IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0954601
(2001-09-17)
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발명자
/ 주소 |
- Debe, Mark Kevitt
- Herdtle, Thomas
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출원인 / 주소 |
- 3M Innovative Properties Company
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
6 인용 특허 :
51 |
초록
▼
Flow field designs are provided, as well as flow field devices employing the subject flow field designs. A fluid distribution assembly is provided comprising a flow field device and a fluid transport layer disposed between the flow field device and a target area, where, for at least one finite non-z
Flow field designs are provided, as well as flow field devices employing the subject flow field designs. A fluid distribution assembly is provided comprising a flow field device and a fluid transport layer disposed between the flow field device and a target area, where, for at least one finite non-zero flow rate and at least one use rate of an active component of the fluid in the fluid transport layer, lateral flux of the active component varies by no more than 35% through at least 90% of all overland portions of said fluid transport layer. In one embodiment, the flow field device comprises a flow field comprising a serpentine channel, comprising non-parallel sequential major segments. In a further embodiment, the angles between successive major segments of the serpentine channel vary progressively.
대표청구항
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1. A fluid distribution assembly comprising: 1) a flow field device embodying a flow field which comprises an active area comprising a) at least one channel having an inlet and an outlet, and b) at least one land area, and 2) a fluid transport layer disposed between said active area and a target are
1. A fluid distribution assembly comprising: 1) a flow field device embodying a flow field which comprises an active area comprising a) at least one channel having an inlet and an outlet, and b) at least one land area, and 2) a fluid transport layer disposed between said active area and a target area;wherein, for at least one non-zero flow rate of a fluid into said inlet and at least one use rate of an active component of the fluid in the fluid transport layer, lateral flux of said active component varies by no more than 35% through at least 90% of all overland portions of said fluid transport layer. 2. The fluid distribution assembly according to claim 1 wherein lateral flux of said active component varies by no more than 25% through at least 90% of all overland portions of said fluid transport layer. 3. The fluid distribution assembly according to claim 1 wherein 70% or more of the active area of said flow field is land area. 4. The fluid distribution assembly according to claim 3 wherein lateral flux of said active component varies by no more than 25% through at least 90% of all overland portions of said fluid transport layer. 5. The fluid distribution assembly according to claim 1 wherein said channel is a serpentine channel. 6. The fluid distribution assembly according to claim 5 wherein at least two sequential major segments of said serpentine channel are non-parallel. 7. The fluid distribution assembly according to claim 5, wherein at least three sequential major segments of said serpentine channel are non-parallel. 8. The fluid distribution assembly according to claim 5, wherein no more than 49% of the major segments of said serpentine channel are parallel. 9. The fluid distribution assembly according to claim 5, wherein no more than 25% of the major segments of said serpentine channel are parallel. 10. The fluid distribution assembly according to claim 1 wherein said channel comprises major segments separated by land areas, wherein the areal size of the land areas decreases monotonically with distance from the inlet as measured along said channel. 11. A fuel cell comprising the fluid distribution assembly according to claim 1. 12. A flow field device embodying a flow field comprising at least one serpentine channel wherein at least two sequential major segments of said serpentine channel are non-parallel. 13. The flow field device according to claim 12, wherein at least three sequential major segments of said serpentine channel are non-parallel. 14. The flow field device according to claim 12, wherein no more than 49% of the major segments of said serpentine channel are parallel. 15. The flow field device according to claim 12, wherein no more than 25% of the major segments of said serpentine channel are parallel. 16. The fluid distribution assembly according to claim 12 wherein said channel comprises major segments separated by land areas, wherein the areal size of the land areas decreases monotonically with distance from the inlet as measured along said channel. 17. The flow field device according to claim 12 wherein said channel comprises multiple courses. 18. A fluid distribution assembly comprising: i) a flow field device according to claim 12, and ii) a fluid transport layer disposed between said active area and a target area. 19. The flow field device according to claim 12 which is porous. 20. The flow field device according to claim 12 which is non-porous. 21. The flow field device according to claim 12 which is electrically conductive. 22. A flow field device embodying a flow field comprising at least one channel and at least one land area,wherein said land area separates a first major segment of said channel and a second major segment of said channel,wherein for any first point on said first major segment there is a second point on said second major segment which is nearest to said first point, andwherein the shortest distance between said first and second points increases monotonically with the distance be tween said first and second points measured as distance along said channel. 23. The fluid distribution assembly according to claim 22 wherein said channel is a serpentine channel. 24. The flow field device according to claim 23 wherein at least two sequential major segments of said serpentine channel form an angle of greater than 0 and less than 45 degrees. 25. The flow field device according to claim 23 wherein at least two sequential major segments of said serpentine channel form an angle of greater than 0 and less than 10 degrees. 26. The flow field device according to claim 23 wherein at least two sequential major segments of said serpentine channel form an angle of greater than 0.5 and less than 10 degrees. 27. The flow field device according to claim 23, wherein a first pair of sequential major segments of said serpentine channel form a first acute angle, wherein a second pair of sequential major segments of said serpentine channel form a second acute angle, and wherein said first acute angle is not equal to said second acute angle. 28. The flow field device according to claim 23 wherein said serpentine channel has an inlet, wherein a first pair of sequential major segments of said serpentine channel form a first acute angle, wherein a second pair of sequential major segments of said serpentine channel form a second acute angle, wherein said first pair of sequential major segments is closer to the inlet than said second pair of sequential major segments as measured in distance along said serpentine channel, and wherein said first acute angle is greater than said second acute angle. 29. The flow field device according to claim 23 wherein said serpentine channel has an inlet, wherein sequential major segments of said serpentine channel form acute angles, and wherein said acute angles decrease in distance from said inlet as measured in distance along said serpentine channel. 30. The flow field device according to claim 23 wherein said channel comprises multiple courses. 31. A fluid distribution assembly comprising: i) a flow field device according to claim 23, and ii) a fluid transport layer disposed between said active area and a target area. 32. A flow field device embodying a flow field comprising at least one channel comprising major segments which comprise analogous parts, wherein the distance between analogous parts of sequential major segments decreases monotonically with distance from the inlet as measured along said channel. 33. A flow field device embodying a flow field comprising at least one channel comprising major segments separated by land areas, wherein the areal size of the land areas decreases monotonically with distance from the inlet as measured along said channel.
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