WO2007059269B1

WO2007059269B1 - High-rate rechargeable battery

Info

Publication number: WO2007059269B1
Application number: PCT/US2006/044471
Authority: WO
Inventors: Wilhelm Kullberg
Original assignee: Electrolysis Technologies; Wilhelm Kullberg
Priority date: 2005-11-16
Filing date: 2006-11-16
Publication date: 2007-10-18
Also published as: JP2009516355A; BRPI0618626A2; WO2007059269A2; WO2007059269A8; EP2095456A4; WO2007059269A3; EP2095456A2

Abstract

A battery consisting of multiple electrochemical cells, serial arranged via multiple 2-circuit relays and controlled by a battery management controller, generating high-rate capacity for powering an electrical motor. The invention has application in a modern automobile for powering a mid-size automobile for a distance of up to 1500km. The new electrochemical cell system can be recharged 500 times (every 1500km), and eliminates air pollution and solves many of the other environmental problems associated with the internal combustion engine.

Claims

AMENDED CLAIMS received by the International Bureau on 02 Aug 2007 (02.08.07)Claims:

1. A ⁽rechargeable battery cell, comprising an anode film layer, a film membrane layer immersed in an electrolyte, a cathode film layer and at least one barrier film layer between said anode and cathode film layer, the cell wound into a coil having multiple integrated anode current collector film layers oriented between said anode film layer and said electrolyte film membrane layer at different coil winding locations, and multiple integrated cathode current collector film layers oriented between said cathode film layer and said electrolyte film membrane layer at different coil winding locations, said multiple anode film current collectors, each contacting at least 10% area of 1 coil winding of the cells anode film, said multiple cathode film current collectors, each contacting at least 10% area of 1 coil winding of the cells cathode film, said multiple anode current collector film layers and said multiple cathode current collector film layers separated by polarity, stacked and compressed outside the coil.

2. A rechargeable battery cell, comprising an anode film layer, a film membrane layer immersed in an electrolyte, a cathode film layer and at least one barrier film layer between said anode and cathode film layers, the cell wound into a coil having multiple integrated anode current collector film layers contacting the anode film layers at different coil winding locations, and multiple integrated cathode current collector film layers contacting the cathode film layers at different coil winding locations, said multiple anode current collector film layers and said multiple cathode current collector film layers separated by polarity, stacked and compressed outside the coil.

3. A rechargeable battery cell, comprising an anode film layer, a film membrane layer immersed in an electrolyte, a cathode film layer and at least one barrier film layer between said anode and cathode film layer, the cell wound into a coil with a stacked part of the anode film layers protruding one cell side, and with a stacked part of the cathode film layers protruding the other cell side, said protruding electrodes separated by polarity, stacked and compressed, collecting the current from the cell.

4. A rechargeable battery cell according to claims 1 - 3, wherein the cell/coif having a flat tube core structure with internal air-cooling bars oriented between both extended panel walls of said flat core structure.

5. A rechargeable battery cell according to claims 1 - 4, wherein the cell core structure consist of at least two conductive cross sections with at least one insulation element oriented between each said two conductive cross sections, one core structure section connected to the anode current collectors and the other core structure section connected to the cathode current collectors.

6. A rechargeable battery cell according to claims 1 - 5, wherein at least one compressed stack anode film current collectors, generally oriented on one cell side, and at least one compressed stack cathode film current collectors, generally oriented on the opposed cell side.

7. A rechargeable battery cell according to claims 1 - 6, wherein at least one anode film current collector stack, generally parallel oriented to the first opposed extended panel wall of the generally rectangular cell cores cross section profile, and at least one cathode film current collector stack, generally parallel oriented to the second opposed extended panel wall of the generally rectangular cell cores cross section profile.

8. A rechargeable cell according to claims 1 - 7, wherein at least one multiple anode film current collector stack, generally having a matching cross section profile with the cell cross section profile of the anode in the film current collector area, and at least one multiple cathode film current collector stack, generally having a matching cross section profile with the cell cross section profile of the cathode in the film current collector area.

9. A rechargeable battery cell according to claims 1 - 8, wherein the cell length is generally equal between each current collector.

10. A rechargeable battery cell according to claims 1 - 9, wherein at least one anode and at least one cathode current collector stack, may be orientated in any position, including on any side, inside or outside the cell container.

11. A rechargeable battery cell according cell to claims 1 - 10, wherein at least one insulation layer is oriented - between the cell core and each compressed cell stack.

12. A rechargeable battery cell according to claims 1 - 11, wherein at least one cell container panel wall is wrapped around the cell core in a closed engagement.

13. A rechargeable battery cell according to claims 1 - 12, wherein a cell container end area having a hermetic seal oriented between the container panel wall and the cell core structure.

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14. A rechargeable battery cell according to claims 1 - 13, wherein at least one cell container panel end wall area is contour formed.

15. A rechargeable battery cell according to claims 1 - 14, wherein the cell is encased in a hermetic sealed container.

16. A rechargeable battery cell according to claims 1 - 15, wherein the cell is air cooled; by velocity as the automobile forward, or by a fan.

17. A rechargeable battery cell according to claims 1 - 16, wherein the cells tube core structure having a generally rectangular cross section profile.

18. A rechargeable battery cell according to claim 3, wherein parts of the electrode film barrier layer overlaps both coil edge sides.

19. A rechargeable battery cell according to claims 3 & 18, wherein at one cell side, the film barrier overlaps the anode film layer edge and at the other cell side, the film barrier overlaps the cathode film layer edge.

20. A rechargeable battery cell according to claims 3, 18 & 19, wherein the battery cell having at least one anode stack and at least one cathode stack.

21. A rechargeable battery cell according to claims 1 - 20, wherein the stacked current collectors are welded together.

22. A rechargeable battery cell according to claims 1 - 21, wherein an air tunnel manifold having an air tunnel branch to each cell core tube structure passage, cooling each multi-laminate cell as the automobile moves forward.

23. A rechargeable battery cell according to claims 1 - 22, wherein a plurality of serial and/or parallel arranged cells power an electrical motor in an automobile, including a Hybrid alternative automobile type.

24. A 2-circuit electromagnetic relay, wherein said electromagnetic relay; make single cell integration in a serial cell arrangement, break single cell bypass in a serial cell arrangement.

25. A 2-circuit electromagnetic relay, wherein said electromagnetic relay; make single cell bypass in a cell arrangement, brake single cell integration in a serial cell arrangement.

26. An electromagnetic relay, wherein an armature arrange a first circuit between a set of first circuit contacts, in a second position said armature arrange a second circuit between a second set circuit contacts, at least one first circuit contact connected with at least one second circuit contact, outside the armature.

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27. An electromagnetic relay, wherein an armature arrange a first circuit between a set of first set circuit contacts, said armature pivot and arranging a second circuit between a second set circuit contacts, said armature contacts for each circuit oriented on opposite armature side of the armature pivoting point, at least one first circuit contact connected with at least one second circuit contact, outside the armature.

28. An electromagnetic relay, wherein an armature arrange a first circuit between a set of first circuit contacts, said armature move linearly and turn around its own axis, arranging a second circuit between a second set circuit contacts (said armature move back and forth between said first and second set circuit contacts), at least one first circuit contact connected with at least one second circuit contact, outside the armature.

29 An electromagnetic relay according to claims 24 - 28, in combination with a plurality of rechargeable battery cells according to any one of claims 1 - 23, wherein said relay switch at least one serial arranged cell in/out of a serial cell arrangement.

30. An arrangement of circuit elements (logic), wherein at least one relay, contactor or any switch type combinations execute arrangement of circuit elements (logic) according to claims 24 - 28.

31. An arrangement of circuit elements (logic) according to claim 29, wherein at least one relay, contactor or any switch is controlled by a computer.

32. A battery management method, wherein a cell reaches a too high predetermined temperature level, it will send a control signal to the controller, which will switch said cell out of the serial or parallel cell arrangement.

33. A battery management method, wherein a cell reaches a too high predetermined temperature level within a predetermined time, it will send a control signal to the controller, which will switch said cell out of the serial or parallel cell arrangement.

34. A battery management method, wherein a cell reaches a too high predetermined temperature level compared with a predetermined average temperature of the other cells, it will send a signal to the controller, which switch said cell out of the serial or parallel cell arrangement.

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35. A battery management method, wherein a cells voltage drops to a predetermined level, it will send a control signal to the controller which will switch said cell out of the serial or parallel cell arrangement.

36. A battery management method, wherein a cells voltage drops to a predetermined level within a predetermined time, it will send a control signal to the controller, which will switch said cell out of the serial or parallel cell arrangement.

37. A battery management method, wherein a cell voltage increases to a predetermined level, it will send a control signal to the controller, which will switch said cell out of the serial or parallel cell arrangement.

38. A battery management method, wherein a cells voltage increases to a predetermined level within a predetermined time, it will send a control signal to the controller, which will switch said cell out of the serial or parallel cell arrangement.

39. A battery management method, wherein an accelerometer built into a micro chip tells the sensor to send a signal to the controller, which will switch at least one cell out of the serial or parallel cell arrangement, if the automobile turn into a high-impact collision.

40. A battery management method, wherein an accelerometer built into a micro chip tells the sensor to send a signal to the controller, which will switch all cells out of the serial or parallel cell arrangement, if the automobile turn into a high-impact collision.

41. An electromagnetic relay according to claims 24 - 28, in combination with a plurality of rechargeable battery cells according to any one of claims 1 - 23, wherein said relay switch a combination of at least one serial arranged cell and at least two parallel arranged cells in/out of a serial cell arrangement.

42. A relay according to claims 24 - 29 & 41, wherein said relay is a solid state relay type.

43. A battery management method according to claims 35 - 38, wherein using series of voltage dividers networks, each of said networks having a node that is connected to the individual cells positive terminal.

44. A battery management method according to claims 35 - 38, wherein using series of temperature dividers networks, each of said networks having a node that is integrated in the individual cells coil.

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45. A battery management method, wherein once one serial cell group of the serial cell arrangement goes off line after being recharged, next group of serial cells will be recharged.

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