US3756785A - Gas generator assembly - Google Patents

Gas generator assembly Download PDF

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US3756785A
US3756785A US00180558A US3756785DA US3756785A US 3756785 A US3756785 A US 3756785A US 00180558 A US00180558 A US 00180558A US 3756785D A US3756785D A US 3756785DA US 3756785 A US3756785 A US 3756785A
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housing
cartridge
oxygen
candle
gas generator
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US00180558A
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L Netteland
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Scott Technologies Inc
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ATO Inc
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Assigned to FIGGIE INTERNATIONAL INC. reassignment FIGGIE INTERNATIONAL INC. CHANGE OF NAME (SEE DOCUMENT FOR DETAILS). EFFECTIVE JUNE 1, 1981. Assignors: A-T-O INC.
Assigned to FIGGIE INTERNATIONAL INC. reassignment FIGGIE INTERNATIONAL INC. MERGER (SEE DOCUMENT FOR DETAILS). EFFECTIVE DATE: DECEMBER 31, 1986 Assignors: FIGGIE INTERNATIONAL INC., (MERGED INTO) FIGGIE INTERNATIONAL HOLDINGS INC. (CHANGED TO)
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J7/00Apparatus for generating gases
    • AHUMAN NECESSITIES
    • A62LIFE-SAVING; FIRE-FIGHTING
    • A62BDEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
    • A62B21/00Devices for producing oxygen from chemical substances for respiratory apparatus
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B13/00Oxygen; Ozone; Oxides or hydroxides in general
    • C01B13/02Preparation of oxygen
    • C01B13/0296Generators releasing in a self-sustaining way pure oxygen from a solid charge, without interaction of it with a fluid nor external heating, e.g. chlorate candles or canisters containing them

Definitions

  • a gas generator assembly comprising a housing containing an oxygen evolving cartridge in spaced relation to the housing.
  • a manually operable actuating mechanism easily reset or cooked by hand, is rele-asably secured in the housing in spaced relation to the cartridge for igniting the oxygen candle therein.
  • a safety release pin locks the actuating mechanism in the cocked position to prevent inadvertent ignition of the candle.
  • This invention relates to a gas generator and, more particularly, to a self contained oxygen-evolving apparatus especially adapted for regular use by patients having respiratory ailments and for respiratory and cardiac emergencies.
  • Gas generators comprising oxygen evolving chlorate candles mounted in cannisters or containers are known, and offer certain advantages over cylinders of oxygen under pressure.
  • these known generators employ an over-the-center type of percussion actuator, which not only is difficult to cock for repeated action, but requires locating the primer in close proximity to the actuator. Since the heat of combustion of the primer and candle is intense, the actuator and container reach excessive temperatures.
  • oxygen evolving generators are very useful in many emergency situations, such as might be encountered in submerged watercraft or high flying aircraft, they present a problem when used by respiratory patients or by medical personnel who must handle such generators and trigger the actuator by hand. Also, the difficulty in manually resetting or cocking the actuator for subsequent use with a freshly replaced oxygen candle renders them unsuitable for repeated usage by respiratory patients and by medical personnel.
  • the gas generator assembly of the present invention is characterized by the provision of stud means afiixed to the opposite ends of an oxygen evolving cartridge for spacing the latter from the ignition actuating mechanism and from the housing walls.
  • the ignition actuating mechanism is easily operated and reset by hand and is provided with a locking mechanism to prevent inadvertent firing.
  • An inner heat dissipating linear and an outer heat shield spaced therefrom are interposed between the oxygen evolving cartridge and the housing.
  • FIG. 1 is a longitudinal sectional view of one form of a gas generating assembly of the present invention
  • FIG. 2 is a longitudinal sectional view of another form of gas generating assembly of this invention.
  • FIG. 3 is a fragmentary vertical sectional view, on an enlarged scale, showing the oxygen evolving unit and a portion of the ignition mechanism therefor;
  • FIG. 4 is a fragmentary vertical sectional view, on an enlarged scale, showing details of the ignition actuating mechanism in its locked, cocked position;
  • FIG. 5 is a transverse cross sectional view taken about on line 5-5 of FIG. 4;
  • FIG. 6 is a view similar to FIG. 4, showing the ignition actuating mechanism in its released, firing position;
  • FIG. 7 is a transverse cross sectional view taken about on line 7-7 of FIG. 6;
  • FIG. 8 is a transverse cross sectional view taken about on line 8-8 of FIG. 6;
  • FIG. 9 is a transverse cross sectional view taken about on line 9-9 of FIG. 6.
  • FIG. 1 an illustrative embodiment of an oxygen generator assembly, generally designated 10, constructed in accordance with this invention, comprising a housing 12 for enclosing an oxygen generator cartridge 14.
  • Housing 12 is of a generally cylindrical configuration and comprises a cylindrical tubular shell 16, a bottom end wall 18 having perforations 19 therethrough, and a top end cover 20.
  • Cover 20 is releasably secured to shell 16 by any suitable means, such as a pair of conventional toggletype safety locks 21 for example.
  • a strap 22 is connected to shell 16 by means of suitable fasteners 23 and is adapted to be looped over the head and about the neck of the user for supporting generator 10 preferably adjacent one side of the user in the area of the hip region.
  • suitable fasteners 23 are used for convenience of description with reference to the drawings and are not used in a limiting sense.
  • oxygen generating cartridge 14 comprises a cannister 24 encasing an inner body composition capable of evolving oxygen upon burning.
  • the composition can consist of a consolidated core body, hereinafter referred to as an oxygen candle 26, having uniformly distributed therethrough an alkali metal chlorate or perchlorate which generates oxygen, a finely divided oxidiza-ble material such as iron powder for burning and supplying part of the heat needed for release of oxygen through an exothermic reaction, a binder such as inorganic glass fibers or steel wool for holding the mass together and aiding in the even decomposition of the chlorate or perchlorate, and barium peroxide or like chlorine fixes for chemically eliminating traces of chlorine gas released during thermal breakdown of the chlorate or perchlorate.
  • the body of oxygen candle 26 can be press-molded or cast to form a cylinder having an ignition area located centrally' at the 'upper end thereof, such ignition'area comprising the foregoing composition enriched with a metal powder, such as iron, to provide a concentrated area of intense heat when ignited.
  • a metal powder such as iron
  • Candle body 26 is encased within a heat insulating envelope 28 of filter medium interposed between candle body 26 and cannister 24 to insulate the latter from the heat of combustion.
  • Envelope 28 can be formed of fiberglass and, if desired, impregnated with a silicate or other hardening agent in an amount suflicient to make the envelope shape sustaining in the desired form.
  • an annular pad 30 is mounted on top of candle 26 and envelope 28 in spaced relation to the top end wall 32 ofcannister 24.
  • a fiberchrome filter 31 is interposed between pad 30 and cannister top end wall 32.
  • the bottom end 'of candle 26 is provided with a fiberfrax disc 33 having an inwardly dished portion resting on the complementary inwardly dished portion of a perforated bafiie plate 34 supported on a metallic screen 35.
  • a layer of catalyst 36 such as the well known Hopcalite,.is sandwiched between a pair of fiberfrax discs 37 beneath oxygen candle 26 and is effective to oxidize to carbon dioxide any carbon monoxide that may result from the combustion of oxygen candle 26.
  • the lower disc 37 is supported on a micro quartz pad 38 which, in turn, is supported on a fiberglass pad 39 resting on a metallic screen 40.
  • Screen 40 rests against the inner surface of a cannister cover or bottom end wall 41, which is provided with an inturned, curved flange 42 at the marginal edge thereof rolled into sealing relation with an annular bead 44 forming a continuation of the cannister body and located at the bottom end thereof.
  • cover 41 the foregoing components are inserted through the bottom open end of cannister 24 and then sealed by cover 41.
  • Bottom end wall 41 is formed with an outwardly dished portion 46 defining a chamber 48 into which filtered oxygen is collected.
  • a stud, generally designated 50 and having a bore 52 therein, is suitably attached to portion 46 of bottom wall 41 and is maintained in a gas tight relation therewith by means of a suitable seal 54. Stud 50 is provided with an annular abutment shoulder 56 and a tubular body 58 adapted to be received in a manifold coupling as will hereinafter become apparent.
  • a stud 60 Mounted on upper end wall 32 of cannister 24 in a gas tight relation therewith is a stud 60 having a flange 62 and a cylindrical body 64 extending downwardly from flange 62 to pad 30, which is provided with a central opening communicating with candle 26.
  • a primer 66 is mounted within body 64 and communicates with the ignition area of oxygen candle 26 through a bore 67 provided in body 64.
  • Stud 60 also includes a tubular body portion 68 extending upwardly from flange 62 and having an annular flange 70 spaced from flange 62.
  • Body portion 68 is adapted to be received in a retainer forming part of the primer actuating mechanism and is bored as at 72 to receive a firing pin, hereinafter more fully described.
  • the oxygen generating cartridge 14 thus far described includes studs 50 and 60 and constitutes a disposable, selfcontained unit which, when spent, can be replaced by a fresh unit in housing 12.
  • a manifold 76 is suitably secured to bottom end wall 18 of housing 12 (FIG. 1) as by means of screws 78 and is provided with a longitudinal passage 80 communicating with a tapped opening 82.
  • One end of passage 80 leads to a port having a pressure relief valve 84 suitably threaded therein.
  • the other end of passage 80 leads to a port 86 connected to a coupling 88 having a hose fitting 89 for connection to a flexible delivery tube (not shown) connected at its other end to the usual face mask, also not shown.
  • the mask, delivery tube and a fitting connection when not in use, can be stored within cover 20.
  • a fitting 90 is threaded into tapped opening 82 in a gas tight relation therewith and is provided with a bore 92 for receiving tubular body 58 of stud 50.
  • a seal 94 is disposed in a peripheral groove formed in body 58 to provide pressure sealing between body 58 and fitting 90. Fitting is provided with an outer face 96 which serves as a seating surface for shoulder 56 of stud 50.
  • a cavity 98 is formed in manifold 76 in registry with opening 82 for receiving a check valve 100 therein.
  • Check valve 100 is provided with a beveled resilient sealing surface 102 adapted to engage a beveled valve seat 104 formed on the end of fitting 90.
  • Valve 100 is normally biased against valve seat 104 by means of a helical spring 106 disposed between the rear face of valve 100 and the bottom of cavity 98.
  • the filtered oxygen under pressure generated by the combustion of candle 26 flows from chamber 48 through bore 52 of stud 50 and acts against valve 100 to urge the latter away from its seat 104, allowing the oxygen to flow through opening 82, passage 80, port 86, coupling 88 and ultimately to the user. Excess pressures are dissipated through relief valve 84 in the usual manner.
  • a support plate 110 is mounted within the lower end of housing 12 (FIG. 1) between manifold 76 and a stepped flange on fitting 90.
  • Plate 110 has a generally circular planar portion 112 and an offset ledge 114 connected to portion 112 by an annular shoulder 116 and terminating in an annular flange 118.
  • Plate 110 supports the lower ends of a pair of concentric, cylindrical liners 120 and 122 the inner lines 120 being mounted in spaced relation to cartridge 14 and perforated as at 124 for dissipating the heat generated by the combustion of candle 26.
  • the lower end of liner 120 is supported on the planar portion 112 of plate 110 against shoulder 116.
  • Outer liner 122 which serves as a heat shield, is spaced radially from liner 120 and is supported at its lower end on ledge 114 against flange 118.
  • the upper ends of liners 120 and 122 are supported in spaced relation by means of a retainer member 126 bonded or otherwise fixedly secured to the upper end of housing shell 16.
  • Member 126 has spaced cylindrical partitions 128 and 130 for embracing the upper ends of liners 120 and 122.
  • a plurality of passages 132 are provided in member 126 and connect an annular passage 134 defined between liners 120 and 122 to the ambient atmosphere when cover 20 is removed from shell 16.
  • Liner 122 serves as a heat shield retaining the heat within passage 134 and preventing the transmission of heat to housing 12 thereby protecting the user against burning contact with housing 12.
  • Member 126 is provided with a central tapped opening 138 for receiving a cup-shaped casing 140 threadably secured therein and provided with a bottom wall 142 for supporting an ignition actuating assembly, generally designated 144 (FIG. 4).
  • Bottom wall 142 is provided with a plurality of openings 143 connecting the area within liner 120 with the ambient atmosphere to aid in the dissipation of heat generated by candle 26 during combustion.
  • actuating assembly 144 comprises a retainer 146 having a flange 18 engaging against the underside of bottom wall 142 and a body portion 149 threadably secured to an actuator 150.
  • Retainer 146 has a bore 152 therein for receiving the upper portion of tubular body 68 of stud 60 (FIG. 3) and a firing pin 154 having an axial projection 156 adapted to strike primer'66 for firing the latter.
  • Flange 148 is provided with an annular rib 158 of generally triangular cross section having an annular apex portion 160 adapted to seat against stud flange 70 (FIG. 3) of cartridge 14 for properly locating the parts in the assembled relation.
  • the entire actuating assembly 144 is assembled as a unit to cartridge 14 by inserting the upper end of stud 60 into bore 152 of retainer 146 and then threading casing 140 into opening 138 of member 126 until rib 158 seats against flange 70. Bore 72 of stud 60 is coaxially aligned with bore 152 of retainer 146 for receiving the end portion of firing pin 154 in the assembled relation with the upper portion of tubular body '68 interposed between retainer 146 and firing pin 154.
  • Actuator 150 comprises a generally cyclindrical body 164 having an end wall 166 provided with a central opening 168 therein.
  • Body 164 is provided with four circumferentially spaced openings 170 for receiving balls 172 as shown in FIG. 8. Of course, more or less than four openings 170 and a corresponding number of balls 172 can be provided, as desired.
  • Body 164 is provided with a re- 'duced diameter portion 174 and a further reduced diameter portion 176 separated by a beveled shoulder 178 for a purpose hereinafter explained.
  • An insulator cap 180 is mounted on the upper end of body 164 about end wall 166 and is provided with an annular bead 182 received in a peripheral groove formed in body 164.
  • Firing pin 154 is provided with a cup-shaped member 184 formed integral therewith and telescopically received within actuator body 164.
  • Member 184 is provided with openings 186 adjacent firing pin 154 to permit the heat of candle 26 to escape by convection.
  • a compression spring 188 is mounted within member 184 for biasing firing pin 154 toward primer 66.
  • Member 184 is provided with a peripheral groove 190 having a beveled cam surface 192 extending from groove 190 to the outer peripheral surface of member 184. Groove 190 receives portions of balls 172 when aligned with openings 170 of actuator 150 as shown in FIG. 4 and cam surface 192 aids in ejecting balls 172 out of groove 190 upon downward movement of member 184 relative to actuator 150.
  • An actuator sleeve 196 is mounted about actuator 150 for sliding movement relative thereto and comprises a hollow body 198 having an inner wall surface 199 and formed with an elongated enlargement 200 (FIG. 5) at one side thereof extending generally normal to the axis body 198. As shown in FIG. 9, a portion of the inner wall surface of body 198 is flat sided as at 195 and complementary to a flat sided portion 197 of actuator body 164 to prevent relative rotation therebetween. Thus, bodies 164 and 198 can move axially relative to each other but are keyed against relative rotational movement.
  • the inner wall surface 199 of the upper portion of sleeve body 198 is provided with an annular beveled shoulder or cam surface 201 leading to an enlarged inside diameter portion 203.
  • the lower portion of body 198 is provided with an enlarged cup-shaped configuration having a cylindrical Wall 202 radially spaced from actuator body 164 for receiving a compression spring 204 therein.
  • the lower end of spring 204 abuts against a washer 206 supported between casing bottom wall 142 and an annular shoulder 208 provided adjacent the lower end of actuator body 164.
  • Enlargement 200 is provided with axially aligned bores 210 for receiving an elongated safety lock shaft 212, the central portion of which passes between portion 203 of sleeve body 198 and portions of the outer peripheral surface of actuator body 164.
  • Enlarged heads 214 are secured to the opposite ends of shaft 212 as by means of suitable fasteners 216. These heads 214 are adapted to be received in cavities 218 provided at the opposite ends of enlargement 200.
  • Shaft 212 is provided with an intermediate reduced diameter portion 220 having annular, bevelled shoulders or cam surfaces 222 leading to the outer peripheral surface of shaft 212.
  • Shaft 212 is adapted to be shifted axially into a locked position as shown in FIGS. 4 and 5 whereby actuator sleeve 196 and actuator body 164 are keyed together and into a release position as shown in FIG. 7 whereby sleeve 196 can be moved vertically relative to actuator body 164.
  • actuating as sembly 144 Prior to use, the various components of actuating as sembly 144 are in the relative positions shown in FIGS. 4 and 5 with safety lock shaft 212 captively held between portion 203- of actuator sleeve 196 and the reduced diameter portion 176 of actuator body 164.
  • actuator sleeve 196 and body 164 are keyed together preventing relative sliding movement therebetween.
  • balls 172 are captively disposed in openings 170 of actuator body 164 and partially in peripheral groove 190 of member 184. In this position, balls 172 lock member 184 upwardly against the bias of spring 188, thus maintaining firing pin 154 upwardly within bore 152 in a cocked position.
  • strap 22 is placed about the users neck region in a manner supporting generator 10 along one side of the user and the toggle-type safety locks 21 are released.
  • Cover 20 can then be removed from housing 12 and the breathing mask and delivery tube removed and connected to the coupling 89.
  • the breathing mask is not placed about the users month until the oxygen generator is actuated and the oxygen evolving process initiated.
  • Cover 20 is left dangling from generator 10 by means of a tether strap 226 connected at one end thereof to a central boss 228 in end cover 20 by a fastener 230 (FIG. 1) and connected at the other end to member 126 by any suitable means (not shown).
  • cover 20 is removed from housing 12 to expose actuating assembly 144, it remains attached thereto by strap 226 so as to prevent misplacement thereof.
  • actuator sleeve 196 is slid downwardly relative to body 164 against the bias of spring 104 to the position shown in FIG. 6. This relative movement can be effected due to the reduced diameter portion 220 of shaft 212 which readily fits into the space between portion 203 of sleeve 196 and portion 174 of body 164.
  • the evolved oxygen passes through chamber 48, bore 52 of stud 50 and bore 92 of fitting
  • the pressure of the evolved oxygen builds up and acts against the face of check valve until such pressure overcomes the bias of spring 106 to unseat valve 100'.
  • the oxygen escapes past check valve 100, through passage 80, port 86, coupling 88, hose fitting 89 and the delivery tube to the face mask at a rate sufficient to meet the oxygen consumption :2 the user. Excess pressures are relieved through valve
  • the heat generated by the combustion of oxygen candle 26 is dissipated by convection through perforated liner 120, passages 134, 132 and outwardly through the open end of housing 12 into the ambient atmosphere.
  • Perforations 19 in bottom end wall 18 permit cool air to communicate with the interior of housing 12 to ventilate the latter and facilitate such heat dissipation. Any heat transmitted upwardly is dissipated through openings 143 in member 126 and through retainer bore 152, openings 186, the interior of cup-shaped member 184, and outwardly through aligned openings in end wall 166 and cap memher 180.
  • Outer liner 122 serves as a heat shield and aids in directing the heat upwardly through passage 134.
  • Housing wall 16, which is spaced from liner 122, is virtually uneffected by the intense heat generated by oxygen candle 26, which heat is dissipated outwardly through perforated liner and upwardly by convection through the open end of housing 12.
  • the temperature of housing shell 16 remains low and is harmless against human contact therewith. This is especially significant when it is realized that cannister 24 maintains a temperature of approximately 400 F. during normal combustion of the candle.
  • oxygen candle 26 can be of the multi-stage ignition type providingfull flow operation at the mask within a predetermined minimal time limit and provding a minimum rate of relatively high oxygen flow for the first few minutes followed by a smooth transition to a minimum rate of reduced oxygen flow for the remainder of the oxygen evolving duration. However, ignited, it will continue to burn until expended.
  • a tool 234 (FIG. 1) is releasably mounted in cover 20- as by means of a spring clip 236 fixed to fastener 230.
  • Tool 234 comprises a strip 236 of metal reversely bent to form a loop 238 which serves as a handle for tool 234.
  • the reversely bent portion is spaced from the main strip portion by a spacer element 240 and is connected thereto by means of a suitable fastener 242.
  • the distal end of tool 234 is bent inwardly as at 244 and is bifurcated to provide spaced fingers 246 (only one of which is shown in FIG. 1) adapted to engage about body portion 68 of stud 60 below flange 70.
  • the angular bend 244 in tool 234 facilitates the entry of fingers 246 into opening 138 of retainer member 126 and the positioning thereof about stud 60 so as to apply upward pressure against flange 70 and raise cartridge 14 out of housing 12.
  • a fresh cartridge 14 can then be placed in housing 12 with tubular body '58 of stud 50 inserted within fitting 90 until shoulder 56 abuts against face 96 of fitting 90.
  • cartridge 14 is correctly positioned within housing 12 in readiness to receive actuating assembly 144, which must be reset and cocked prior to assembly with cartridge 14.
  • actuating assembly 144 When actuating assembly 144 is detached from retainer member 126, the various parts thereof are in the relative positions shown in FIG. 6.
  • firing pin 154 In order to reset or cock actuating assembly 144, firing pin 154 is forced within actuator body 150 against the bias of spring 188.
  • groove 190 When groove 190 is aligned with openings 170 in body 150, balls 172 will be shifted inwardly by cam surface 201 of actuator sleeve 196 under the influence of spring 204.
  • Actuator sleeve 1% is then free to move upwardly relative to body 150 under the urging of spring 204, carrying safety lock shaft 212 therewith.
  • the various parts of actuating assembly 144 are then in the relative positions illustrated in FIG. 4 and firing pin 154 is held in its cocked position by means of balls 172.
  • Lock shaft 212 is shifted axially to lock actuating sleeve 196 in its raised position to prevent inadvertent release of firing pin 154.
  • Casing 140, together with actuating assembly 146 in its cocked position, can then be assembled to retainer member 126 and cartridge 14 in a manner hereinbefore described.
  • FIG. 2 illustrates another form of an oxygen generator assembly of this invention which is similar to the form of the invention first described except that the housing, identified by numeral 12', is made larger to contain two cartridges 14, which may be serially activated to produce a substantially continuous flow of oxygen when one of the cartridges 14 is spent.
  • manifold 76' is substantially longer than manifold 76 to receive the output of both cartridges 14.
  • Retainer member 126 also is different in construction in order to accommodate both cartridges 14 and their actuating assemblies 144.
  • each cartridge 14 is provided with its own inner and outer liners, and 122, respectively, in a construction similar to that first described.
  • FIG. 1 illustrates another form of an oxygen generator assembly of this invention which is similar to the form of the invention first described except that the housing, identified by numeral 12', is made larger to contain two cartridges 14, which may be serially activated to produce a substantially continuous flow of oxygen when one of the cartridges 14 is spent.
  • manifold 76' is substantially longer than manifold 76 to
  • FIG. 2 also illustrates the use of a fastener 250 fixed to member 126 for securing the other end of tether strap 226 thereto preventing complete detachment of cover 20 and possible misplacement thereof.
  • the other elements shown in FIG. 2 are identical to those described in connection with the first form of the invention and are identified by similar reference characters.
  • An advantage residing in the second form of this invention is that the second cartridge can be ignited just prior to the depletion of the first to provide a continuous flow of oxygen to the user, if required. While the second cartridge is being consumed, the first can be replaced by still another cartridge to insure a continuous supply, when needed.
  • the present invention contemplates the use of any number of cartridges 14 suitably mounted in a common housing, as desired.
  • an oxygen generator is mounted within a housing in spaced relation thereto and is provided 'with means for dissipating the heat released from the burning generator by convection away from the housing to enable the latter to be safely handled by the user during combustion.
  • An easily cocked, manually operable actuating mechanism is releasably mounted in the housing in spaced relation to the generator to prevent overheating of the actuator.
  • a gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means affixed to and extending from the opposite ends thereof for suspending said cartridge in a fixed position between said end wall and said retainer in spaced relation therefrom to prevent direct transmission of heat between said cartridge and said retainer member, and actuating means for igniting said candle, said actuating means being mounted on said retainer in spaced relation from said cartridge to prevent direct transmission of heat between said candle and said actuating means.
  • a gas generator assembly according to claim 1 wherein said suspending means comprises hollow studs fixed to the opposite ends of said cartridge and defining passages therein.
  • said actuating means comprises a spring-loaded firing pin movable from a cocked position to a firing position, means retaining said firing pin in said cocked position, and means releasing said retaining means enabling said firing pin to move to said firing position.
  • a gas generator assembly according to claim 4 wherein said actuating means includes means for locking said releasing means to prevent actuation of said firing pin into said firing position.
  • a housing for a gas generator comprising: an elongated shell having an end wall and an open end, said end wall having a plurality of openings therethrough forming vent passages, a cover adapted to close said open end, means removably securing at least one gas generator cartridge within said shell in spaced relation thereto, spaced inner and outer liners interposed between said cartridge and said shell in spaced relation from said cartridge and said shell, respectively, said inner liner being provided with a multiplicity of openings for dissipating heat generated by the combustion of said cartridge, said inner and outer liners defining a passage for the dissipation of said heat, and said securing means having openings therein placing said passage in communication with the ambient atmosphere.
  • a housing according to claim 6 including means connecting said cover to said housing upon removal of said cover from said open end of said shell.
  • a housing according to claim 6 including manifold means interposed between said end wall and said cartridge and having oxygen passage means connecting said cartridge to a delivery tube.
  • a housing according to claim 9 wherein said housing contains two gas generator cartridges, each surrounded by a pair of said liners, said manifold connecting said cartridges to a common delivery tube.
  • a gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation there from, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, said suspending means comprising hollow studs fixed to the opposite ends of said cartridge as an integral part thereof, and a manifold fixed to said housing end wall and interposed between said housing end wall and the inner end of said cartridge, said manifold having means for receiving one of said cartridge studs in a slip fit engagement for properly positioning said cartridge in the desired orientation.
  • a gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite 10 ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation therefrom, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, and a pair of spaced inner and outer liners interposed between said cartridge and said shell in spaced relation therefrom.
  • a gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation therefrom, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, said suspending means comprising hollow studs fixed to the opposite ends of said cartridge as an integral part thereof, said actuating means comprising a casing releasably secured in said housing retainer member, and a retainer mounted in said casing for slip fitted engagement about one of said cartridge studs.

Abstract

A GAS GENERATOR ASSEMBLY COMPRISING A HOUSING CONTAINING AN OXYGEN EVOLVING CARTRIDGE IN SPACED RELATION TO THE HOUSING. A MANUALLY OPERABLE ACTUATING MECHANISM, EASILY RESET OR COCKED BY HAND, IS RELEASABLY SECURED IN THE HOUSING IN SPACED RELATION TO THE CARTRIDGE FOR IGNITING THE OXYGEN CANDLE THEREIN. A SAFTEY RELEASE PIN LOCKS THE ACTUATING

MECHANISM IN THE COCKED POSITION TO PREVENT INADVERTENT IGNITION OF THE CANDLE.

Description

Sept. 4, 1973 5. NETTELAND GAS GENERATOR ASSEMBLY 4 Sheets-Sheet 1 Filed Sept. 15, 1971 &
INVENTOR. .Zoya? G. fiefi ezanci BY ,6 AZ'ORNE'YS.
Sept. 4, 1 l... e. NETTELAND GAS GENERATOR ASSEMBLY 4 Sheets-Sheet 2 Filed Sept. 15, 1971 Z5 INVENTOR. Loyal G 7ZeZieZ0rza BY ATTORNEYS.
United States Patent Olmce 3,756,785 Patented Sept. 4, 1973 Int. Cl. 1301i 7/00 US. Cl. 23-281 16 Claims ABSTRACT OF THE DISCLOSURE A gas generator assembly comprising a housing containing an oxygen evolving cartridge in spaced relation to the housing. A manually operable actuating mechanism, easily reset or cooked by hand, is rele-asably secured in the housing in spaced relation to the cartridge for igniting the oxygen candle therein. A safety release pin locks the actuating mechanism in the cocked position to prevent inadvertent ignition of the candle.
BACKGROUND OF THE INVENTION This invention relates to a gas generator and, more particularly, to a self contained oxygen-evolving apparatus especially adapted for regular use by patients having respiratory ailments and for respiratory and cardiac emergencies.
Gas generators comprising oxygen evolving chlorate candles mounted in cannisters or containers are known, and offer certain advantages over cylinders of oxygen under pressure. Often, these known generators employ an over-the-center type of percussion actuator, which not only is difficult to cock for repeated action, but requires locating the primer in close proximity to the actuator. Since the heat of combustion of the primer and candle is intense, the actuator and container reach excessive temperatures. While such oxygen evolving generators are very useful in many emergency situations, such as might be encountered in submerged watercraft or high flying aircraft, they present a problem when used by respiratory patients or by medical personnel who must handle such generators and trigger the actuator by hand. Also, the difficulty in manually resetting or cocking the actuator for subsequent use with a freshly replaced oxygen candle renders them unsuitable for repeated usage by respiratory patients and by medical personnel.
SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an improved solid state gas generator assembly having a novel actuator that can be easily reset for repeated usage.
It is another object of this invention to provide the foregoing gas generator assembly with an actuator arrangement facilitating an optimal design relation betwen the primer and candle body and between the generator and the operator.
It is a further object of the present invention to provide a novel solid state gas generator housing having spaced heat dissipating and heat shielding means to preclude undesirable heat transmission to the housing.
It is still another object of this invention to provide the foregoing gas generator assembly with a self contained chemical oxygen evolving unit having means affixed to the opposite ends thereof for properly orienting such unit in a spaced relation to the actuator and the associated housing.
In one aspect thereof, the gas generator assembly of the present invention is characterized by the provision of stud means afiixed to the opposite ends of an oxygen evolving cartridge for spacing the latter from the ignition actuating mechanism and from the housing walls. The ignition actuating mechanism is easily operated and reset by hand and is provided with a locking mechanism to prevent inadvertent firing. An inner heat dissipating linear and an outer heat shield spaced therefrom are interposed between the oxygen evolving cartridge and the housing.
The foregoing and other objects, advantages and characterizing features of the present invention will become clearly apparent from the ensuing detailed description of an illustrative embodiment thereof, taken together with the accompanying drawing wherein like reference numerals denote like parts throughout.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal sectional view of one form of a gas generating assembly of the present invention;
FIG. 2 is a longitudinal sectional view of another form of gas generating assembly of this invention;
FIG. 3 is a fragmentary vertical sectional view, on an enlarged scale, showing the oxygen evolving unit and a portion of the ignition mechanism therefor;
FIG. 4 is a fragmentary vertical sectional view, on an enlarged scale, showing details of the ignition actuating mechanism in its locked, cocked position;
FIG. 5 is a transverse cross sectional view taken about on line 5-5 of FIG. 4;
FIG. 6 is a view similar to FIG. 4, showing the ignition actuating mechanism in its released, firing position;
FIG. 7 is a transverse cross sectional view taken about on line 7-7 of FIG. 6;
FIG. 8 is a transverse cross sectional view taken about on line 8-8 of FIG. 6; and
FIG. 9 is a transverse cross sectional view taken about on line 9-9 of FIG. 6.
DETAILED DESCRIPTION OF AN ILLUSTRATIVE EMBODIMENT Referring now in detail to the drawings, there is shown in FIG. 1 an illustrative embodiment of an oxygen generator assembly, generally designated 10, constructed in accordance with this invention, comprising a housing 12 for enclosing an oxygen generator cartridge 14. Housing 12 is of a generally cylindrical configuration and comprises a cylindrical tubular shell 16, a bottom end wall 18 having perforations 19 therethrough, and a top end cover 20. Cover 20 is releasably secured to shell 16 by any suitable means, such as a pair of conventional toggletype safety locks 21 for example. A strap 22 is connected to shell 16 by means of suitable fasteners 23 and is adapted to be looped over the head and about the neck of the user for supporting generator 10 preferably adjacent one side of the user in the area of the hip region. The terms top, bottom, upper, lower and the like are used for convenience of description with reference to the drawings and are not used in a limiting sense.
As shown in FIG. 3, oxygen generating cartridge 14 comprises a cannister 24 encasing an inner body composition capable of evolving oxygen upon burning. By way of example, the composition can consist of a consolidated core body, hereinafter referred to as an oxygen candle 26, having uniformly distributed therethrough an alkali metal chlorate or perchlorate which generates oxygen, a finely divided oxidiza-ble material such as iron powder for burning and supplying part of the heat needed for release of oxygen through an exothermic reaction, a binder such as inorganic glass fibers or steel wool for holding the mass together and aiding in the even decomposition of the chlorate or perchlorate, and barium peroxide or like chlorine fixes for chemically eliminating traces of chlorine gas released during thermal breakdown of the chlorate or perchlorate. Such oxygen candle compositions are known and, per se, form no part of the present invention. The body of oxygen candle 26 can be press-molded or cast to form a cylinder having an ignition area located centrally' at the 'upper end thereof, such ignition'area comprising the foregoing composition enriched with a metal powder, such as iron, to provide a concentrated area of intense heat when ignited. I
Candle body 26 is encased within a heat insulating envelope 28 of filter medium interposed between candle body 26 and cannister 24 to insulate the latter from the heat of combustion. Envelope 28 can be formed of fiberglass and, if desired, impregnated with a silicate or other hardening agent in an amount suflicient to make the envelope shape sustaining in the desired form. In the illustrative embodiment depicted in FIG. 3, an annular pad 30 is mounted on top of candle 26 and envelope 28 in spaced relation to the top end wall 32 ofcannister 24. A fiberchrome filter 31 is interposed between pad 30 and cannister top end wall 32. The bottom end 'of candle 26 is provided with a fiberfrax disc 33 having an inwardly dished portion resting on the complementary inwardly dished portion of a perforated bafiie plate 34 supported on a metallic screen 35. A layer of catalyst 36, such as the well known Hopcalite,.is sandwiched between a pair of fiberfrax discs 37 beneath oxygen candle 26 and is effective to oxidize to carbon dioxide any carbon monoxide that may result from the combustion of oxygen candle 26. The lower disc 37 is supported on a micro quartz pad 38 which, in turn, is supported on a fiberglass pad 39 resting on a metallic screen 40. Screen 40 rests against the inner surface of a cannister cover or bottom end wall 41, which is provided with an inturned, curved flange 42 at the marginal edge thereof rolled into sealing relation with an annular bead 44 forming a continuation of the cannister body and located at the bottom end thereof. Thus, in forming cartridge 14, the foregoing components are inserted through the bottom open end of cannister 24 and then sealed by cover 41.
Bottom end wall 41 is formed with an outwardly dished portion 46 defining a chamber 48 into which filtered oxygen is collected. A stud, generally designated 50 and having a bore 52 therein, is suitably attached to portion 46 of bottom wall 41 and is maintained in a gas tight relation therewith by means of a suitable seal 54. Stud 50 is provided with an annular abutment shoulder 56 and a tubular body 58 adapted to be received in a manifold coupling as will hereinafter become apparent.
Mounted on upper end wall 32 of cannister 24 in a gas tight relation therewith is a stud 60 having a flange 62 and a cylindrical body 64 extending downwardly from flange 62 to pad 30, which is provided with a central opening communicating with candle 26. A primer 66 is mounted within body 64 and communicates with the ignition area of oxygen candle 26 through a bore 67 provided in body 64. Stud 60 also includes a tubular body portion 68 extending upwardly from flange 62 and having an annular flange 70 spaced from flange 62. Body portion 68 is adapted to be received in a retainer forming part of the primer actuating mechanism and is bored as at 72 to receive a firing pin, hereinafter more fully described. The oxygen generating cartridge 14 thus far described includes studs 50 and 60 and constitutes a disposable, selfcontained unit which, when spent, can be replaced by a fresh unit in housing 12.
A manifold 76 is suitably secured to bottom end wall 18 of housing 12 (FIG. 1) as by means of screws 78 and is provided with a longitudinal passage 80 communicating with a tapped opening 82. One end of passage 80 leads to a port having a pressure relief valve 84 suitably threaded therein. The other end of passage 80 leads to a port 86 connected to a coupling 88 having a hose fitting 89 for connection to a flexible delivery tube (not shown) connected at its other end to the usual face mask, also not shown. The mask, delivery tube and a fitting connection when not in use, can be stored within cover 20. A fitting 90 is threaded into tapped opening 82 in a gas tight relation therewith and is provided with a bore 92 for receiving tubular body 58 of stud 50. A seal 94 is disposed in a peripheral groove formed in body 58 to provide pressure sealing between body 58 and fitting 90. Fitting is provided with an outer face 96 which serves as a seating surface for shoulder 56 of stud 50.
A cavity 98 is formed in manifold 76 in registry with opening 82 for receiving a check valve 100 therein. Check valve 100 is provided with a beveled resilient sealing surface 102 adapted to engage a beveled valve seat 104 formed on the end of fitting 90. Valve 100 is normally biased against valve seat 104 by means of a helical spring 106 disposed between the rear face of valve 100 and the bottom of cavity 98. The filtered oxygen under pressure generated by the combustion of candle 26 flows from chamber 48 through bore 52 of stud 50 and acts against valve 100 to urge the latter away from its seat 104, allowing the oxygen to flow through opening 82, passage 80, port 86, coupling 88 and ultimately to the user. Excess pressures are dissipated through relief valve 84 in the usual manner.
A support plate 110 is mounted within the lower end of housing 12 (FIG. 1) between manifold 76 and a stepped flange on fitting 90. Plate 110 has a generally circular planar portion 112 and an offset ledge 114 connected to portion 112 by an annular shoulder 116 and terminating in an annular flange 118. Plate 110 supports the lower ends of a pair of concentric, cylindrical liners 120 and 122 the inner lines 120 being mounted in spaced relation to cartridge 14 and perforated as at 124 for dissipating the heat generated by the combustion of candle 26. The lower end of liner 120 is supported on the planar portion 112 of plate 110 against shoulder 116. Outer liner 122, which serves as a heat shield, is spaced radially from liner 120 and is supported at its lower end on ledge 114 against flange 118. The upper ends of liners 120 and 122 are supported in spaced relation by means of a retainer member 126 bonded or otherwise fixedly secured to the upper end of housing shell 16. Member 126 has spaced cylindrical partitions 128 and 130 for embracing the upper ends of liners 120 and 122. A plurality of passages 132 are provided in member 126 and connect an annular passage 134 defined between liners 120 and 122 to the ambient atmosphere when cover 20 is removed from shell 16. Heat is dissipated during combustion of candle 26 by convection through the perforated liner 120 and upwardly through passages 134 and 132 to the ambient atmosphere. Liner 122 serves as a heat shield retaining the heat within passage 134 and preventing the transmission of heat to housing 12 thereby protecting the user against burning contact with housing 12. Member 126 is provided with a central tapped opening 138 for receiving a cup-shaped casing 140 threadably secured therein and provided with a bottom wall 142 for supporting an ignition actuating assembly, generally designated 144 (FIG. 4). Bottom wall 142 is provided with a plurality of openings 143 connecting the area within liner 120 with the ambient atmosphere to aid in the dissipation of heat generated by candle 26 during combustion.
As best shown in FIGS. 4-8, actuating assembly 144 comprises a retainer 146 having a flange 18 engaging against the underside of bottom wall 142 and a body portion 149 threadably secured to an actuator 150. Retainer 146 has a bore 152 therein for receiving the upper portion of tubular body 68 of stud 60 (FIG. 3) and a firing pin 154 having an axial projection 156 adapted to strike primer'66 for firing the latter. Flange 148 is provided with an annular rib 158 of generally triangular cross section having an annular apex portion 160 adapted to seat against stud flange 70 (FIG. 3) of cartridge 14 for properly locating the parts in the assembled relation. The entire actuating assembly 144 is assembled as a unit to cartridge 14 by inserting the upper end of stud 60 into bore 152 of retainer 146 and then threading casing 140 into opening 138 of member 126 until rib 158 seats against flange 70. Bore 72 of stud 60 is coaxially aligned with bore 152 of retainer 146 for receiving the end portion of firing pin 154 in the assembled relation with the upper portion of tubular body '68 interposed between retainer 146 and firing pin 154.
Actuator 150 comprises a generally cyclindrical body 164 having an end wall 166 provided with a central opening 168 therein. Body 164 is provided with four circumferentially spaced openings 170 for receiving balls 172 as shown in FIG. 8. Of course, more or less than four openings 170 and a corresponding number of balls 172 can be provided, as desired. Body 164 is provided with a re- 'duced diameter portion 174 and a further reduced diameter portion 176 separated by a beveled shoulder 178 for a purpose hereinafter explained. An insulator cap 180 is mounted on the upper end of body 164 about end wall 166 and is provided with an annular bead 182 received in a peripheral groove formed in body 164.
Firing pin 154 is provided with a cup-shaped member 184 formed integral therewith and telescopically received within actuator body 164. Member 184 is provided with openings 186 adjacent firing pin 154 to permit the heat of candle 26 to escape by convection. A compression spring 188 is mounted within member 184 for biasing firing pin 154 toward primer 66. Member 184 is provided with a peripheral groove 190 having a beveled cam surface 192 extending from groove 190 to the outer peripheral surface of member 184. Groove 190 receives portions of balls 172 when aligned with openings 170 of actuator 150 as shown in FIG. 4 and cam surface 192 aids in ejecting balls 172 out of groove 190 upon downward movement of member 184 relative to actuator 150.
An actuator sleeve 196 is mounted about actuator 150 for sliding movement relative thereto and comprises a hollow body 198 having an inner wall surface 199 and formed with an elongated enlargement 200 (FIG. 5) at one side thereof extending generally normal to the axis body 198. As shown in FIG. 9, a portion of the inner wall surface of body 198 is flat sided as at 195 and complementary to a flat sided portion 197 of actuator body 164 to prevent relative rotation therebetween. Thus, bodies 164 and 198 can move axially relative to each other but are keyed against relative rotational movement. The inner wall surface 199 of the upper portion of sleeve body 198 is provided with an annular beveled shoulder or cam surface 201 leading to an enlarged inside diameter portion 203. The lower portion of body 198 is provided with an enlarged cup-shaped configuration having a cylindrical Wall 202 radially spaced from actuator body 164 for receiving a compression spring 204 therein. The lower end of spring 204 abuts against a washer 206 supported between casing bottom wall 142 and an annular shoulder 208 provided adjacent the lower end of actuator body 164.
Enlargement 200 is provided with axially aligned bores 210 for receiving an elongated safety lock shaft 212, the central portion of which passes between portion 203 of sleeve body 198 and portions of the outer peripheral surface of actuator body 164. Enlarged heads 214 are secured to the opposite ends of shaft 212 as by means of suitable fasteners 216. These heads 214 are adapted to be received in cavities 218 provided at the opposite ends of enlargement 200. Shaft 212 is provided with an intermediate reduced diameter portion 220 having annular, bevelled shoulders or cam surfaces 222 leading to the outer peripheral surface of shaft 212. Shaft 212 is adapted to be shifted axially into a locked position as shown in FIGS. 4 and 5 whereby actuator sleeve 196 and actuator body 164 are keyed together and into a release position as shown in FIG. 7 whereby sleeve 196 can be moved vertically relative to actuator body 164.
Prior to use, the various components of actuating as sembly 144 are in the relative positions shown in FIGS. 4 and 5 with safety lock shaft 212 captively held between portion 203- of actuator sleeve 196 and the reduced diameter portion 176 of actuator body 164. Thus, actuator sleeve 196 and body 164 are keyed together preventing relative sliding movement therebetween. Also, balls 172 are captively disposed in openings 170 of actuator body 164 and partially in peripheral groove 190 of member 184. In this position, balls 172 lock member 184 upwardly against the bias of spring 188, thus maintaining firing pin 154 upwardly within bore 152 in a cocked position.
In use, strap 22 is placed about the users neck region in a manner supporting generator 10 along one side of the user and the toggle-type safety locks 21 are released. Cover 20 can then be removed from housing 12 and the breathing mask and delivery tube removed and connected to the coupling 89. The breathing mask is not placed about the users month until the oxygen generator is actuated and the oxygen evolving process initiated. Cover 20 is left dangling from generator 10 by means of a tether strap 226 connected at one end thereof to a central boss 228 in end cover 20 by a fastener 230 (FIG. 1) and connected at the other end to member 126 by any suitable means (not shown). Thus, although cover 20 is removed from housing 12 to expose actuating assembly 144, it remains attached thereto by strap 226 so as to prevent misplacement thereof.
The user then shifts safety lock shaft 212 axially to position the reduced diameter portion 220 between portion 203 of actuator sleeve 196 and portion 176 of actuator body 164 to permit actuation of assembly 144. To initiate the oxygen evolving process, actuator sleeve 196 is slid downwardly relative to body 164 against the bias of spring 104 to the position shown in FIG. 6. This relative movement can be effected due to the reduced diameter portion 220 of shaft 212 which readily fits into the space between portion 203 of sleeve 196 and portion 174 of body 164.
Upon relative sliding movement between sleeve 196 and body 164, the larger inside diameter portion 203 of sleeve 1% provides a wider space for receiving balls 172 which are cammed radially outwardly from grooves 190 by cam surface 192 under the influence of spring 188. Member 184 is thereby released allowing the force of spring 188 compressed therein to drive firing pm 154 downwardly into contact with primer 66 for igniting the latter and initiating ignition of oxygen candle 26. When firing pin 154 is released, the various components of actuating assembly 144 are in the relative positions shown in FIG. 6. The evolved oxygen passes through chamber 48, bore 52 of stud 50 and bore 92 of fitting The pressure of the evolved oxygen builds up and acts against the face of check valve until such pressure overcomes the bias of spring 106 to unseat valve 100'. The oxygen escapes past check valve 100, through passage 80, port 86, coupling 88, hose fitting 89 and the delivery tube to the face mask at a rate sufficient to meet the oxygen consumption :2 the user. Excess pressures are relieved through valve The heat generated by the combustion of oxygen candle 26 is dissipated by convection through perforated liner 120, passages 134, 132 and outwardly through the open end of housing 12 into the ambient atmosphere. Perforations 19 in bottom end wall 18 permit cool air to communicate with the interior of housing 12 to ventilate the latter and facilitate such heat dissipation. Any heat transmitted upwardly is dissipated through openings 143 in member 126 and through retainer bore 152, openings 186, the interior of cup-shaped member 184, and outwardly through aligned openings in end wall 166 and cap memher 180. Outer liner 122 serves as a heat shield and aids in directing the heat upwardly through passage 134. Housing wall 16, which is spaced from liner 122, is virtually uneffected by the intense heat generated by oxygen candle 26, which heat is dissipated outwardly through perforated liner and upwardly by convection through the open end of housing 12. Also, the suspension of cartridge 14 within housing 12 at only two points by means once candle 26 is of studs 50 and '60 significantly contributes to the dissipation of heat away from housing 12. As a result, the temperature of housing shell 16 remains low and is harmless against human contact therewith. This is especially significant when it is realized that cannister 24 maintains a temperature of approximately 400 F. during normal combustion of the candle.
The size and the oxygen evolving duration of cartridge 14 can vary, as desired. Also, oxygen candle 26 can be of the multi-stage ignition type providingfull flow operation at the mask within a predetermined minimal time limit and provding a minimum rate of relatively high oxygen flow for the first few minutes followed by a smooth transition to a minimum rate of reduced oxygen flow for the remainder of the oxygen evolving duration. However, ignited, it will continue to burn until expended.
In order to replace a spent cartridge 14 with a fresh one and to reset actuating'asse'mbly 144 for subsequent operation, cover is removed and casing 140 is threaded out of retainer member 126, carrying with it the entire ignition actuating assembly 146 to expose cartridge 14. To facilitate the removal of a spent cartridge 14, a tool 234 (FIG. 1) is releasably mounted in cover 20- as by means of a spring clip 236 fixed to fastener 230.
Tool 234 comprises a strip 236 of metal reversely bent to form a loop 238 which serves as a handle for tool 234. The reversely bent portion is spaced from the main strip portion by a spacer element 240 and is connected thereto by means of a suitable fastener 242. The distal end of tool 234 is bent inwardly as at 244 and is bifurcated to provide spaced fingers 246 (only one of which is shown in FIG. 1) adapted to engage about body portion 68 of stud 60 below flange 70. The angular bend 244 in tool 234 facilitates the entry of fingers 246 into opening 138 of retainer member 126 and the positioning thereof about stud 60 so as to apply upward pressure against flange 70 and raise cartridge 14 out of housing 12. A fresh cartridge 14 can then be placed in housing 12 with tubular body '58 of stud 50 inserted within fitting 90 until shoulder 56 abuts against face 96 of fitting 90. Thus, cartridge 14 is correctly positioned within housing 12 in readiness to receive actuating assembly 144, which must be reset and cocked prior to assembly with cartridge 14.
When actuating assembly 144 is detached from retainer member 126, the various parts thereof are in the relative positions shown in FIG. 6. In order to reset or cock actuating assembly 144, firing pin 154 is forced within actuator body 150 against the bias of spring 188. When groove 190 is aligned with openings 170 in body 150, balls 172 will be shifted inwardly by cam surface 201 of actuator sleeve 196 under the influence of spring 204. Actuator sleeve 1% is then free to move upwardly relative to body 150 under the urging of spring 204, carrying safety lock shaft 212 therewith. The various parts of actuating assembly 144 are then in the relative positions illustrated in FIG. 4 and firing pin 154 is held in its cocked position by means of balls 172. Lock shaft 212 is shifted axially to lock actuating sleeve 196 in its raised position to prevent inadvertent release of firing pin 154. Casing 140, together with actuating assembly 146 in its cocked position, can then be assembled to retainer member 126 and cartridge 14 in a manner hereinbefore described.
FIG. 2 illustrates another form of an oxygen generator assembly of this invention which is similar to the form of the invention first described except that the housing, identified by numeral 12', is made larger to contain two cartridges 14, which may be serially activated to produce a substantially continuous flow of oxygen when one of the cartridges 14 is spent. As shown in FIG. 2, manifold 76' is substantially longer than manifold 76 to receive the output of both cartridges 14. Retainer member 126 also is different in construction in order to accommodate both cartridges 14 and their actuating assemblies 144. However, each cartridge 14 is provided with its own inner and outer liners, and 122, respectively, in a construction similar to that first described. FIG. 2 also illustrates the use of a fastener 250 fixed to member 126 for securing the other end of tether strap 226 thereto preventing complete detachment of cover 20 and possible misplacement thereof. The other elements shown in FIG. 2 are identical to those described in connection with the first form of the invention and are identified by similar reference characters.
An advantage residing in the second form of this invention is that the second cartridge can be ignited just prior to the depletion of the first to provide a continuous flow of oxygen to the user, if required. While the second cartridge is being consumed, the first can be replaced by still another cartridge to insure a continuous supply, when needed. Of course, the present invention contemplates the use of any number of cartridges 14 suitably mounted in a common housing, as desired.
From the foregoing, it is apparent that the objects of the present invention have been fully accomplished. As a result of this invention, an oxygen generator is mounted within a housing in spaced relation thereto and is provided 'with means for dissipating the heat released from the burning generator by convection away from the housing to enable the latter to be safely handled by the user during combustion. An easily cocked, manually operable actuating mechanism is releasably mounted in the housing in spaced relation to the generator to prevent overheating of the actuator.
Certain embodiments of this invention having been described and illustrated in detail, it is to be understood that this has been done by way of illustration only.
What is claimed is:
l. A gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means affixed to and extending from the opposite ends thereof for suspending said cartridge in a fixed position between said end wall and said retainer in spaced relation therefrom to prevent direct transmission of heat between said cartridge and said retainer member, and actuating means for igniting said candle, said actuating means being mounted on said retainer in spaced relation from said cartridge to prevent direct transmission of heat between said candle and said actuating means.
2. A gas generator assembly according to claim 1 wherein said suspending means comprises hollow studs fixed to the opposite ends of said cartridge and defining passages therein.
3. A gas generator assembly according to claim 1 wherein said cartridge is a self-contained unit separably insertable in and removable from said housing.
4. A gas generator assembly according to claim 1 wherein said actuating means comprises a spring-loaded firing pin movable from a cocked position to a firing position, means retaining said firing pin in said cocked position, and means releasing said retaining means enabling said firing pin to move to said firing position.
5. A gas generator assembly according to claim 4 wherein said actuating means includes means for locking said releasing means to prevent actuation of said firing pin into said firing position.
6. A housing for a gas generator comprising: an elongated shell having an end wall and an open end, said end wall having a plurality of openings therethrough forming vent passages, a cover adapted to close said open end, means removably securing at least one gas generator cartridge within said shell in spaced relation thereto, spaced inner and outer liners interposed between said cartridge and said shell in spaced relation from said cartridge and said shell, respectively, said inner liner being provided with a multiplicity of openings for dissipating heat generated by the combustion of said cartridge, said inner and outer liners defining a passage for the dissipation of said heat, and said securing means having openings therein placing said passage in communication with the ambient atmosphere.
7. A housing according to claim 6 including means connecting said cover to said housing upon removal of said cover from said open end of said shell.
8. A housing according to claim 6 wherein said cover is provided with means for carrying a cartridge removing tool.
9. A housing according to claim 6 including manifold means interposed between said end wall and said cartridge and having oxygen passage means connecting said cartridge to a delivery tube.
10. A housing according to claim 9 wherein said housing contains two gas generator cartridges, each surrounded by a pair of said liners, said manifold connecting said cartridges to a common delivery tube.
11. A gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation there from, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, said suspending means comprising hollow studs fixed to the opposite ends of said cartridge as an integral part thereof, and a manifold fixed to said housing end wall and interposed between said housing end wall and the inner end of said cartridge, said manifold having means for receiving one of said cartridge studs in a slip fit engagement for properly positioning said cartridge in the desired orientation.
12. A gas generator assembly according to claim 11 wherein said manifold is provided with passage means establishing communication between said cartridge and a delivery tube leading to a face mask.
13. A gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite 10 ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation therefrom, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, and a pair of spaced inner and outer liners interposed between said cartridge and said shell in spaced relation therefrom.
14. A gas generator assembly according to claim 13 wherein said inner liner is perforated forming vent passages therethrough for dissipating heat generated by the combustion of said candle.
15. A gas generator according to claim 13 wherein said outer liner comprises a shield means preventing transmission of heat to said housing shell.
16. A gas generator assembly comprising: a housing comprising a shell, an end wall and an open end, a cover adapted to close said open end of said housing shell, a retainer member mounted in said housing adjacent said open end, a cartridge containing an oxygen-evolving candle therein mounted within said housing in spaced relation from said shell, said cartridge having means at the opposite ends thereof for suspending said cartridge between said end wall and said retainer in spaced relation therefrom, actuating means mounted on said retainer in spaced relation from said cartridge for igniting said candle, said suspending means comprising hollow studs fixed to the opposite ends of said cartridge as an integral part thereof, said actuating means comprising a casing releasably secured in said housing retainer member, and a retainer mounted in said casing for slip fitted engagement about one of said cartridge studs.
References Cited UNITED STATES PATENTS 2,114,142 4/1938 Hloch 23-281 3,385,672 5/1968 McGofi et a1. 23-281 3,443,907 5/1969 Marsteller 23-281 3,565,068 2/1971 Bickford 23-281 X 3,580,250 5/1971 Oroza 23-281 X 3,607,122 9/1971 Hwaschinsky 23-281 3,620,683 11/1971 Hwaschinsky et al. 23-281 FOREIGN PATENTS 498,449 12/1953 Canada 23-281 601,295 5/ 1948 Great Britain 23-281 834,422 5/1956 Great Britain 23-281 BARRY S. RICHMAN, Primary Examiner US. Cl. X.R.
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Cited By (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3860396A (en) * 1973-08-13 1975-01-14 Olin Corp Oxygen generator
US4111661A (en) * 1974-12-27 1978-09-05 Rothenberger Gmbh Werkzeuge Und Maschinen Kg Oxygen generator with cartridge holder for oxygen-yielding cartridges
US4140765A (en) * 1976-07-17 1979-02-20 Westinghouse Electric Corp. Gas flow-sensor for chemical oxygen generation device
JPS55151834U (en) * 1979-04-16 1980-11-01
FR2494995A1 (en) * 1980-11-29 1982-06-04 Draegerwerk Ag OXYGEN CHEMICAL GENERATOR
US4342725A (en) * 1978-10-19 1982-08-03 Preiser Scientific, Incorporated Oxygen supply apparatus
FR2558388A1 (en) * 1984-01-23 1985-07-26 Ruggieri Ets CHEMICAL OXYGEN GENERATOR WITH REDUCED IMPURITY RATE
US4628970A (en) * 1983-11-22 1986-12-16 Kothenberger GmbH & Co. Werkzeuge-Maschinen KG Apparatus for refilling compressed-gas bottles
US4687640A (en) * 1985-11-08 1987-08-18 Figgie International Inc. Chlorine gas filtering material suitable for use in a chemical oxygen generator
US4891189A (en) * 1988-07-06 1990-01-02 Figgie International, Inc. High flow chemical oxygen generator assembly
WO1997010025A1 (en) * 1995-09-11 1997-03-20 Palmer Kenneth J Personal oxygen dispenser
WO1999010093A1 (en) * 1997-08-21 1999-03-04 Nikolai Nikolaevich Sysoev Method for generating a low-temperature gas from solid fuel
US6684881B2 (en) * 2000-04-28 2004-02-03 Fraanberg Oskar Rechargeable breathing apparatus particularly an apparatus for divers
US20140000592A1 (en) * 2012-06-28 2014-01-02 Intertechnique Chemical oxygen generator with bimetal reaction control
US8845325B1 (en) * 2010-10-26 2014-09-30 The United States Of America As Represented By The Secretary Of The Navy Oxygen candle furnace ignition fitting
CN104176709A (en) * 2014-08-18 2014-12-03 中国工程物理研究院化工材料研究所 High-capacity all solid oxygen generator
US20150151144A1 (en) * 2013-12-03 2015-06-04 Intertechnique Chemical oxygen generator with compact design
CN108136151A (en) * 2016-02-18 2018-06-08 氧气生成产品私人有限公司 Modular portable oxygen generator

Cited By (24)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3860396A (en) * 1973-08-13 1975-01-14 Olin Corp Oxygen generator
US4111661A (en) * 1974-12-27 1978-09-05 Rothenberger Gmbh Werkzeuge Und Maschinen Kg Oxygen generator with cartridge holder for oxygen-yielding cartridges
US4140765A (en) * 1976-07-17 1979-02-20 Westinghouse Electric Corp. Gas flow-sensor for chemical oxygen generation device
US4342725A (en) * 1978-10-19 1982-08-03 Preiser Scientific, Incorporated Oxygen supply apparatus
JPS55151834U (en) * 1979-04-16 1980-11-01
FR2494995A1 (en) * 1980-11-29 1982-06-04 Draegerwerk Ag OXYGEN CHEMICAL GENERATOR
US4628970A (en) * 1983-11-22 1986-12-16 Kothenberger GmbH & Co. Werkzeuge-Maschinen KG Apparatus for refilling compressed-gas bottles
FR2558388A1 (en) * 1984-01-23 1985-07-26 Ruggieri Ets CHEMICAL OXYGEN GENERATOR WITH REDUCED IMPURITY RATE
US4623520A (en) * 1984-01-23 1986-11-18 Etablissements Ruggieri Chemical oxygen generator with a low content of impurities
US4687640A (en) * 1985-11-08 1987-08-18 Figgie International Inc. Chlorine gas filtering material suitable for use in a chemical oxygen generator
US4891189A (en) * 1988-07-06 1990-01-02 Figgie International, Inc. High flow chemical oxygen generator assembly
US5620664A (en) * 1995-09-11 1997-04-15 Palmer; Kenneth J. Personal oxygen dispenser
WO1997010025A1 (en) * 1995-09-11 1997-03-20 Palmer Kenneth J Personal oxygen dispenser
WO1999010093A1 (en) * 1997-08-21 1999-03-04 Nikolai Nikolaevich Sysoev Method for generating a low-temperature gas from solid fuel
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CN104176709B (en) * 2014-08-18 2016-08-17 中国工程物理研究院化工材料研究所 The all solid state oxygen generator of Large Copacity
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CN108136151B (en) * 2016-02-18 2021-06-08 氧气生成产品私人有限公司 Modular portable oxygen generator

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