[미국특허]
Battery resetting process for scaffold fuel electrode
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H01M-012/08
H01M-010/42
H01M-010/44
H01M-002/40
출원번호
US-0277031
(2011-10-19)
등록번호
US-9105946
(2015-08-11)
발명자
/ 주소
Friesen, Cody A.
Krishnan, Ramkumar
Trimble, Todd
Puzhaev, Sergey
출원인 / 주소
FLUIDIC, INC.
대리인 / 주소
Pillsbury Winthrop Shaw Pittman, LLP
인용정보
피인용 횟수 :
2인용 특허 :
128
초록▼
An electrochemical cell includes a fuel electrode configured to operate as an anode to oxidize a fuel when connected to a load. The cell also includes an oxidant electrode configured to operate as a cathode to reduce oxygen when connected to the load. The fuel electrode comprises a plurality of scaf
An electrochemical cell includes a fuel electrode configured to operate as an anode to oxidize a fuel when connected to a load. The cell also includes an oxidant electrode configured to operate as a cathode to reduce oxygen when connected to the load. The fuel electrode comprises a plurality of scaffolded electrode bodies. The present invention relates to an electrochemical cell system and method of resetting the electrochemical cell by applying a charge (i.e. voltage or current) to the cell to drive oxidation of the fuel, wherein the fuel electrode operates as an anode, and the second cell operates as a cathode, removing uneven distributions of fuel that may cause premature shorting of the electrode bodies to improve capacity, energy stored, and cell efficiency.
대표청구항▼
1. A method for resetting an electrochemical cell, the electrochemical cell comprising: a fuel electrode comprising a series of permeable electrode bodies arranged in spaced apart relation for receiving electrodeposited metal fuel;an oxidant electrode spaced from the fuel electrode;a charging electr
1. A method for resetting an electrochemical cell, the electrochemical cell comprising: a fuel electrode comprising a series of permeable electrode bodies arranged in spaced apart relation for receiving electrodeposited metal fuel;an oxidant electrode spaced from the fuel electrode;a charging electrode;an ionically conductive medium contacting the electrodes;the fuel electrode and the oxidant electrode being configured to, during discharge, oxidize the metal fuel at the fuel electrode and reduce an oxidant at the oxidant electrode to generate a electrical discharge current therebetween for application to a load; andthe fuel electrode and the charging electrode being configured to, during re-charge, reduce a reducible species of the fuel to electrodeposit the fuel on the fuel electrode and oxidize an oxidizable species of the oxidant by application of a electrical recharge current therebetween from a power source;the method comprising: applying an electrical reset current between the fuel electrode and at least one other aforesaid electrode of the cell with the fuel electrode functioning as an anode and the other aforesaid electrode functioning as a cathode, such that the metal fuel on the fuel electrode is oxidized into the reducible fuel species; andremoving the electrical reset current to discontinue the resetting process. 2. The method of claim 1, wherein the electrical reset current between the fuel electrode and the other aforesaid electrode provides approximately a potential difference capable of oxidizing a metal fuel on the fuel electrode, and reducing an oxidant at the other aforesaid electrode. 3. The method of claim 1, further comprising repeating the method a plurality of times. 4. The method of claim 1, further comprising determining if a resetting process is needed for the electrochemical cell, prior to applying the electrical reset current from the power source. 5. The method of claim 4, wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present charge capacity for the electrochemical cell;comparing the present charge capacity to an initial charge capacity; andif the present charge capacity is less than an initial charge capacity by a greater than a threshold amount, determining that a resetting process is needed. 6. The method of claim 4, wherein determining if the resetting process is needed comprises determining if a predetermined amount of elapsed time has occurred since the electrochemical cell was last discharged, or since the electrochemical cell was last reset. 7. The method of claim 6, wherein the predetermined amount of elapsed time contains a randomized time interval. 8. The method of claim 4 wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present voltage between the permeable electrode bodies;comparing the present voltage to an initial voltage; andif the present voltage is less than the initial voltage by greater than a threshold amount, determining that a resetting process is needed. 9. The method of claim 4, wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present resistance between the permeable electrode bodies;comparing the present resistance to an initial resistance; andif the present resistance is less than the initial resistance by greater than a threshold amount, determining that a resetting process is needed. 10. The method of claim 4, wherein determining if the resetting process is needed for the electrochemical cell comprises: determining if the cell is entering a passivation regime where the metal fuel has an increased likelihood of passivating; and,if the cell is entering the passivation regime, applying the electrical reset current, wherein the electrical reset current corresponds to oxidizing the metal fuel in a transpassive regime, where the metal fuel has a decreased likelihood of passivating. 11. The method of claim 10, further comprising, prior to applying the electrical reset current, controlling the present voltage and/or the electrical discharge current to consume a threshold amount of the fuel without entering the passivation regime. 12. The method of claim 1, wherein the electrical reset current is approximately above 0 mA/cm2 through 10 mA/cm2. 13. The method of claim 1, wherein the electrical reset current corresponds to a reset voltage of above −1V through 1V. 14. The method of claim 1, wherein the charging electrode is selected from the group consisting of (a) the oxidant electrode, (b) a third electrode spaced from the oxidant electrode, and (c) a portion of the fuel electrode. 15. The method of claim 14, wherein the charging electrode during recharge is a dynamic charging electrode comprising at least some of the permeable electrode bodies. 16. The method of claim 14, wherein the charging electrode is the oxidant electrode, and the other aforesaid electrode is thus also the oxidant electrode, and wherein the other aforesaid electrode reduces oxygen. 17. The method of claim 14, wherein the charging electrode is the third electrode, and the other aforesaid electrode is the oxidant electrode, and wherein the other aforesaid electrode reduces oxygen. 18. The method of claim 14, wherein the charging electrode is the third electrode, and the other aforesaid electrode is also the third electrode, and wherein the other aforesaid electrode reduces water in the ionically conductive medium. 19. The method of claim 14, wherein the charging electrode is the third electrode, and the other aforesaid electrode is also the third electrode, and wherein the other aforesaid electrode reduces oxygen dissolved within the ionically conductive medium. 20. An electrochemical cell system comprising: an electrochemical cell comprising:a fuel electrode comprising a series of permeable electrode bodies arranged in spaced apart relation for receiving electrodeposited metal fuel;an oxidant electrode spaced apart from the fuel electrode;a charging electrode;an ionically conductive medium communicating the electrodes;circuitry configured to provide electrical connections between the electrodes, a power input circuit, and a power output circuit;a plurality of switches in the circuitry, configured to selectively open or close the electrical connections the between the electrodes, the power input circuit, and the power output circuit;wherein the cell is configured to generate an electrical discharge current by oxidizing the metal fuel on the electrode bodies of the fuel electrode and reducing an oxidizer at the oxidant electrode; andwherein the spaced apart relation of said permeable electrode bodies of the fuel electrode enables an electrical recharge current to be applied between the charging electrode and at least one of the permeable electrode bodies with the charging electrode functioning as an anode and the at least one permeable electrode body functioning as a cathode, such that reducible fuel ions are reduced and electrodeposited from the ionically conductive medium as fuel in oxidizable form on the at least one permeable electrode body, whereby the electrodeposition causes growth of the fuel among the permeable electrode bodies such that the electrodeposited fuel establishes an electrical connection between the permeable electrode bodies; anda controller comprising logic to control an open state or a closed state of each of the plurality of switches of the electrochemical cell, wherein the controller further comprises logic to initiate a resetting process by: selectively operating the plurality of switches to apply an electrical reset current from a power source to the power input circuit and between the fuel electrode and at least one other aforesaid electrode with the fuel electrode functioning as an anode and the other aforesaid electrode functioning as a cathode, such that the metal fuel on the fuel electrode is oxidized into a reducible fuel species; andselectively operating the plurality of switches to remove the electrical reset current to discontinue the resetting process. 21. The electrochemical cell system of claim 20, wherein the controller comprises logic to determine if the resetting process is needed for the electrochemical cell, prior to applying an electrical reset current from the power source. 22. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present charge capacity for the electrochemical cell;comparing the present charge capacity to an initial charge capacity; andif the present charge capacity is less than an initial charge capacity by a greater than a threshold amount, determining that a resetting process is needed. 23. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed comprises determining if a predetermined amount of elapsed time has occurred since the electrochemical cell was last discharged, or since the electrochemical cell was last reset. 24. The electrochemical cell system of claim 23, wherein the predetermined amount of elapsed time contains a randomized time interval. 25. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed comprises determining if a predetermined number of discharge and recharge cycles have occurred since the electrochemical cell was initially charged or last reset. 26. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed comprises determining if a randomized number of discharge and recharge cycles have occurred since the electrochemical cell was initially charged or last reset. 27. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present voltage between the permeable electrode bodies;comparing the present voltage to an initial voltage; andif the present voltage is less than the initial voltage by greater than a threshold amount, determining that a resetting process is needed. 28. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed for the electrochemical cell comprises: sensing a present resistance between the permeable electrode bodies;comparing the present resistance to an initial resistance; andif the present resistance is less than the initial resistance by greater than a threshold amount, determining that a resetting process is needed. 29. The electrochemical cell system of claim 21, wherein determining if the resetting process is needed for the electrochemical cell comprises: determining if the cell is entering a passivation regime where the metal fuel has an increased likelihood of passivating; and,if the cell is entering the passivation regime, applying the electrical reset current, wherein the electrical reset current corresponds to oxidizing the metal fuel in a transpassive regime, where the metal fuel has a decreased likelihood of passivating. 30. The electrochemical cell system of claim 20, wherein the electrical reset current is approximately above 0 mA/cm2 through 10 mA/cm2. 31. The electrochemical cell system of claim 20, wherein the electrical reset current corresponds to a reset voltage of above −1V through 1V. 32. The electrochemical cell system of claim 20, wherein the charging electrode is selected from the group consisting of (a) the oxidant electrode, (b) a third electrode spaced from the oxidant electrode, and (c) a portion of the fuel electrode. 33. The electrochemical cell system of claim 32, wherein the charging electrode during re-charge is a dynamic charging electrode comprising at least some of the permeable electrode bodies. 34. The electrochemical cell system of claim 32, wherein the charging electrode is the oxidant electrode, and the other aforesaid electrode is thus also the oxidant electrode, and wherein the other aforesaid electrode reduces oxygen. 35. The electrochemical cell system of claim 32, wherein the charging electrode is the third electrode, and the other aforesaid electrode is the oxidant electrode, and wherein the other aforesaid electrode reduces oxygen. 36. The electrochemical cell system of claim 32, wherein the charging electrode is the third electrode, and the other aforesaid electrode is also the third electrode, and wherein the other aforesaid electrode reduces water in the ionically conductive medium. 37. The electrochemical cell system of claim 32, wherein the charging electrode is the third electrode, and the other aforesaid electrode is also the third electrode, and wherein the other aforesaid electrode reduces oxygen dissolved within the ionically conductive medium. 38. The electrochemical cell system of claim 20, further comprising a plurality of the electrochemical cells and a second plurality of switches therebetween, wherein the controller further comprises logic to selectively open and/or close the second plurality of switches to apply the electrical reset current from the power source to the power input circuits of one or more of the plurality of the electrochemical cells. 39. The electrochemical cell system of claim 38, wherein the controller further comprises logic to determine if a resetting process is needed for each of the plurality of electrochemical cells, and if the resetting process is needed for at least some of the plurality of electrochemical cells, initiating the resetting process for the at least some of the plurality of electrochemical cells. 40. The system of claim 20, wherein the electrochemical cell further comprises an electrode holder comprising a cavity for holding the fuel electrode, a plurality of inlets connected to the cavity on one side of the cavity and configured to supply the ionically conductive medium to the cavity, and a plurality of outlets connected to the cavity on an opposite side of the cavity and configured to allow the ionically conductive medium to flow out of the cavity. 41. The system of claim 40, wherein the electrochemical cell further comprises a plurality of spacers extending across the fuel electrode and the cavity in a spaced relation from each other to define a plurality of flow lanes in the cavity, wherein one of the plurality of inlets and one of the plurality of outlets are associated with each flow lane so that the ionically conductive medium flows into each flow lane via the associated inlet, across the fuel electrode, and out of the flow lane via the associated outlet. 42. The system of claim 41, further comprising flowing the ionically conductive medium through the inlets and into the flow lanes, prior to applying the electrical reset current from the power source. 43. The system of claim 20, wherein the electrochemical cell further comprises an electrode holder comprising a cavity for holding the fuel electrode, and a passageway through which the ionically conductive medium flows into the cavity, wherein the cavity comprises a plurality of fluidization zones, each fluidization zone being at least partially defined by diverging surfaces where the passageway is connected to the cavity, the fluidization zones being configured to fluidize precipitates in the ionically conductive medium as the ionically conductive medium flows into the cavity. 44. The system of claim 43, further comprising flowing the ionically conductive medium into the fluidization zones prior to applying the electrical reset current from the power source. 45. A system for managing a plurality of electrochemical cells, wherein each of the electrochemical cells comprises: a fuel electrode comprising a series of permeable electrode bodies arranged in spaced apart relation for receiving electrodeposited metal fuel;an oxidant electrode spaced apart from the fuel electrode;a charging electrode; andan ionically conductive medium communicating the electrodes;the system comprising a controller, the controller comprising logic to: determine for each of a plurality of the electrochemical cells whether a maintenance operation is needed for the electrochemical cell, whether to bypass the electrochemical cell, or whether to charge or discharge the electrochemical cell;control charging or discharging each of the plurality of electrochemical cells that are determined to be charged or discharged;electrically isolate each of the plurality of electrochemical cells for which the maintenance operation is determined to be needed from each cell determined to be charged or discharged;connecting each cell for which the maintenance operation is determined to be needed to a maintenance subsystem; andperforming under control of the maintenance subsystem the maintenance operation on each cell for which the maintenance operation is determined to be needed while electrically isolated from each of the charged or discharged cells. 46. The system of claim 45, wherein the controller comprises logic to determine whether the maintenance operation is needed through sensing one or more measurements associated with each of the plurality of electrochemical cells. 47. The system of claim 46, wherein said sensing comprises sensing one or more of a current, a voltage, a fuel growth status, and a charge capacity measurement. 48. The system of claim 45, wherein each of the plurality of electrochemical cells are distributed into a plurality of modules comprising one or more electrochemical cells, wherein said determining is for the plurality of electrochemical cells in each module. 49. The system of claim 45, wherein the controller comprises logic to determine whether the maintenance operation is needed by determining if a predetermined amount of elapsed time has occurred since the electrochemical cell was last discharged, or since the electrochemical cell was last maintained. 50. The system of claim 45, wherein the maintenance operation is a resetting process. 51. The system of claim 50, wherein an electrical reset current is applied from a power source between the fuel electrode and at least one other electrode, with the fuel electrode functioning as an anode and the other electrode functioning as a cathode, such that the metal fuel on the fuel electrode is oxidized into a reducible fuel species. 52. The system of claim 51, wherein the power source comprises an external power source to the electrochemical cell system. 53. The system of claim 51, wherein the power source comprises one or more of the plurality of electrochemical cells. 54. The system of claim 50, wherein said charging or discharging, said electrically isolating each electrochemical cell, or said resetting process comprises controlling an open state or a closed state of each of a plurality of switches associated with the electrochemical cell.
Kitahara Jun,JPX ; Ishii Masato,JPX ; Saitou Kenichi,JPX ; Miyata Junichi,JPX ; Takeoka Hitoshi,JPX, Battery unit having a plurality of rechargeable battery cells and method of charging the same.
Niksa Marilyn J. (Painesville OH) Pohto Gerald R. (Mentor OH) Lakatos Leslie K. (Mentor OH) Wheeler Douglas J. (Cleveland Heights OH) Niksa Andrew J. (Painesville OH) Schue Thomas J. (Huntsburg OH), Battery with modular air cathode and anode cage.
Tsai, Tsepin; Faris, Sadeg M., Electro-chemical power generation systems employing arrays of electronically-controllable discharging and/or recharging cells within a unitary support structure.
Harats Yehuda (Jerusalem ILX) Goldstein Jonathan R. (Jerusalem ILX), Electrochemical metal-air cell and electrically and mechanically rechargeable anodes for use therein.
Goldstein Jonathan (Jerusalem) Naimer Neal (Jerusalem) Khasin Erik (Rishon Le-Zion) Brokman Avner (Jerusalem ILX), Electrodes for metal/air batteries and fuel cells and bipolar metal/air batteries incorporating the same.
Brokman Avner (Jerusalem ILX) Goldstein Jonathan (Jerusalem ILX), Electrodes for metal/air batteries and fuel cells and metal/air batteries incorporating the same.
Brady Joseph M. (Huntingdon PA) Cordes Franz R. (State College PA) Gedrat Klaus H. (Berlin NJ DEX) Goffredo Daniel L. (Riverton NJ) Meyer Walter (Berlin PA DEX) Shakley Conrad D. (Spring Mills PA), Electroplating apparatus and method.
O\Neill Charles E. (Mississauga CAX) Ettel Victor A. (Mississauga CAX) Villazor Alfredo (Fonthill CAX) Garritsen Peter G. (Welland CAX), Electrowinning cell with bagged anode.
Keefer, Bowie G.; Babicki, Matthew L.; Boulet, Andre Jason Joseph; Pelman, Aaron M.; Sellars, Brian G.; Roy, Surajit, Gas separation by combined pressure swing and displacement purge.
Sadeg M. Faris ; Tsepin Tsai, METAL-AIR FUEL CELL BATTERY SYSTEMS HAVING A METAL-FUEL CARD STORAGE CARTRIDGE, INSERTABLE WITHIN A FUEL CARTRIDGE INSERTION PORT, CONTAINING A SUPPLY OF SUBSTANTIALLY PLANAR DISCRETE METAL-FUEL CARD.
Stone Gordon R. (O\Fallon IL) McGee Richard L. (Chesterfield MO) Amick Douglas J. (Ann Arbor MI), Metal-air cell and power system using metal-air cells.
Sadeg M. Faris, Metal-air fuel cell battery system having means for bi-directionally transporting metal-fuel tape and managing metal-fuel available therealong.
Faris, Sadeg M.; Tsai, Tsepin, Metal-air fuel cell battery system having means for recording and reading operating parameters during discharging and recharging modes of operation.
Faris, Sadeg M.; Tsai, Tsepin, Metal-air fuel cell battery systems having mechanism for extending the path length of metal-fuel tape during discharging and recharging modes of operation.
Faris, Sadeg M.; Tsai, Tsepin, Metal-air fuel cell battery systems having mechanism for extending the path length of metal-fuel tape during discharging and recharging modes of operation.
Sadeg M. Faris ; Yuen-Ming Chang ; Tsepin Tsai ; Wayne Yao, Metal-fuel card with a plurality of metal-fuel elements and corresponding contact apertures, and electro-chemical electric power generation devices employing same.
Srinivasan Venkataraman (Attleboro MA) Cassidy Stephen (Canton MA) Grassie Charles (Attleboro MA), Method for selectively electroplating portions of articles.
Smedley, Stuart I.; Novkov, Donald James; Smedley, Kent I.; Alstadt, Raymond H.; Grochulski, Frederick R., Method of and system for flushing one or more cells in a particle-based electrochemical power source in standby mode.
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.
Smedley,Kent I.; Gulino,Ronald; Novkov,Donald James; Alger,Ethan T.; Rosen,Jesse; Smedley,Stuart I., Methods and devices for controlling flow and particle fluidization in a fuel cell.
Kevin M. Gorman ; John A. McElver ; Charles P. Cartwright ; David R. Patterson, Multiplexed PCR assay for detecting disseminated Mycobacterium avium complex infection.
Gutierrez Bernardo A. ; Colborn Jeffrey A. ; Smedley Stuart I. ; Smedley Kent I., Particle feeding apparatus for electrochemical power source and method of making same.
Ovshinsky,Stanford R.; Aladjov,Boyko; Venkatesan,Srinivasan; Tekkanat,Bora; Vijan,Meera; Wang,Hong; Dhar,Subhash K., Performance enhancing additive material for the nickel hydroxide positive electrode in rechargeable alkaline cells.
Benczur-Urmossy Gabor (Stuttgart DT) VON Benda Klaus (Kemnat DT) Haschka Friedrich (Stuttgart DT), Rechargeable galvanic cell with zinc electrode and auxiliary structure.
Pinto, Martin; Smedley, Stuart; Colborn, Jeffrey A., Refuelable electrochemical power source capable of being maintained in a substantially constant full condition and method of using the same.
Morrison Bernard H. (Mississauga CAX) Lenz John G. (Pierrefonds CAX) Pageau Jacques (Montreal CAX) Bard J. Gerald (Brossard CAX), Treatment of anode slimes in a top blown rotary converter.
Krishnan, Ramkumar; Hayes, Joel; Friesen, Grant; Fink, Shawn, Water management system in electrochemical cells with vapor return comprising air electrodes.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.