Described herein are various embodiments of an oxygen concentrator system that includes a home oxygen concentrator system couplable to a portable oxygen concentrator system.
대표청구항▼
1. A method of producing oxygen enriched gas, comprising: positioning at least a portion of a first oxygen concentrator apparatus in a support structure of a second oxygen concentrator apparatus, wherein the support structure has a size and shape complementary to the size and shape of the first oxyg
1. A method of producing oxygen enriched gas, comprising: positioning at least a portion of a first oxygen concentrator apparatus in a support structure of a second oxygen concentrator apparatus, wherein the support structure has a size and shape complementary to the size and shape of the first oxygen concentrator apparatus, the first oxygen concentrator apparatus comprising: at least two canisters;gas separation adsorbent disposed in the at least two canisters, wherein the gas separation adsorbent separates at least some nitrogen from air in the canister to produce oxygen enriched gas;a compression system comprising at least one compressor coupled to at least one canister; anda first apparatus controller that controls operation of the first oxygen concentrator apparatus using operating parameters stored in the first apparatus controller;the second oxygen concentrator apparatus comprising: at least two canisters;gas separation adsorbent disposed in the at least two canisters, wherein the gas separation adsorbent separates at least some nitrogen from air in the canister to produce oxygen enriched gas;a compression system comprising at least one compressor coupled to at least one canister; anda second apparatus controller that controls operation of the second oxygen concentrator apparatus using operating parameters stored in the second apparatus controller; andwherein the first oxygen concentrator apparatus and the second oxygen concentrator apparatus are independently operable;electrically coupling the first oxygen concentrator apparatus to the second oxygen concentrator apparatus, wherein the electrical connection provides electrical power from the second oxygen concentrator apparatus to the first oxygen concentrator apparatus and wherein the electrical connection further allows information to be exchanged between the first apparatus controller and the second apparatus controller. 2. The method of claim 1, further comprising regenerating gas adsorbent in the first oxygen concentrator apparatus while providing oxygen enriched gas to the user from the second oxygen apparatus. 3. The method of claim 1, further comprising controlling the first and second oxygen concentrator apparatus using the first apparatus controller. 4. The method of claim 1, further comprising controlling the first and second oxygen concentrator apparatus by transmitting a signal from a wireless controller to the first apparatus controller and/or the second apparatus controller. 5. The method of claim 1, further comprising collecting diagnostic information regarding the operation of the first oxygen concentrator apparatus using the first apparatus controller; and collecting diagnostic information regarding the operation of the second oxygen concentrator apparatus with the first apparatus controller, when the first oxygen concentrator apparatus is coupled to the second oxygen concentrator apparatus. 6. The method of claim 5, further comprising coupling the first apparatus controller to a computer system, wherein the computer system: analyzes the collected diagnostic information; determines new operating parameters for the first oxygen concentrator apparatus and/or the second oxygen concentrator apparatus; and stores the new operating parameters for the first oxygen concentrator apparatus and/or the second oxygen concentrator apparatus on the first apparatus controller. 7. The method of claim 6, further comprising using the first apparatus controller to change the operating parameters stored on the second apparatus controller to the new operating parameters prepared by the computer system for the second oxygen concentrator apparatus when the first oxygen concentrator apparatus is coupled to the second oxygen concentrator apparatus. 8. The method of claim 1, wherein the support structure couples a power supply of the second oxygen concentrator apparatus to the power supply of the first oxygen concentrator apparatus, wherein the power supply of the first oxygen concentrator apparatus comprises a rechargeable power supply, and wherein the method further comprises recharging the rechargeable power supply of the first oxygen concentrator apparatus using the power supply of the second oxygen concentrator apparatus through the support structure. 9. The method of claim 1, wherein the support structure comprises one or more conduits that couple the compressor of the first oxygen concentrator apparatus to one or more of the canisters of the second oxygen concentrator apparatus, wherein the method further comprises operating the compressor of the first oxygen concentrator apparatus to provide compressed air to one or more of the conduits of the second oxygen concentrator apparatus when the first oxygen concentrator apparatus is coupled to the second oxygen concentrator apparatus. 10. The method of claim 1, further comprising decoupling the first oxygen concentrator apparatus from the second oxygen concentrator apparatus and coupling a portable controller to the second oxygen concentrator apparatus via the support structures, wherein the portable controller operates the second oxygen concentrator apparatus. 11. The method of claim 1, wherein the second oxygen concentrator apparatus further comprises one or more conduits that couple the outlet of one or more canisters of the second oxygen concentration apparatus to the first oxygen concentrator apparatus such that oxygen enriched gas is provided to the first oxygen concentrator apparatus from the second oxygen concentrator apparatus. 12. The method of claim 1, wherein the second oxygen concentrator apparatus further comprises an oxygen enriched gas storage container and one or more conduits that couple the oxygen enriched gas storage container to the first oxygen concentrator apparatus, wherein the method further comprises providing oxygen enriched gas to the first oxygen concentrator apparatus from the oxygen enriched gas storage container. 13. The method of claim 12, wherein the conduits couple the oxygen enriched gas storage container to an expansion chamber of the first oxygen concentrator apparatus. 14. The method of claim 12, wherein the one or more conduits couple the outlet of one or more canisters of the second oxygen concentration apparatus to an accumulator of the first oxygen concentrator apparatus. 15. The method of claim 1, wherein one or more conduits couple the outlet of one or more canisters of the second oxygen concentration apparatus to an outlet conduit of the first oxygen concentration apparatus that provides oxygen to a user of the first oxygen concentrator apparatus. 16. The method of claim 1, wherein patient specific oxygen enriched gas delivery parameters are stored on the first apparatus controller, and wherein the method further comprises altering the operating parameters of the second apparatus controller using the first apparatus controller such that oxygen enriched gas produced and delivered by the second oxygen concentrator apparatus corresponds to the patient specific oxygen enriched gas delivery parameters. 17. An oxygen concentrator system, comprising: a first oxygen concentrator apparatus, the first oxygen concentrator apparatus comprising: at least two canisters;gas separation adsorbent disposed in the at least two canisters, wherein the gas separation adsorbent separates at least some nitrogen from air in the canister to produce oxygen enriched gas;a compression system comprising at least one compressor coupled to at least one canister; anda first apparatus controller that controls the operation of the first oxygen concentrator apparatus;a second oxygen concentrator apparatus, the second oxygen concentrator apparatus comprising: at least two canisters;gas separation adsorbent disposed in the at least two canisters, wherein the gas separation adsorbent separates at least some nitrogen from air in the canister to produce oxygen enriched gas;a compression system comprising at least one compressor coupled to at least one canister;a second apparatus controller that controls the operation of the second oxygen concentrator apparatus using operating parameters stored in the second apparatus controller; andwherein second oxygen concentrator apparatus comprises a support structure which has a size and shape complementary to the size and shape of the first oxygen concentrator apparatus, and wherein the first oxygen concentrator apparatus fits at least partially within the support structure;wherein the first oxygen concentrator apparatus and the second oxygen concentrator apparatus are independently operable; andwherein the first oxygen concentrator system comprises an first electrical connection port and wherein the second oxygen concentrator system comprises a second electrical connection port, and wherein the first and second electrical connection ports allow the first oxygen concentrator apparatus to be electrically coupled to the second oxygen concentrator apparatus, wherein the electrical connection provides electrical power from the second oxygen concentrator apparatus to the first oxygen concentrator apparatus and wherein the electrical connection further allows information to be exchanged between the first apparatus controller and the second apparatus controller. 18. The oxygen concentrator system of claim 17, wherein the first apparatus controller collects diagnostic information regarding the operation of the first oxygen concentrator apparatus; and wherein the first apparatus controller collects diagnostic information regarding the operation of the second oxygen concentrator apparatus, when coupled to the second apparatus controller. 19. The oxygen concentrator system of claim 18, wherein the first apparatus controller is coupleable to a computer system, wherein the computer system: analyzes the collected diagnostic information; determines new operating parameters for the first oxygen concentrator apparatus and/or the second oxygen concentrator apparatus; and stores the new operating parameters for the first oxygen concentrator apparatus and/or the second oxygen concentrator apparatus on the first apparatus controller. 20. The oxygen concentrator system of claim 19, wherein the first apparatus controller changes the operating parameters stored on the second apparatus controller to the new operating parameters prepared by the computer system for the second oxygen concentrator apparatus when the first apparatus controller is coupled to the second apparatus controller. 21. The oxygen concentrator system of claim 17, wherein the support structure couples a power supply of the second oxygen concentrator apparatus to the power supply of the first oxygen concentrator apparatus, wherein the power supply of the first oxygen concentrator apparatus comprises a rechargeable power supply, and wherein the rechargeable power supply of the first oxygen concentrator apparatus is recharged by the power supply of the second oxygen concentrator apparatus through the support structure. 22. The oxygen concentrator system of claim 17, further comprising a portable controller, coupleable to the second oxygen concentrator apparatus via the support structure, wherein the portable controller operates the second oxygen concentrator apparatus. 23. The oxygen concentrator system of claim 17, wherein patient specific oxygen enriched gas delivery parameters are stored on the first apparatus controller, and wherein the first apparatus controller alters the operating parameters of the second apparatus controller such that oxygen enriched gas is produced and delivered by the second oxygen concentrator apparatus corresponds to the patient specific oxygen enriched gas delivery parameters. 24. The oxygen concentrator system of claim 17, wherein the second oxygen concentrator system further comprises one or more conduits that couple the outlet of one or more canisters of the second oxygen concentration apparatus to the first oxygen concentrator apparatus such that oxygen enriched gas is provided to the first oxygen concentrator apparatus from the second oxygen concentrator apparatus. 25. The oxygen concentrator system of claim 17, wherein one or more conduits couple the outlet of one or more canisters of the second oxygen concentration apparatus to an accumulator of the first oxygen concentrator apparatus. 26. The oxygen concentrator system of claim 17, wherein one or more conduits couple the outlet of one or more canisters of the second oxygen concentration apparatus to an outlet conduit of the first oxygen concentration apparatus that provides oxygen to a user of the first oxygen concentrator system.
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Phillips Robert E. ; Otsap Ben A., Activity responsive therapeutic delivery system.
Richey ; II Joseph B. ; Goertzen Gerold G., Apparatus and method for forming oxygen-enriched gas and compression thereof for high-pressure mobile storage utilization.
Monereau Christian,FRX ; Derive Nathalie,FRX ; Petit Pierre,FRX, Apparatus and process for the separation of gas mixtures by pressure swing adsorption.
Dietz Henry G. (80 Salisbury Ave. Garden City NY 11530), Apparatus for inhalation therapy using triggered dose oxygenator employing an optoelectronic inhalation sensor.
Russel ; Sr. Larry L. (4109 Ravine Dr. Cana Winchester OH 43110) Anderson George A. (1239A Lakeshore Dr. Columbus OH 43229), Inhalation-based control of medical gas.
Snook James A. (Overland Park KS) Nelson Thomas W. (Lenexa KS) Wyble Marilyn S. (Overland Park KS) Trimble Russell L. (Overland Park KS), Inspiration oxygen saver.
Chua James ; Salter Peter W. ; Kelly Francis J. ; Wada Robert Toshiaki ; Fujimoto Roy Yasuo, Intermitten gas-insufflation apparatus and method therefor.
Chua James (Tehachapi CA) Salter Peter W. (Tehachapi CA) Kelly Francis J. (Upland CA) Wada Robert Toshiaki (Claremont CA) Fujimoto Roy Yasuo (Upland CA), Intermittent gas-insufflation apparatus.
Jagger, Theodore W.; Van Brunt, Nicholas P.; Kivisto, John A.; Lonnes, Perry B., Method and apparatus for controlling the purity of oxygen produced by an oxygen concentrator.
Bowen,Kevin; Jonczak,Daniel; Yurko,Gregory; Mechlenburg,Douglas M.; Duff,Winslow K.; D'Angelo,Mark, Method and apparatus for monitoring and controlling a medical device.
Tiep Brian L. (632 Norumbega Dr. Monrovia CA 91016) Phillips Robert E. (12217 Iredell St. Studio City CA 91601) Otsap Ben A. (7661 Airport Blvd. Los Angeles CA 90045), Method and apparatus for supplying a gas to a body.
Dietz Henry G. (80 Salisbury Ave. Garden City NY 11530), Method and apparatus for using an inhalation sensor for monitoring and for inhalation therapy.
Mondry Adolph J. (46340 Concord Dr. Plymouth MI 48170), Method for delivering incremental doses of oxygen for maximizing blood oxygen saturation levels.
Jagger, Theodore W.; Van Brunt, Nicholas P.; Kivisto, John A.; Lonnes, Perry B., Method of controlling the rate of oxygen produced by an oxygen concentrator.
Honkonen, Scott C.; Hill, Theodore B.; Hill, Charles C.; Walker, Graham, Methods and apparatus to generate liquid ambulatory oxygen from an oxygen concentrator.
Connor, Denis J.; Keefer, Bowie G.; McLean, Christopher R.; Knights, Shanna D.; St-Pierre, Jean, Methods and apparatuses for gas separation by pressure swing adsorption with partial gas product feed to fuel cell power source.
Cao Tuan Quoc ; Hart Russell Frank ; Molis William David ; Frantz Richard Kent ; Hager Charles Bradley ; Crome Victor Paul, Oxygen concentrator with beds' duty cycle control and self-test.
Yagi, Hideaki; Kojima, Takahito; Akiyama, Junichi, Oxygen enriching apparatus, controller for the oxygen enriching apparatus, and recording medium for the controller.
Appel, William Scot; Winter, David Phillip; Sward, Brian Kenneth; Sugano, Masato; Salter, Edmund; Bixby, James A., Portable oxygen concentration system and method of using the same.
Ackley, Mark William; Smolarek, James; Leavitt, Frederick Wells, Pressure swing adsorption gas separation method, using adsorbents with high intrinsic diffusivity and low pressure ratios.
Graham, David Ross; Whitley, Roger Dean; Chiang, Robert Ling; Weist, Jr., Edward Landis; Golden, Timothy Christopher; Labuda, Matthew James, Pressure swing adsorption process operation and optimization.
Schrter Hans (Mlheim/Ruhr DEX) Heimbach Heinrich (Essen DEX) Tarnow Ferdinand (Duisburg DEX), Process for at least partially separating a gaseous component from a mixture of gaseous components.
Moreau Serge (Velizy Villacoublay FRX) Barbe Christian (Fontenay Sous Bois FRX), Process for the separation of mixtures of oxygen and of nitrogen employing an adsorbent with improved porosity.
Moseley Robin (Allentown PA) Spira Joel S. (Coopersburg PA) Karunaratne Arjuna (Santa Clara CA) Wylie John (Allentown PA) Barney Jonathan A. (Whitehall PA), Remotely controllable power control system.
McCormick,James J.; Jou,William; Anthony,David; Isagholian,David, Respiratory mask having intraoral mouthpiece with large sealing area and multiple sealing configuration.
Kandybin Alexander I. (Toledo OH) Anderson Richard A. (Katonah NY) Reichley Daniel L. (Toledo OH), System for separation of oxygen from argon/oxygen mixture.
Deane, Geoffrey Frank; Jenneve, Jeffrey; Morison, Charles; Taylor, Brenton Alan, Systems and methods of monitoring and controlling the performance of a gas fractionalization apparatus.
Dee, Douglas Paul; Chiang, Robert Ling; Gondecki, Gregory John; Whitley, Roger Dean; Ostroski, Jane Elizabeth, Use of lithium-containing fau in air separation processes including water and/or carbon dioxide removal.
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