Abstract: A pneumatic wheel and tire assembly equipped with a brake heat sink is protected from overpressure due to increased internal inflation gas temperature, caused by increased temperature of the brake heat sink, by installing a thermally activated fuse plug having a fuse in the wheel structure such that the fuse extends beyond the wheel structure towards the brake heat sink.

Abstract: Apparatus for venting a container containing a fluid and including a poppet mounted to the bottom of a cap or flap mounted to a housing for being mounted to the container, a fastener for fastening the cap of flap to the housing and which fastener may be a fusible fastener for unfastening the cap or flap and for venting the container to the atmosphere upon heat applied externally to the container reaching a predetermined temperature. The poppet venting the container to the atmosphere upon the pressure in the container reaching a predetermined pressure and the poppet may be a combination poppet for venting the container to the atmosphere upon pressure in the container reaching a predetermined pressure and for venting the container to the atmosphere upon a vacuum in the container reaching a predetermined vacuum.

Abstract: A safety apparatus is disclosed to include a main body having a chamber, a pin installed in the chamber, and a thermally-sensitive fragile member. The chamber has a top opening, a bottom opening and through holes communicating with outside. A supporting piece is mounted inside the chamber adjacent to the bottom opening. The pin has a base portion and a body portion which is fit with a spring and runs through the top opening of the main body. The thermally-sensitive fragile member has an end positioned on the supporting piece and the other end holding against the pin. When the thermally-sensitive fragile member is shattered at a predetermined temperature, the pin will be driven by a rebounding resilience of the spring to move inwardly into the chamber. The safety apparatus is completely properly for use in a gas switch and a fire alarm device.

Abstract: An actuator assembly and method for making and using an actuator assembly. In one embodiment, the assembly includes an actuator body having an actuator channel with a first region and a second region. An actuator is disposed in the actuator channel and is movable when in a flowable state between a first position and a second position. A heater is positioned proximate to the actuator channel to heat the actuator from a solid state to a flowable state. A source of gas or other propellant is positioned proximate to the actuator channel to drive the actuator from the first position to the second position. The actuator has a higher surface tension when engaged with the second region of the channel than when engaged with the first region. Accordingly, the actuator can halt upon reaching the second region of the channel due to the increased surface tension between the actuator and the second region of the channel.

Abstract: The valve is intended to be opened at a predetermined temperature in order to release the pressurized fluid from the tank and its opening is triggered by melting of a meltable material. It comprises a body in the shape of a socket (10), the open end of which is exposed to the gas pressure and the bottom of which is closed except for a minuscule orifice (12). The side wall of the body (10) comprises at least one radial opening (14) and the body (10) is engaged, by its bottom, by sliding, in a cap (16) of complementary shape and is fastened thereto by means of the meltable material (18). The cap (16) comprises at least one access (20) to the atmosphere and, after melting of the meltable material (18), can be moved with respect to the body (10) until each access (20) communicates with a side opening (14) in the body (10).

Abstract: A pressure relief apparatus includes a valve having a body. A shaft is rotatably disposed in the body and has an exterior end extending through the body. A plug, which may contain an internal passageway, is mounted on the shaft and is disposed in the fluid flowpath. The body is engageable with the system to expose the plug to the pressurized fluid so that the pressurized fluid acts on the plug to exert a torque on the shaft which is offset from the center line of the plug. The apparatus further includes a linkage assembly configured to translate the torque exerted on the shaft into an output force. A release device, such as a buckling pin or a magnet, is connected to the linkage assembly and is configured to release the shaft when the output force exceeds a predetermined limit. Preferably, the linkage assembly is adjustable to vary the magnitude of the output force corresponding to a given torque.

Abstract: A pressure relief apparatus includes a valve having a body. A shaft is rotatably disposed in the body and has an exterior end extending through the body. A plug, which may contain an internal passageway, is mounted on the shaft and is disposed in the fluid flowpath. The body is engageable with the system to expose the plug to the pressurized fluid so that the pressurized fluid acts on the plug to exert a torque on the shaft which is offset from the center line of the plug. The apparatus further includes a linkage assembly configured to translate the torque exerted on the shaft into an output force. A release device, such as a buckling pin or a magnet, is connected to the linkage assembly and is configured to release the shaft when the output force exceeds a predetermined limit. Preferably, the linkage assembly is adjustable to vary the magnitude of the output force corresponding to a given torque.

Abstract: A pressure relief device comprising a body including an exterior surface, a cavity, an inlet, an outlet, and an aperture, each of the inlet, the outlet, and the aperture opening into the cavity, a temperature sensitive bonding element and a valve, disposed within the cavity and extending through the aperture, including a sealing member and a cap, the cap being joined to the exterior of the body by the temperature sensitive bonding element, and the sealing member being configured to seal the inlet when the cap is joined to the exterior surface of the body. The pressure relief device as claimed in claim 16, wherein the body further includes a retainer configured to prevent the valve from separating from the body when the cap becomes disengaged from the body.

Abstract: An apparatus and method of operating devices (such as devices in a wellbore or other types of devices) utilizes actuators having expandable or contractable elements. Such expandable or contractable elements may include piezoelectric elements, magnetostrictive elements, and heat-expandable elements. Piezoelectric elements are expandable by application of an electrical voltage; magnetostrictive elements are expandable by application of a magnetic field (which may be generated by a solenoid in response to an electrical current); and heat-expandable elements are expandable by heat energy (e.g., infrared energy or microwave energy). Expandable elements are abutted to an operator member such that when the expandable element expands, the operator member is moved in a first direction, and when the expandable element contracts, the operator member moves in an opposite direction.

Abstract: This invention relates generally to remotely operated well borehole or sub-sea tools for oilfield use, and more particularly, for a one shot valve useful for activating such well tools or sub-sea devices in a safe and reliable manner.

Abstract: A heat-responsive fuse cord is positioned in the proximity of a pressure vessel and is thermally coupled to a thermal-pressure relief device which is in communication with the pressurized contents of the vessel. When ignited the fuse cord burns to a thermal coupler, transferring the heat to the thermal actuator of the TPRD. In a kit form, fuse cord and a thermal coupler provide an economical remote and retrofit triggering system for TPRD's having an otherwise limited environment of influence.

Abstract: A safety valve has a valve body, a piston contained in the valve body, a soluble alloy filled between said piston and said valve body, and a spring inserted between the piston and the valve body. The piston includes a path connecting both ends thereof, and has a first gas pressure receiving surface and a second gas pressure receiving surface at both ends. The first and second gas pressure receiving surfaces have the same area; the piston works as a balanced piston where the gas pressure in the fuel tank functions in reverse directions. As a result, no gas pressure is applied to the soluble alloy but only the energizing force of the spring is applied. Therefore, the pressure applied to the soluble alloy can be kept constant without regard to the increase of the gas pressure.

Abstract: A pressure relief apparatus includes a valve having a body. A shaft is rotatably disposed in the body and has an exterior end extending through the body. A plug, which may contain an internal passageway, is mounted on the shaft and is disposed in the fluid flowpath. The body is engageable with the system to expose the plug to the pressurized fluid so that the pressurized fluid acts on the plug to exert a torque on the shaft which is offset from the center line of the plug. The apparatus further includes a linkage assembly configured to translate the torque exerted on the shaft into an output force. A release device, such as a buckling pin or a magnet, is connected to the linkage assembly and is configured to release the shaft when the output force exceeds a predetermined limit. Preferably, the linkage assembly is adjustable to vary the magnitude of the output force corresponding to a given torque.

Abstract: This invention provides methods and apparatus for performing microanalytic and microsynthetic analyses and procedures. Specifically, the invention provides a microsystem platform for use with a micromanipulation device to manipulate the platform by rotation, thereby utilizing the centripetal force resulting from rotation of the platform to motivate fluid movement through microchannels embedded in the microplatform. The microsystem platforms of the invention are also provided having microfluidics components, resistive heating elements, temperature sensing elements, mixing structures, capillary and sacrificial valves, and methods for using these microsystems platforms for performing biological, enzymatic, immunological and chemical assays. An electronic spindle designed rotor capable of transferring electrical signals to and from the microsystem platforms of the invention is also provided.

Abstract: A safety device for an apparatus under pressure, such as a vessel under gas pressure, includes a housing having an overflow channel in fluid communication with the interior of the apparatus, and an outlet port. Received in the housing is a thermal trigger unit which has a rupture element intended to burst when a critical temperature level is exceeded. The rupture element interacts with a closure member which is moveable from a ready position, in which the closure member is so loaded by the rupture element as to seal the overflow channel and thereby cut a fluid communication between the overflow channel and the outlet port, to a release position, in which the overflow channel is cleared for fluid communication with the outlet port as a result of a bursting of the rupture element.

Abstract: Inside the casing (1), there are three or more ribs (8) arranged with their longitudinal axes parallel to the closing body's direction of movement when closing so that each rib forms a slide-way for the closing body (5) moving from open into closed position. Into each of these ribs there is cut a first groove (10) in which is placed a shaped part (11) that supports the closing spring (9). At least the ribs arranged approximately opposite to the tappet (20) have a second groove whose side facing the seat (7) forms a rest edge (18) on which the control edge may rest when the closing body is in open position. When the fusible soft solder component (21) is melting away, the tappet changes its position in axial direction under the force exercised by the closing spring. Due to this change of position, the control edge is no longer resting on the rest edge, and the closing body driven by the dosing spring switches over into its close position.

Abstract: A well control system having well controlled fluids distributed through pipes includes valves that are opened by a heat softened valve obstruction element. The translation of a fluid flow obstructing gate in a gate valve is driven by a stem element attached to the gate. Without a mechanical or fluid obstacle, fluid pressure in the distribution pipe above about 2 psi will drive the valve gate to a biased position. This internal pressure displacement of the valve gate also displaces the gate stem. In the present invention, the displacement of gate stems for critical valves from a normal maintenance position to an emergency activation position, is obstructed by a fusible barrier that is secured across the gate stem translation path. In the event of a well fire, at a predetermined temperature of fusion, the barrier element will no longer resist the displacement force imposed by the stem.

Abstract: A valve with fire-resistant seal for use in industrial piping applications. The valve includes a valve body with a valve element therein. The valve is illustrated as a ball valve, but other valve configurations could also be used. A valve stem engages the valve element so that it can be rotated between open and closed positions. A conventional primary seal is used on the valve stem for normal conditions. The valve body defines a body bearing surface, and the valve stem defines a facing stem bearing surface. A thrust bearing is disposed between the body and stem bearing surfaces, and a fire-resistant seal is positioned radially inwardly from the thrust bearing. Initially, the fire-resistant seal is not engaged with at least one of the body or stem bearing surfaces, and the fire-resistant seal has a thickness less than an initial thickness of the thrust bearing.

Abstract: A temperature activated diversion valve for supplying a first inflow fluid as an outflow fluid and for switching to supply a second inflow fluid as the outflow fluid if the first inflow fluid reaches a specified temperature. The temperature activated diversion valve includes a first inflow conduit for carrying the first inflow fluid, a second inflow conduit for carrying the second inflow fluid, an outflow conduit and a valve member. The valve member is moveable between a first position and a second position and establishes fluid communication between the first inflow conduit and the outflow conduit in the first position, while blocking fluid communication between the second inflow conduit and the outflow conduit in the first position. Additionally, the valve member establishes fluid communication between the second inflow conduit and the outflow conduit in the second position, while blocking fluid communication between the first inflow conduit and the outflow conduit in the second position.

Abstract: A novel PRD (pressure relief device) design called fuse plug which is creep-resistant and leakage-free is developed to improve the thermal response of PRD to fire when it is used as a temperature safety device for valves, cylinders, pressurized pipes, or any pressure vessels, the new design being the combination of geometrical configuration of PRD structure and composite technology wherein the low-melting matrix alloy is dispersed with strong/stiff reinforcing agents such as cut-wire type aggregates/cylinders and such composite alloy is contained in a threaded/rugged cavity with the length/diameter ratio being greater than a minimum. The new design employs a disc-type seal T backed by the composite alloy, thus allowing the use of this new design for cylinders of poor thermal conductivity.

Abstract: The fire-extinguishing device proposed includes a container, holding a gas under pressure, and a fusible hollow element designed to actuate the device. The fusible hollow element is connected to the extinguishant container in such a way that it is acted on by the compressed gas in the container. A pressure regulator is fitted between the extinguishant container and the fusible hollow element. The pressure regulator enables the device to be operated using CO.sub.2 for instance as the extinguishant, even in situations in which the ambient temperature varies widely. The fusible hollow element can also be designed as a feed line for the extinguishant. Also proposed is a valve for a fire-extinguishing device of this kind.

Abstract: A sprinkler head includes a nozzle through which water is discharged to extinguish fire. The nozzle is normally held in a closed position. The nozzle is opened in the event of fire. A leaf spring is provided to hold the nozzle in its closed position and permit the nozzle to open. The leaf spring is deformed both in the axial direction of the sprinkler head and in a direction at right angles to the axial direction when an axial force is applied. Furthermore, the leaf spring and is resiliently returned to its original shape when the axial force is released.

Abstract: A fire detecting valve activation assembly for vehicle fire suppression systems that have a pressurized gas fire suppressant cylinder and a pressurized gas fire suppressant distribution line terminating in a release valve having an actuator shaft for closing and opening the release valve. The fire detecting valve activation assembly includes a nozzle and a lead link fire detecting valve activation assembly.

Abstract: A thermally responsive pressure relief system is provided for a receptacle such as a pressure vessel. The system includes a thermally responsive pressure relief device on the vessel at a given location in communication with the interior of the vessel for venting the vessel in response to the pressure relief device being subjected to a given excess temperature. A heat pipe has one end thermally coupled to the pressure relief device and extends therefrom to a location remote from the given location. The heat pipe rapidly transmits heat from the remote location to the pressure relief device for venting the vessel in response to an excess temperature at the remote location.

Abstract: An actuator assembly for moving a member, such as a gate valve, or the like, between a retracted and extended position, and a locking device for locking the member in its extended position. A ball screw is connected to the member to be moved and is in threaded engagement with a ball nut so that, upon rotation of the ball nut, the ball screw, and therefore the member, moves between a retracted and an extended position. A gear train is connect able between a power source and the ball nut for transferring torque therebetween to rotate the nut member. The locking device cooperates with the actuator for quickly and easily locking the ball screw in an extended position at any time without requiring it to be retracted and then extended, and includes a plunger that moves axially in a housing in response to movement of the ball screw. The plunger has a reduced dimension portion, and a stem is provided that has a reduced dimension portion and a regular dimension portion.

Abstract: Filtering apparatus includes two or more passages (2) acting in parallel, each having an extended filter (12) which passes through inlet and outlet ports (48, 49), flowable preferably sealed by solidified plugs of the flowable substance such as a polymer being filtered. The flow of such substance to one passage can be terminated so as to permit filter advance under conditions of zero pressure drop, whilst flow through the other passage continues. Filter advance can be assisted by extrusion of a sealing plug in the outlet port under the pressure of such substance from the other passage which is still filtering. In additional or alternative mode, flow into a passage is terminated and a secondary outlet (20, 21) in that passage is opened. This creates a counterflow under the pressure of substance from the other passage, which cleans the filter. The secondary outlet can be sealed by a plug which is extruded during counterflow.

Abstract: A thermally activated relief valve is used with a compressed gas storage cylinder. A valve body has a passage for communication with the interior of the cylinder. A metal disc sealing the passage has a first side exposed to the interior of the cylinder and a second side opposite the first side. A cutting end of a movable hollow bayonet is positioned in the passage of the valve body adjacent to the second side of the metal disc. A spring biases the bayonet toward the metal disc. A thermal trigger is operably coupled to the bayonet for holding the bayonet in spaced relation to the metal disc until the thermal trigger reaches a predetermined temperature threshold. Upon reaching the predetermined temperature threshold, the thermal trigger releases the bayonet thereby allowing the cutting end of the hollow bayonet to move toward the metal disc under force exerted by the spring to pierce the metal disc and thereby expose a flow path through the hollow bayonet.

Abstract: A relief device which activates in response either to excess temperatures or pressures in or around a pressurized vessel and which resists extrusion related failures even at high pressures is provided. The relief device includes a body having an inlet, an outlet, and a fluid flow passage communicating with the inlet and outlet. The body further includes a fluid escape passage having a member therein which is porous to gases and liquids but not to solids and a plug of a fusible material which melts at a predetermined temperature positioned adjacent to the porous member. A first piston is positioned in the fluid flow passage and is normally biased into a sealing relationship with the inlet. A second piston is positioned in the fluid escape passage and is normally biased against and applies a compressive force on the plug of fusible material.

Abstract: A nuclear reactor has a pressure vessel with an interior, a coolant conducting surface, such as a wall of the pressure vessel or a line passing through the wall of the pressure vessel, a pressure relief line, and a core. A safety device which protects the pressure vessel against overpressure failure upon inadequate cooling of the core includes a pressure relief valve being pressure-tightly inserted into the coolant conducting surface and having a seat, a closure element normally disposed on the seat for blocking a flow from the interior of the pressure vessel to the pressure relief line, an abutment, and a valve closing spring holding the closure element and being supported against the abutment. A force transmission element holds the abutment and has an end facing away from the abutment. A detent is disposed in the pressure vessel and fixes the end of the force transmission element. The detent is releasable in dependence on a given threshold temperature, for example 700.degree. C.

Abstract: A thermally activated relief device which resists extrusion-related failures even at high pressures and yet reliably activates to relieve pressure in a vessel and to prevent a catastrophic pressure rupture of a vessel is provided. The thermally activated relief device includes a body having an inlet, an outlet, and a fluid flow passage communicating with the inlet and outlet. The body further includes a fluid escape passage having a member therein which is porous to gases and liquids but not to solids. A plug of a fusible material which melts at a predetermined temperature is positioned adjacent to the porous member and normally seals the fluid escape passage. A piston is normally biased into a sealing relationship with the inlet, but, when the fusible plug melts, moves upwardly to open the flow passage and relieve fluid pressure.

Abstract: The described invention takes as its basis the problem of developing an overtemperature shut-off valve which guarantees a reproducible gas-tight seal. The problem is solved in that the metal closure body (11) has a spherical shape at least in its sealing area and its diameter is selected so as to form a slight tight fit with the diameter of a valve seat which is in the form of a bore (21) shaped in the housing (1) of the valve when the valve is closed. A second bore (20) extends in the direction of the first bore (21) is arranged upstream thereof. A guide (19) that tapers outwardly in the direction of the closure body (11) when it is in its open position is located between the closure body and the second bore (20).

Abstract: This disclosure relates to a valve including a valve member having: a predetermined surface area on its inlet side exposed to the inlet pressure to produce a force tending to move the valve member to an open position; a larger surface area on its opposite, control side exposed to the inlet pressure to produce a larger force tending to move the valve member to its closed position; a passageway through the valve member; a restrictor orifice in the passageway; and a one-way valve in the passageway permitting fluid flow only from the inlet side to the control side of the valve member, to prevent unintentional opening of the valve member in the event of a drop in the inlet pressure followed by the resumption of the inlet pressure.

Abstract: Packaging apparatus and method, for use in controlled atmosphere packaging of horticultural produce in controlled permeability film. A valve apparatus mounted on or in a packaging film including a temperature sensitive sensor formed from a bimetallic or shape-memory material (2), or a chemical sensitive sensor formed from a swellable polymer, to actuate the valve member (pin or plug) (1) on, or in communication with the sensor. In use, after sealing the produce within the packaging film, the valve apparatus opens the packaging film in response to a temperature change of predetermined magnitude to allow oxygen flow for extension of storage life or fumigation of the produce.

Abstract: A unique design for improved creep strength with a leakage-free structure is presented for manufacture of creep-resistant pressure relief device (PRD) of valves or cylinders or any pressure vessels as a fire protection safety device, the new design being the combination of geometrical configuration of PRD body shell and composite technology wherein the relatively weak matrix phase is dispersed with strong reinforcing agent and such composite mixture of matrix phase/reinforcing agent is contained in a nonslip structure of PRD cavity with a length/diameter ration being greater than about one such that the external load is transferred to the PRD structural body via stress transfer mechanism through reinforcing agents. The PRD's or fuse plugs fabricated by techniques of the present invention exhibit pronounced creep strength and show no gas leakage under high pressure/elevated temperature conditions realized during fires.

Abstract: A fail-safe thermostat valve for controlling the flow of coolant to an engine has, in addition to a thermostat element that expands and contracts to open and close the valve, a fusible element that supports an elevated plate that holds two springs. One spring holds the valve plate in its normally closed position. When the thermostat element fails, the fusible element melts and allows the second spring to force the elevated plate away from the valve seat and pull valve plate away from the valve seat as well. Thus, when the thermostat element fails, the valve will remain permanently open until it can be replaced.

Abstract: A safety valve for a sealed vessel, for releasing pressurized gas from the sealed vessel in an abnormally heated state defined by a critical temperature. The safety valve includes an end plate for the vessel, the end plate having opposite concave and convex surfaces. A bore perforates the plate at a low point of the concave surface. A central portion of the plate surrounding the bore is bent toward the bore so as to define a cavity which opens toward the concave surface. An alloy material, having a melting point which is lower than the critical temperature, is provided in the cavity and plugs the bore so that if the temperature of the pressurized gas exceeds the critical temperature, the alloy material melts thereby opening the valve and relieving the pressure within the vessel.

Abstract: A valve for a sterilizer container comprises an elastic support body in the form of a pressure capsule which holds the valve in open position. This pressure capsule communicates with the interior of a headpiece which is sealingly arranged on the valve cap, the capsule having a valve opening which can be closed by the plug of an adjusting member. The closing is effected, after the sterilization temperature has been reached, by a temperature-sensitive member which has an alloy which melts when the sterilization temperature is reached. The alloy when in solidified state holds the adjusting member, which is under spring tension, fast and permits it to move as soon as it melts. The adjusting member can be clamped by means of a one-way coupling when the alloy is solidified. The entire valve arrangement can be removed from the container. It preferably lies in a cup-shaped depression in the lid of the container, the possibility of stacking with other containers being thus assured.

Abstract: A quick response frangible bulb sprinkler head includes a tubular body connected to a water line. The body has an outlet that is enclosed by a cap or closure, which is held in the closed position by a lever assembly. The lever assembly includes a pair of lever arms which are disposed in an X-configuration, with one end of each arm engaged with the body and the opposite ends of the lever arms are spaced apart and engaged with the opposite ends of an elongated glass bulb. The axis of the bulb is disposed normal to the axis of the outlet in the body. A screw is threaded in the closure and the tip is engaged with a channel-shaped pressure member that is connected to the central portions of the lever arms. Through adjustment of the screw, the compressive force on the bulb can be varied.

Abstract: A fire safe valve which includes a body having an inlet, an outlet, a valve chamber communicating with the inlet and the outlet and having an opening, a bonnet secured to the body and having a bore therethrough with the opening of the bore communicating with the valve chamber opening and defining a back seat surrounding the bore, a valve member, a valve stem connected to the valve member and extending through the bonnet bore, a backseating shoulder on the valve stem, an actuator, the valve stem connecting to the actuator to move the valve member within the valve chamber to open and close flow through, the valve, a temperature sensitive material retaining the valve stem shoulder spaced from said bonnet bore seat during normal operations and allowing additional movement of the valve stem responsive to excessive temperatures to bring the valve stem shoulder into engagement with the bonnet bores seat to backseat and prevent flow of fluids within the valve from escaping therefrom.

Abstract: A thermally activated pressure relief valve includes a valve housing with an inlet communicating with an interior of a pressure vessel, and a passage from the inlet, through the housing, to an outlet for communicating with the exterior of the housing. A seal plug is disposed within a cavity of the housing and across the passage for sealing the passage. A thermal trigger engages the seal plug within the cavity to restrict movement of the seal plug and maintain a seal of the passage when a temperature adjacent to the housing is below a predetermined temperature threshold. The thermal trigger releases the seal plug, which is movable within the cavity, allowing the seal plug to relocate within the cavity when the temperature reaches the predetermined temperature threshold, thereby exposing a flow path between the inlet and outlet through which gas can escape.

Abstract: A thermally activated relief valve is used with a compressed gas storage cylinder. A valve body has a passage for communication with the interior of the cylinder. A metal diaphragm sealing the passage has a first side exposed to the interior of the cylinder and a second side opposite the first side. A hollow bayonet is mounted to the valve body on the second side of the diaphragm. A spring is used to bias the bayonet toward the diaphragm. A thermal trigger is operably coupled to the bayonet for holding the bayonet in spaced relation to the diaphragm until the thermal trigger reaches a predetermined temperature threshold. Upon reaching the predetermined temperature threshold, the thermal trigger releases the bayonet so that the bayonet moves toward the diaphragm under force exerted by the spring and so that the bayonet pierces the diaphragm.

Abstract: A method of sealing a pressure vessel so that pressurized gas in the vessel is released if the temperature of the gas approaches a critical temperature. An end plate having a concave upper surface and a convex lower surface, is provided with a bore perforating the plate at a low point of the concave surface. A central portion of the plate surrounding the bore bending downwardly to the bore so as to define a cavity in the plate. The plate is oriented with the concave surface facing in an upward direction. An alloy pellet, having a melting point which is lower than the critical temperature, is provided onto the concave surface so that the pellet is gravitationally drawn to rest in the cavity. The end plate is then heated at a temperature higher that the melting point of the pellet so that the pellet is melted and plugs the bore. The end plate is then cooled to solidify the melted pellet in the cavity and in the bore.

Abstract: The adaptive braking system (10) default activated proportioning valve (80, 80A, 80B) comprises a proportioning valve that is deactivated during normal and adaptive braking system operation. Should the adaptive braking system (10) experience a failure so that the related wheel or wheels (49, 59) of the vehicle no longer receive an appropriate braking pressure from a pressure producing mechanism (12) of the vehicle, the proportioning valve (80, 80A, 80B) is activated by the electronic control unit (70) of the adaptive braking system (10) so that the braking pressure is proportioned accordingly. The valve contains a fusible link that is disipated to allow the valve to proportion.

Abstract: A poppet valve structure has a valve plug biased inwardly to close a vent opening (10). A connector member (40, 58) includes a cage (40) extending inwardly from the valve plug and a separately formed bottom plate (58) secured to the cage (40). The plate (58) defines a radially outwardly opening recess (64) and a first pair of axially spaced apart confronting surfaces. A spring abutment member (66) surrounds the plate (58) and defines a radially inwardly opening recess (74) and a second pair of confronting surfaces. The two pairs of surfaces confront and substantially contact each other. The recesses (64, 74) together define a substantially closed annular chamber. The chamber may be formed by a pair of confronting channels (64, 74) or defined axially between two flanges (61, 67) on the plate (58') and the abutment member (66'), respectively. A ring of fusible material (76) is cast in situ within the chamber to interconnect the plate (58) and the abutment member ( 66).

Abstract: A temperature sensitive valve having a body with an internal valve chamber being open through said body, an inlet extending into the valve chamber, a control outlet communicating with said valve chamber, and a bleed outlet communicating with said valve chamber, a bonnet having a bore secured to said body in surrounding relationship to the opening of the valve chamber through the body, a control sleeve positioned in said valve chamber and in said bonnet bore, means for sealing between the control sleeve and the interior of the valve chamber above and below the entry of said inlet into the valve chamber, said control sleeve defining a first valve seat in its lower portion, a second valve seat surrounding the entrance of the bleed outlet into said valve chamber, a valve member extending through said valve sleeve and having valve seat engaging surfaces for engaging said first and second valve seats, a first temperature sensitive material supporting said valve member in position out of engagement with said first v

Abstract: A heat releasable weldment for a mechanical opening jack used in combination with fluid powered valve actuators to release said manual opening jack in the event of fire comprising grooved inner and outer members which cooperate to form a eutectic chamber, said inner and said outer members being retained in spaced relationship with each other by horizontal and vertical restraining members in cooperation with a fusable eutectic alloy which is poured into said eutectic chamber and allowed to solidify together and a method to field retrofit said weldment to a mechanical opening jack is presented.

Abstract: The protective device prevents overheating, in particular by fire, of individual or batteries of pressure vessels of length equal to at least 1,5 m, employed for storage and/or transportation of gases under high pressure. The essentially cylindrical pressure vessels have at least one closure cap with a valve or a closure plug. Mounted on one closure cap is a pressure pipe which communicates with the interior of the pressure vessel, and is fitted with a controllable venting valve that under normal conditions closes off the pressure pipe or a common pressure pipe and has a venting pipe which terminates outwith the region of the pressrue vessel/vessels. Temperature sensitive actuating means are provdied in the axial direciton of the pressure vessel/vessels a spacing apart and connected to the venting valve. These means can individually actuate the venting valve should overheating occur.

Abstract: A flow control device, such as a valve, has a valve body which has a fluid holding chamber therein. An inlet in the valve body couples the chamber to a source of pressurized fluid. An outlet in the valve body couples the chamber to downstream devices such as sprinkler heads. The outlet has an outlet opening which opens to the valve chamber. A collapsible tubing is sealingly attached at a first end to the outlet opening. The collapsible tubing has an opposite end which extends into the chamber. The opposite end of the collapsible tubing has an inlet which opens into the chamber. A mechanism is provided for blocking and unblocking the inlet of the opposite end of the collapsible tubing to cause the collapsible tubing to collapse and uncollapse to block and unblock fluid flow from the chamber through the outlet. The mechanism has a piston for insertion into and withdrawal from the inlet of the collapsible tubing to block and unblock the inlet.

Abstract: An oil filter for an internal combustion engine lubrication system has an anti-drainback valve that is temporarily held open with a quantity of special grease during the initial filling of the engine's oil lubrication system with oil, and then passively melts or dissipates upon contact with the oil so as to allow the anti-drainback valve to thereafter close.

Abstract: The thermal fuse valve (10, 110) is disposed within a passage (14, 114) of the wheel rim (12, 112). The thermal fuse valve (10, 110) includes a retention mechanism (22, 122) which engages a complementary-shaped retention mechanism (13, 113) of the passage (14, 114) such that the thermal fuse valve (10, 110) is disposed stationary relative to the passage (14, 114). The thermal fuse valve (10, 110) comprises a fuse body (20, 120) joined with a sealing fuse plug (30, 130) by way of a fusible material (40, 140). The fuse body (20, 120) includes a central opening (24, 24A, 124) receiving an axial extension (34, 134) of said sealing plug (10, 110). A seal (50, 150) is disposed about the perimeter of the sealing fuse plug (30, 130) in order to retain pressurized fluid within the tire, the pressurized fluid communicating with the central opening (24, 24A, 124) and acting upon the extension ( 34, 134) of the sealing fuse plug (30, 130).