
Number | Date | Country | |
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60485211 | Jul 2003 | US |