A rechargeable galvanic cell that has a negative electrode material made of a molten alkali metal (such as sodium or lithium). The galvanic cell also includes a positive electrode active material that may be sulfur or iodine. The positive electrode active material may be used in conjunction with a p
A rechargeable galvanic cell that has a negative electrode material made of a molten alkali metal (such as sodium or lithium). The galvanic cell also includes a positive electrode active material that may be sulfur or iodine. The positive electrode active material may be used in conjunction with a polar solvent. An ion-conductive separator is disposed between the polar solvent and the negative electrode material. The positive electrode active material has a specific gravity that is greater than the specific gravity of the polar solvent. Thus, the positive electrode active material is proximate the bottom of the positive electrode compartment while the polar solvent is above the positive electrode active material. The cell is designed to be operated at temperatures above the melting point of the alkali metal, but at temperatures that are lower than about 250° C.
대표청구항▼
1. A cell comprising: a negative electrode compartment housing a negative electrode material, wherein the negative electrode material comprises at least one of a liquid sodium metal and a liquid lithium metal that is oxidized during discharge of the cell;a positive electrode compartment;a polar solv
1. A cell comprising: a negative electrode compartment housing a negative electrode material, wherein the negative electrode material comprises at least one of a liquid sodium metal and a liquid lithium metal that is oxidized during discharge of the cell;a positive electrode compartment;a polar solvent within the positive electrode compartment;a liquid positive electrode active material within the positive electrode compartment that is reduced during discharge of the cell, wherein the liquid positive electrode active material has a specific gravity greater than the polar solvent such that an interface exists between the liquid positive electrode active material and the polar solvent, wherein the liquid positive electrode active material comprises at least one of elemental sulfur and iodine;an ion-conductive membrane comprising at least one of NaSICON and LiSICON separator separating the negative electrode compartment from the positive electrode compartment; anda positive electrode current collector configured to provide electrical contact to the interface between the liquid positive electrode active material and the polar solvent, wherein the interface between the liquid positive electrode active material and the polar solvent moves with respect to the positive electrode current collector as the cell charges or discharges;wherein the cell is a galvanic cell. 2. The cell as in claim 1 wherein the negative electrode material comprises lithium and the liquid positive electrode active material comprises elemental sulfur and the temperature of the galvanic cell is maintained between about 185° C. and about 250° C. 3. The cell as in claim 1 wherein the negative electrode material comprises sodium and the temperature of the cell is maintained between about 100° C. and about 200° C. 4. The cell as in claim 3, wherein the temperature of the galvanic cell is maintained between about 100° C. and about 185° C. 5. The cell as in claim 3, wherein the temperature of the galvanic cell is maintained between about 110° C. and about 170° C. 6. The cell as in claim 1 wherein the polar solvent comprises at least one of acetamide, methylacetamide, and dimethylacetamide, N-methyl formamide (NMF), formamide, dimethylformamide, tetraglyme, diglyme, dimethylether, Ethanolammonium nitrate, imidazolium halogenoaluminate salts and combinations thereof. 7. The cell as in claim 1 wherein the galvanic cell is configured to allow the polar solvent to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges. 8. The cell as in claim 7 wherein the galvanic cell is configured to allow an inert gas in a headspace within the negative electrode compartment to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges. 9. The cell as in claim 1 wherein the galvanic cell is configured to allow liquids within the positive electrode compartment to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges. 10. The cell as in claim 1 wherein the ion-conductive membrane is planar or tubular. 11. The cell as in claim 1, wherein the positive electrode current collector comprises one or more fins extending upward from a base of the positive electrode compartment. 12. The cell as in claim 11, wherein the height of the fins is designed such that, even when the cell is fully charged or discharged, the height of the interface does not exceed the height of the fins. 13. The cell as in claim 12, wherein the fins comprise one or more holes. 14. A battery comprising one or more galvanic cells, wherein each cell comprises: a negative electrode compartment comprising a negative electrode material, wherein the negative electrode comprises at least one of liquid sodium metal and liquid lithium metal that is oxidized during discharge of the galvanic cell;a positive electrode compartment;a polar solvent within the positive electrode compartment;a liquid positive electrode active material within the positive electrode compartment that is reduced during discharge of the galvanic cell, wherein the liquid positive electrode active material comprises elemental sulfur or iodine, wherein the liquid positive electrode active material has a specific gravity greater than the polar solvent such that an interface exists between the liquid positive electrode active material and the polar solvent;an ion-conductive membrane comprising at least one of NaSICON and LiSICON separating the negative electrode from the polar solvent; anda positive electrode current collector configured to provide electrical contact to the interface between the liquid positive electrode active material and the polar solvent, wherein the interface between the liquid positive electrode active material and the polar solvent moves with respect to the positive electrode current collector as the galvanic cell charges or discharges; andwherein the galvanic cell is configured to allow liquid polar solvent within the positive electrode compartment to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges. 15. The battery as is claim 14, wherein the polar solvent comprises: at least one of acetamide, methylacetamide, and dimethylacetamide, N-methyl formamide (NMF), formamide, dimethylformamide, tetraglyme, diglyme, dimethylether, Ethanolammonium nitrate, imidazolium halogenoaluminate salts and combinations thereof;wherein the ion-conductive membrane is either tubular or planar. 16. The battery as in claim 15 wherein negative electrode material comprises sodium and the temperature of the galvanic cell is maintained between about 100° C. and about 200° C. 17. A cell comprising: a negative electrode compartment housing a negative electrode material, wherein the negative electrode material comprises at least one of a liquid sodium metal and a liquid lithium metal that is oxidized during discharge of the cell;a positive electrode compartment;a polar solvent within the positive electrode compartment;a liquid positive electrode active material within the positive electrode compartment that is reduced during discharge of the cell, wherein the liquid positive electrode active material has a specific gravity greater than the polar solvent such that an interface exists between the liquid positive electrode active material and the polar solvent, wherein the liquid positive electrode active material comprises at least one of elemental sulfur and iodine;an ion-conductive membrane comprising at least one of NaSICON and LiSICON separating the negative electrode compartment from the positive electrode compartment;a positive electrode current collector configured to provide electrical contact to the interface between the liquid positive electrode active material and the polar solvent, wherein the interface between the liquid positive electrode active material and the polar solvent moves with respect to the positive electrode current collector as the cell charges or discharges;wherein: the cell is a galvanic cell configured to allow the liquid polar solvent to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges; andthe galvanic cell comprises an inert gas in a headspace within the negative electrode compartment, and wherein the galvanic cell is configured to allow the inert gas to leave the galvanic cell and re-enter the galvanic cell as the galvanic cell charges or discharges. 18. The cell as in claim 1, wherein elemental sulfur has the formula S8. 19. The cell as in claim 1, wherein elemental sulfur has the formula Sy, wherein 1≤y≤30.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (88)
Visco,Steven J.; Nimon,Yevgeniy S.; Katz,Bruce D.; De Jonghe,Lutgard C., Active metal fuel cells.
Hagedorn Norman H. (Bay Village OH), Alkali metal carbon dioxide electrochemical system for energy storage and/or conversion of carbon dioxide to oxygen.
Brons Glen B. (Phillipsburg NJ) Myers Ronald (Calgary CAX) Bearden ; Jr. Roby (Baton Rouge LA), Continuous in-situ combination process for upgrading heavy oil.
Hwang, Duck Chul; Choi, Yun Suk; Choi, Soo Seok; Lee, Jea Woan; Jung, Yong Ju; Kim, Joo Soak, Electrolyte for a lithium-sulfur battery and a lithium-sulfur battery using the same.
Gordon,John H.; Toshinori,Hachiya; Balagopal,Shekar H.; Bhavaraju,Sai V., Gas diffusion electrode and catalyst for electrochemical oxygen reduction and method of dispersing the catalyst.
Venkatesan Srinivasan ; Reichman Benjamin ; Ovshinsky Stanford R. ; Prasad Binay ; Corrigan Dennis A., High power nickel-metal hydride batteries and high power electrodes for use therein.
Anani Anaba A. (Lawrenceville GA) Reichert Veronica R. (Bethlehem GA) Massaroni Kenneth M. (Berkeley Lake GA), Metal hydride electrochemical cell having a polymer electrolyte.
Joshi Ashok V. (Salt Lake City UT) Liu Meilin (Salt Lake City UT) Bjorseth Alf (Oslo NOX) Renberg Lars (Stockholm SEX), NaOH production from ceramic electrolytic cell.
Cristian Fierro ; Michael A. Fetcenko ; Stanford R. Ovshinsky ; Dennis A. Corrigan ; Beth Sommers ; Avram Zallen, Nickel hydroxide electrode material and method for making the same.
Brons Glen ; Myers Ronald Damian,CAX ; Bearden ; Jr. Roby ; MacLeod John Brenton,CAX, Process for desulfurization of petroleum feeds utilizing sodium metal.
Visco,Steven J.; Katz,Bruce D.; Nimon,Yevgeniy S.; De Jonghe,Lutgard C., Protected active metal electrode and battery cell structures with non-aqueous interlayer architecture.
Visco Steven J. (Berkeley CA) Takemoto Jiro K. (Berkeley CA) Chu May-Ying (Oakland CA), Secondary cell using organosulfur/metal charge transfer materials as positive electrode.
Balagopal Shekar H. (Salt Lake City UT) Gordon John H. (Salt Lake City UT) Virkar Anil V. (Salt Lake City UT) Joshi Ashok V. (Salt Lake City UT), Selective metal cation-conducting ceramics.
Tokoi Hiromi (Tohkai JPX) Souma Hisashi (Hitachi JPX) Watahiki Naohisa (Mito JPX), Sodium-sulphur cell, method of operating same and method of load levelling using the same.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.