A method for assembling an electrochemical cell stack may include arranging a plurality of electrochemical cells into an electrochemical cell stack, the electrochemical cell stack including at least a first substack and a second substack; connecting the first substack and second substack such that r
A method for assembling an electrochemical cell stack may include arranging a plurality of electrochemical cells into an electrochemical cell stack, the electrochemical cell stack including at least a first substack and a second substack; connecting the first substack and second substack such that reactant fluid flows in series from the first substack to the second substack; and coupling the first substack to a first electrical control device such that the first electrical control device selectively electrically reconfigures the first substack to operate in series and in parallel with the second substack.
대표청구항▼
1. A method for assembling an electrochemical cell stack, the method comprising: electrically connecting a plurality of electrochemical cells into a plurality of electrochemical cell stacks, including at least a first electrochemical cell stack having at least a first substack and a second substack
1. A method for assembling an electrochemical cell stack, the method comprising: electrically connecting a plurality of electrochemical cells into a plurality of electrochemical cell stacks, including at least a first electrochemical cell stack having at least a first substack and a second substack of electrochemical cells, and a second electrochemical cell stack having a first substack and a second substack of electrochemical cells; andelectrically coupling the plurality of electrochemical cell stacks together such that the first substack of the first electrochemical cell stack and the first substack of the second electrochemical cell stack form a first row of substacks across the first and the second electrochemical cell stacks;including electrically coupling at least the first substack of the first electrochemical cell stack to the first substack of the second electrochemical cell substack and to a first electrical control device such that the first electrical control device selectively electrically configures the first substack of the first electrochemical cell stack to operate electrically in series and in parallel with the first substack of the second electrochemical cell stack. 2. The method of claim 1, further comprising dividing a stream of reactant fluid into multiple incoming streams to the plurality of stacks to flow in series through substacks of each of the plurality of electrochemical cell stacks. 3. A method for assembling an electrochemical cell stack, the method comprising: arranging a plurality of electrochemical cells into a plurality of electrochemical cell stacks, including a first electrochemical cell stack having at least a first substack and a second substack of electrochemical cells, and a second electrochemical cell stack having at least a first substack and a second substack of electrochemical cells;electrically coupling the plurality of electrochemical cell stacks together, including electrically coupling the first substack of the first electrochemical cell stack to the first substack of the second electrochemical cell stack to form a first row of substacks across at least the first and the second electrochemical cell stacks, and eletrically coupling the second substack of the first electrochemical cell stack to the second substack of the second electrochemical cell stack to form a second row of subtracks across at least the first and the second electrochemical cell stacks;coupling the first substack of the first electrochemical cell stack and the first substack of the second electrochemical cell stack to a first electrical control device such that the first electrical control device selectively electrically configures the first substack of the first electrochemical cell stack and the first substack of the second electrochemical cell stack to operate in series and in parallel; andcoupling the second substack of the first electrochemical cell stack and the second substack of the second electrochemical cell stack to a second electrical control device to selectively electrically configure the second substack of the first electrochemical cell stack and the second substack of the second electrochemical cell stack to operate in series and in parallel, wherein the first electrical control device is controllable independently of the second electrical control device to selectively electrically configure the first and the second rows of substacks. 4. The method of claim 3, wherein coupling the first substack to a first electrical control device, and coupling the second substack to the second electrical control device includes coupling the first electrical control device to selectively couple and decouple the first substack to a load or a power source, and coupling the second electrical control device to selectively couple and decouple the second substack to the load or the power source. 5. The method of claim 3, wherein coupling the first substack to a first electrical control device, and coupling the second substack to the second electrical control device includes coupling the first and second electrical control devices to selectively electrically couple the first and the second substacks in series. 6. The system of claim 3, wherein coupling the first substack to a first electrical control device, and coupling the second substack to the second electrical control device includes coupling the first and second electrical control devices to selectively electrically couple the first and second substacks in parallel. 7. The method of claim 1, wherein providing a plurality of electrochemical cells includes providing a plurality of electrochemical cells selected from fuel cells and electrolyzer cells. 8. The method of claim 1, further comprising connecting the first substack and second substack such that reactant fluid flows in series from the first substack to the second substack of at least the first stack electrochemical cells. 9. A method for assembling an electrochemical cell stack, the method comprising: arranging a plurality of electrochemical cells into a plurality of electrochemical cell stacks, at least one of the plurality of the electrochemical cell stacks having at least a first substack and a second substack of electrochemical cells;electrically coupling the plurality of electrochemical cell stacks together;coupling at least the first substack to a first electrical control device such that the first electrical control device selectively electrically reconfigures the first substack to operate in series and in parallel with the second substack of the at least one of the plurality of electrochemical cell stacks; andselectively operating the electrochemical cells of the plurality of electrochemical cells in both a fuel cell mode and an electrolyzer mode. 10. A method for assembling an electrochemical cell stack, the method comprising: arranging a plurality of electrochemical cells into a plurality of electrochemical cell stacks, including a first electrochemical cell stack having at least a first substack and a second substack of electrochemical cells, and a second electrochemical cell stack having at least a first substack and a second substack of electrochemical cells;electrically coupling the plurality of electrochemical cell stacks together;electrically coupling at least the first substack of the first electrochemical cell stack and the first substack of the second electrochemical cell stack to a first electrical control device to form a first row of substacks across the first and the second electrochemical cell stacks such that the first electrical control device selectively electrically configures the first substack of the first electrochemical cell stack to operate in series and in parallel with the first substack of the second electrochemical cell stack; andwherein arranging the plurality of electrochemical cells includes arranging a plurality of electrochemical cells selected from polymer exchange membrane cells and solid oxide fuel cells. 11. A method for assembling an electrochemical cell stack, the method comprising: arranging a plurality of electrochemical cells into a plurality of electrochemical cell stacks, including a first electrochemical cell stack hacing at least a first substack and a second substack of electrochemical cells, and a second electrochemical cell stack having at least a first substack and a second substack of electrochemical cells;electrically coupling the plurality of electrochemical cell stacks together;coupling at least the first substack to a first electrical control device such that the first electrical control device selectively electrically reconfigures the first substack to operate in series and in parallel with the second substack of the at least one of the plurality of electrochemical cell stacks; andcontrolling fluid flow in series between the substacks of the first and the second electrochemical cell stacks at a single flow control point. 12. The method of claim 11, further comprising electrically coupling the first substack of the first electrochemical cell stack with the first substack of the second electrochemical cell stack; and electrically coupling the second substack of the first electrochemical cell stack with the second substack of the second electrochemical cell stack. 13. The method of claim 12, further comprising coupling the second substack of the first electrochemical cell stack to a second electrical control device to selectively electrically reconfigure the second substack to operate in series and in parallel with substacks of other electrochemical cell stacks of the plurality of substacks; and wherein coupling the first substack and coupling the second substack includes coupling the first and second electrical control devices to selectively electrically configure the first and the second substacks of the electrochemical cell stack and the second electrochemical cell stack in a selected one of a series configuration, a parallel configuration, and a disconnected configuration. 14. A method of operating an electrochemical cell system, the method comprising: electrically coupling in series a first substack of a first electrochemical cell stack with a first substack of a second electrochemical cell stack to form a first row of substacks across the first and the second electrochemical cell stacks;electrically coupling an electrical control device to the first row of substacks; andselectively and independently electrically reconfiguring the first row of substacks with the electrical control device to alternately couple and decouple the first row from a load. 15. The method of claim 14, further comprising causing reactant fluid to flow in series from substack to substack in each of the plurality of substacks, wherein the fluid is selected from fuel cell reactant and electrolyzer reactant. 16. A method for regulating voltage and power output of an electrochemical cell system to a load, the method comprising: arranging a plurality of electrochemical cells of the electrochemical cell system into a first electrochemical cell stack and a second electrochemical cell stack, the first and the second electrochemical cell stacks each including at least a first substack and a second substack;electrically coupling the first substack of the first electrochemical cell stack to the first substack of the second electrochemical cell stack to form a first row of substacks across the first and the second electrochemical cell stacks;electrically coupling the first row of substacks to a first electrical switch that selectively electrically couples and decouples the first row of substacks to the load; andactuating the first electrical switch to regulate the voltage and the power output of the electrochemical cell system by one of electrically coupling first row of substacks to or decoupling the first row of substacks from the load. 17. The method of claim 16, further comprising connecting the first substack and the second substack such that reactant fluid flows in series through the first electrochemical cell stack and in series through the second electrochemical cell stack. 18. The method of claim 17, further comprising operating the electrochemical cell system in electrolysis mode by initially switching on only certain rows of substacks; and then turning on multiple rows of substacks as input power increases, thereby allowing the electrochemical cell system to support a wide swing in input power while still operating efficiently. 19. The method of claim 16, further comprising: electrically coupling the second substack of the first electrochemical cell stack to the second substack of the second electrochemical cell stack to form a second row of substacks across the first and the second electrochemical cell stacks;electrically coupling the second row of substacks to a second electrical switch that selectively electrically reconfigures the second substack to operate in series and in parallel with the first substack; andactuating the first and the second electrical switches to regulate the voltage and the power output of the electrochemical cell system by modifying the electrical configuration of the first row of substacks and second row of substacks to the load between a parallel configuration and a series configuration. 20. The method of claim 3, wherein coupling the first substack to the first electrical control device, and coupling the second substack to the second electrical control device includes coupling the first substack and the second substack of the first and the second stacks of electrochemical cells, wherein at least one of the first substack and the second substack is selectively reconfigurable independently of the other remaining substacks of the plurality of substacks by the first electrical control device and the second electrical control device, respectively.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (1)
Cohen Ronald (West Hartford CT) Hall Eugene W. (Gastonbury CT), Plaque fuel cell stack.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.