Fuel cell system including separator having cooling water flow channels
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H01M-008/00
H01M-008/02
H01M-008/04
H01M-008/06
H01M-008/10
출원번호
UP-0044220
(2005-01-28)
등록번호
US-7537851
(2009-07-01)
우선권정보
KR-10-2004-0006000(2004-01-30)
발명자
/ 주소
Lee, Dong Hun
Kweon, Ho Jin
Kim, Ju Yong
출원인 / 주소
Samsung SDI Co., Ltd.
대리인 / 주소
H.C. Park & Associates, PLC
인용정보
피인용 횟수 :
6인용 특허 :
5
초록▼
The present invention is a fuel cell system including a stack having an electricity generator, that includes separators disposed on both surfaces of a membrane-electrode assembly, a reformer that converts fuel to generate hydrogen gas and supplies the hydrogen gas to the stack, a fuel supply unit th
The present invention is a fuel cell system including a stack having an electricity generator, that includes separators disposed on both surfaces of a membrane-electrode assembly, a reformer that converts fuel to generate hydrogen gas and supplies the hydrogen gas to the stack, a fuel supply unit that supplies the fuel to the reformer, an air supply unit that supplies air to the stack, a cooling water supply unit that supplies cooling water to the stack, and a flow channel section that is formed in the separator and through that the cooling water supplied from the cooling water supply unit passes.
대표청구항▼
What is claimed is: 1. A fuel cell system, comprising: a stack that has an electricity generator, the electricity generator comprising a membrane electrode assembly, a separator disposed on a first surface of the membrane electrode assembly, and a separator disposed on a second surface of the membr
What is claimed is: 1. A fuel cell system, comprising: a stack that has an electricity generator, the electricity generator comprising a membrane electrode assembly, a separator disposed on a first surface of the membrane electrode assembly, and a separator disposed on a second surface of the membrane electrode assembly; a reformer to convert fuel to generate hydrogen gas; a fuel supply unit to supply the fuel to the reformer; an air supply unit to supply air to the stack; and a cooling water supply unit to supply cooling water to the stack, wherein each separator comprises a flow channel section through which the cooling water supplied from the cooling water supply unit passes, and wherein the flow channel section comprises: a first flow channel comprising a first via hole into which the cooling water flows, a second via hole from which the cooling water flows out, and a first groove that connects the first via hole and the second via hole to each other, the first flow channel being formed on the separator along a first edge thereof; and a second flow channel comprising a third via hole into which the cooling water flows, a fourth via hole from which the cooling water flows out, and a second groove that connects the third via hole and the fourth via hole to each other, the second flow channel being formed on the separator along a second edge thereof, the second edge being adjacent to the first edge. 2. The fuel cell system of claim 1, wherein the fuel supply unit comprises: a fuel tank connected to the reformer and stores liquid-state fuel containing hydrogen; and a fuel pump connected to the fuel tank. 3. The fuel cell system of claim 1, wherein the air supply unit comprises: an air pump connected to the stack. 4. The fuel cell system of claim 1, wherein the cooling water supply unit comprises: a cooling water tank connected to the flow channel section and storing the cooling water; and a cooling water pump connected to the cooling water tank. 5. The fuel cell system of claim 1, wherein a first channel to allow the air to flow into the membrane-electrode assembly is formed on a first surface of the separator, and a second channel to allow the hydrogen gas to flow into the membrane-electrode assembly is formed on a second surface of the separator. 6. The fuel cell system of claim 5, wherein the separator comprises: a first inlet to supply the air to the first channel; a first outlet to discharge unreacted air while passing through the first channel; a second inlet to supply the hydrogen gas to the second channel; and a second outlet to discharge unreacted hydrogen gas while passing through the second channel. 7. The fuel cell system of claim 5, wherein: the first edge of the separator corresponds to an area where the hydrogen gas and the air are supplied to the first channel and the second channel; and the second edge of the separator corresponds to an area where the hydrogen gas and the air flow along the first channel and the second channel. 8. The fuel cell system of claim 7, wherein the flow channel section further comprises: a third flow channel formed on the separator along a third edge thereof, the third edge being opposite the first edge and corresponding to an area where the hydrogen gas and the air flow out from the first channel and the second channel. 9. The fuel cell system of claim 8, wherein the third flow channel comprises: a fifth via hole into which the cooling water passing through the first and second flow channels flow; a sixth via hole from which the cooling water flows out; and a third groove connecting the fifth via hole and the sixth via hole to each other. 10. The fuel cell system of claim 1, wherein the stack comprises: a polymer electrolyte membrane. 11. A fuel cell system, comprising: a stack that has an electricity generator, the electricity generator comprising a membrane electrode assembly, a separator disposed on a first surface of the membrane electrode assembly, and a separator disposed on a second surface of the membrane electrode assembly; a reformer to convert fuel to generate hydrogen gas; a fuel supply unit to supply the fuel to the reformer; an air supply unit to supply air to the stack; a cooling water supply unit to supply cooling water to the stack; and a first heat exchanger that is connected to the air supply unit and the stack and is also connected to the cooling water supply unit and the flow channel section, wherein each separator comprises a flow channel section through which the cooling water supplied from the cooling water supply unit passes, and wherein the flow channel section comprises: a first flow channel comprising a first via hole into which the cooling water flows, a second via hole from which the cooling water flows out, and a first groove that connects the first via hole and the second via hole to each other, the first flow channel being formed on the separator along a first edge thereof; and a second flow channel comprising a third via hole into which the cooling water flows, a fourth via hole from which the cooling water flows out, and a second groove that connects the third via hole and the fourth via hole to each other, the second flow channel being formed on the separator along a second edge thereof, the second edge being adjacent to the first edge. 12. The fuel cell system of claim 11, wherein a first channel allowing the air to flow into the membrane-electrode assembly is formed on a first surface of the separator, and wherein a second channel allowing the hydrogen gas to flow into the membrane-electrode assembly is formed on a second other surface of the separator. 13. The fuel cell system of claim 12, wherein the first edge of the separator corresponds to an area where the hydrogen gas and the air are supplied to the first channel and the second channel, and wherein the second edge of the separator corresponds to an area where the hydrogen gas and the air flow along the first channel and the second channel. 14. The fuel cell system of claim 13, wherein the first heat exchanger comprises: a first supply tube connected to the air supply unit and the separator, the first supply tube to supply the air to the separator; and at least one second supply tube connected to the cooling water supply unit and the first and second flow channels, the at least one second supply tube contacting the first supply tube. 15. The fuel cell system of claim 11, wherein the stack comprises: a polymer electrolyte membrane. 16. A fuel cell system, comprising: a stack that has an electricity generator, the electricity generator comprising a membrane electrode assembly, a separator disposed on a first surface of the membrane electrode assembly, and a separator disposed on a second surface of the membrane electrode assembly; a reformer to convert fuel to generate hydrogen gas; a fuel supply unit to supply the fuel to the reformer; an air supply unit to supply air to the stack; a cooling water supply unit to supply cooling water to the stack; a first heat exchanger connected to the air supply unit and the stack and connected to the cooling water supply unit and the flow channel section; and a second heat exchanger connected to the reformer and the stack and connected to the flow channel section, wherein each separator comprises a flow channel section through which the cooling water supplied from the cooling water supply unit passes, and wherein the flow channel section comprises: a first flow channel comprising a first via hole into which the cooling water flows, a second via hole from which the cooling water flows out, and a first groove that connects the first via hole and the second via hole to each other, the first flow channel being formed on the separator along a first edge thereof; and a second flow channel comprising a third via hole into which the cooling water flows, a fourth via hole from which the cooling water flows out, and a second groove that connects the third via hole and the fourth via hole to each other, the second flow channel being formed on the separator along a second edge thereof, the second edge being adjacent to the first edge. 17. The fuel cell system of claim 16, wherein a first channel allowing the air to flow into the membrane-electrode assembly is formed on a first surface of the separator, and wherein a second channel allowing the hydrogen gas to flow into the membrane-electrode assembly is formed on a second surface of the separator. 18. The fuel cell system of claim 17, wherein the first edge of the separator corresponds to an area where the hydrogen gas and the air are supplied to the first channel and the second channel, wherein the second edge of the separator corresponds to an area where the hydrogen gas and the air flow along the first channel and the second channel, and wherein a third flow channel is formed on the separator along a third edge thereof, the third edge being opposite the first edge and corresponding to an area where the hydrogen gas and the air flow out from the first channel and the second channel. 19. The fuel cell system of claim 18, wherein the second heat exchanger comprises: a third supply tube connected to the reformer and the separator, the third supply tube to supply the hydrogen gas to the separator, wherein at least one fourth supply tube is connected to the first, second, and the third flow channels and contacts the third supply tube. 20. The fuel cell system of claim 18, further comprising: a third heat exchanger connected to the fuel supply unit and the reformer, and connected to the flow channel section. 21. The fuel cell system of claim 20, wherein the third heat exchanger comprises: a fifth supply tube connected to the fuel supply unit and the reformer, the fifth supply tube to supply the fuel to the reformer; and at least one sixth supply tube connected to the third flow channel and contacting the fifth supply tube. 22. The fuel cell system of claim 16, wherein the stack-comprises: a polymer electrolyte membrane. 23. A stack, comprising: an electricity generator that includes a membrane-electrode assembly, a separator disposed on a first surface of the membrane-electrode assembly, and a separator disposed on a second surface of the membrane-electrode assembly, wherein each separator comprises: a first channel to supply air to the membrane-electrode assembly formed on one surface of the separator, a second channel to supply hydrogen gas to the membrane-electrode assembly formed on the other surface of the separator, and a flow channel section through which cooling water passes formed in the separator, wherein the flow channel section comprises: a first flow channel comprising a first via hole into which the cooling water flows, a second via hole from which the cooling water flows out, and a first groove that connects the first via hole and the second via hole to each other, the first flow channel being formed on the separator along a first edge thereof; and a second flow channel comprising a third via hole into which the cooling water flows, a fourth via hole from which the cooling water flows out, and a second groove that connects the third via hole and the fourth via hole to each other, the second flow channel being formed on the separator along a second edge thereof, the second edge being adjacent to the first edge. 24. The stack of claim 23, wherein: the first edge of the separator corresponds to an area where the hydrogen gas and the air are supplied to the first channel and the second channel; and the second edge of the separator corresponds to an area where the hydrogen gas and the air flow along the first channel and the second channel. 25. The stack of claim 24, wherein the flow channel section further comprises: a third flow channel formed on the separator along a third edge thereof, the third edge being opposite the first edge and corresponding to an area where the hydrogen gas and the air are discharged from the first and second channels.
Ernst William D. ; Mittleman Gary, PEM-type fuel cell assembly having multiple parallel fuel cell sub-stacks employing shared fluid plate assemblies and s.
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