IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0999387
(2001-10-31)
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발명자
/ 주소 |
- Muthuswamy, Sivakumar
- Pratt, Steven D.
- Kelley, Ronald J.
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출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
6 |
초록
▼
A fuel cell ( 200 ) includes a membrane electrode assembly ( 210 ) located together with a layer of porous, z-axis electrically conductive, non-linear positive temperature coefficient (NPTC) material ( 250 ). The NPTC material ( 250 ) operates to selectively limit the amount of electrons collected f
A fuel cell ( 200 ) includes a membrane electrode assembly ( 210 ) located together with a layer of porous, z-axis electrically conductive, non-linear positive temperature coefficient (NPTC) material ( 250 ). The NPTC material ( 250 ) operates to selectively limit the amount of electrons collected from localized areas of the membrane electrode assembly ( 210 ) in order to reduce hot spots.
대표청구항
▼
1. A fuel cell, comprising:a membrane electrode assembly; anda layer of Z-axis electrically conductive, positive temperature coefficient material located together with the membrane electrode assembly;wherein Z-axis electrical resistivity of the positive temperature coefficient material at localized
1. A fuel cell, comprising:a membrane electrode assembly; anda layer of Z-axis electrically conductive, positive temperature coefficient material located together with the membrane electrode assembly;wherein Z-axis electrical resistivity of the positive temperature coefficient material at localized areas on the positive temperature coefficient material layer changes from a first value to a second value in response to a trigger condition at corresponding areas on the membrane electrode assembly adjacent to the positive temperature coefficient material layer. 2. The fuel cell as described in claim 1, further comprising a current collector, wherein the positive temperature coefficient material layer is interposed between the current collector and the membrane electrode assembly. 3. The fuel cell as described in claim 1, further comprising a gas diffusion layer and a current collector, wherein the positive temperature coefficient material layer is interposed between the gas diffusion layer and the membrane electrode assembly and the gas diffusion layer is interposed between the positive temperature coefficient material layer and the current collector. 4. The fuel cell as described in claim 1, further comprising a Z-axis electrically conductive gas diffusion layer and a current collector, wherein the Z-axis electrically conductive gas diffusion layer is interposed between the positive temperature coefficient material layer and the membrane electrode assembly and the positive temperature coefficient material layer is interposed between the Z-axis electrically conductive gas diffusion layer and the current collector. 5. The fuel cell as described in claim 1, wherein the positive temperature coefficient material is selected from the group consisting of polymer positive temperature coefficient materials, ceramic positive temperature coefficient materials and semiconducting positive temperature coefficient materials. 6. The fuel cell as described in claim 1, wherein the trigger condition is created in response to a combination of one or more elements selected from the group consisting of temperature, pH, hydrogen concentration, electrolyte water content, electrolyte thickness, electrolyte ionic conductivity and electrolyte electronic conductivity of the membrane electrode assembly adjacent to the positive temperature coefficient material layer, crossing a threshold value. 7. A fuel cell, comprising:a membrane electrode assembly; anda layer of porous, Z-axis electrically conductive, non-linear positive temperature coefficient material located together with the membrane electrode assembly;wherein Z-axis electrical resistivity of the non-linear positive temperature coefficient material at localized areas on the non-linear positive temperature coefficient material layer changes from a low value to a high value in response to a rise in temperature at corresponding areas on the membrane electrode assembly adjacent to the non-linear positive temperature coefficient material layer, over a threshold value. 8. The fuel cell of claim 7, further comprising a current collector, wherein the non-linear positive temperature coefficient material layer is interposed between the current collector and the membrane electrode assembly. 9. The fuel cell of claim 7, further comprising a gas diffusion layer and a current collector, wherein the non-linear positive temperature coefficient material layer is interposed between the gas diffusion layer and the membrane electrode assembly and the gas diffusion layer is interposed between the non-linear positive temperature coefficient material layer and the current collector. 10. The fuel cell of claim 7, further comprising a Z-axis electrically conductive gas diffusion layer and a current collector, wherein the Z-axis electrically conductive gas diffusion layer is interposed between the non-linear positive temperature coefficient material layer and the membrane electrode assembly and the non-linear positive temperat ure coefficient material layer is interposed between the Z-axis electrically conductive gas diffusion layer and the current collector. 11. The fuel cell of claim 7, wherein the non-linear positive temperature coefficient material is selected from the group consisting of polymer positive temperature coefficient materials, ceramic positive temperature coefficient materials and semiconducting positive temperature coefficient materials. 12. A fuel cell, comprising:a membrane electrode assembly, comprising a solid electrolyte disposed between and in intimate contact with an anode forming first major side of the membrane electrode assembly and a cathode forming second major side of the membrane electrode assembly; anda layer of porous, Z-axis electrically conductive non-linear positive temperature coefficient material disposed on and in intimate contact with at least one of the major sides of the membrane electrode assembly;wherein the Z-axis electrical resistivity of the non-linear positive temperature coefficient material at localized areas on the non-linear positive temperature coefficient material layer changes from a low value to a high value in response to a rise in temperature at corresponding areas on the membrane electrode assembly side in contact with the non-linear positive temperature coefficient material layer, above a threshold value;wherein the Z-axis electrical resistivity change of the non-linear positive temperature coefficient material at localized areas on the non-linear positive temperature coefficient material layer is reversed by a decrease in temperature at corresponding areas on the membrane electrode assembly side in contact with the non-linear positive temperature coefficient material layer, below a threshold value. 13. The fuel cell as described in claim 12, further comprising a current collector, wherein the non-linear positive temperature coefficient material layer is interposed between the current collector and the membrane electrode assembly. 14. The fuel cell as described in claim 12, further comprising a gas diffusion layer and a current collector, wherein the non-linear positive temperature coefficient material layer is interposed between the gas diffusion layer and the membrane electrode assembly and the gas diffusion layer is interposed between the non-linear positive temperature coefficient material layer and the current collector. 15. The fuel cell as described in claim 12, wherein the non-linear positive temperature coefficient material is selected from the group consisting of polymer positive temperature coefficient materials, ceramic positive temperature coefficient materials and semiconducting positive temperature coefficient materials.
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