An energy-storage device electrode core is disclosed that features relatively low-inductive impedance (and thus low equivalent series resistance (ESR)). Also disclosed is an energy-storage device electrode core that features a radii-modulated electrode core that forms extra vias to facilitate effici
An energy-storage device electrode core is disclosed that features relatively low-inductive impedance (and thus low equivalent series resistance (ESR)). Also disclosed is an energy-storage device electrode core that features a radii-modulated electrode core that forms extra vias to facilitate efficient heat removal away from the electrode, thus improving the performance and capabilities of an energy-storage device so equipped. The internal electrode core heat-removal vias are defined by the modulation patterns that in turn define the size and layout of the folds in the electrode, which are circumferentially collapsed about the center axis of the electrode core.
대표청구항▼
1. An energy-storage electrode core, adapted for use in an energy-storage device, comprising: a first current-collector foil element having a first side and a second side, comprising: a first plurality of carbon-electrode elements disposed on said first side of said first current-collector foil elem
1. An energy-storage electrode core, adapted for use in an energy-storage device, comprising: a first current-collector foil element having a first side and a second side, comprising: a first plurality of carbon-electrode elements disposed on said first side of said first current-collector foil element, wherein said first plurality of carbon-electrode elements define a first plurality of fold-zone regions defined between a first plurality of fold-zone demarcation regions, anda second plurality of carbon-electrode elements disposed on said second side of said first current-collector foil element, wherein said second plurality of carbon-electrode elements define a second plurality of fold-zone regions defined between a first plurality of fold zone demarcation regions;a second current-collector foil element having a first side and a second side, comprising: a third plurality of carbon-electrode elements disposed on said first side of said second current-collector foil element, wherein said third plurality of carbon-electrode elements define a third plurality of fold-zone regions defined between a second plurality of fold zone demarcation regions, anda fourth plurality of carbon-electrode elements disposed on said second side of said second current-collector foil element, wherein said fourth plurality of carbon-electrode elements define a fourth plurality of fold-zone regions defined between a second plurality of fold zone demarcation regions;a separator element, having a front side and a back side, wherein the front side of said separator element is affixed to said second side of said first current-collector foil element,wherein the back side of said separator element is affixed to said first side of said second current-collector foil element, andwherein said separator element prevents said first current-collector foil element from electronically shorting to said second current-collector foil element, while still allowing ionic current flow therebetween; anda center axis about which said fold-zones of said current-collector foil elements are circumferentially collapsed, wherein folded electrode elements are disposed in a substantially annular form, forming substantially a single loop of radial electrode folds, andwherein said pluralities of fold-zone demarcation regions are approximately laterally and co-axially aligned with respect to said first and second current-collector foils. 2. The energy-storage electrode core of claim 1, wherein said energy-storage device is an ultracapacitor. 3. The energy-storage electrode core of claim 1, wherein said energy-storage device is a battery. 4. The energy-storage electrode core of claim 3, wherein said battery is a lithium-ion battery. 5. The energy-storage electrode core of claim 1, wherein said energy-storage device is a hybrid energy-storage device. 6. A method adapted for use in an energy-storage device, comprising the steps of: providing a first current-collector foil element having a first side and a second side, comprising: a first plurality of carbon-electrode elements disposed on said first side of said first current-collector foil element, wherein said first plurality of carbon-electrode elements define a first plurality of fold-zone regions defined between a first plurality of fold-zone demarcation regions, anda second plurality of carbon-electrode elements disposed on said second side of said first current-collector foil element, wherein said second plurality of carbon-electrode elements define a second plurality of fold-zone regions defined between a first plurality of fold zone demarcation regions;providing a second current-collector foil element having a first side and a second side, comprising: a third plurality of carbon-electrode elements disposed on said first side of said second current-collector foil element, wherein said third plurality of carbon-electrode elements define a third plurality of fold-zone regions defined between a second plurality of fold zone demarcation regions, anda fourth plurality of carbon-electrode elements disposed on said second side of said second current-collector foil element, wherein said fourth plurality of carbon-electrode elements define a fourth plurality of fold-zone regions defined between a second plurality of fold zone demarcation regions;providing a separator element, having a front side and a back side, wherein the front side of said separator element is affixed to said second side of said first current-collector foil element,wherein the back side of said separator element is affixed to said first side of said second current-collector foil element, andwherein said separator element prevents said first current-collector foil element from electronically shorting to said second current-collector foil element, while still allowing ionic current flow therebetween; andcircumferentially collapsing said fold-zones of said current-collector foil elements about a center axis, wherein folded electrode elements are disposed in a substantially annular form, forming substantially a single loop of radial electrode folds, andwherein said pluralities of fold-zone demarcation regions are approximately laterally and co-axially aligned with respect to said first and second current-collector foils. 7. The method of claim 6, wherein said energy-storage device is an ultracapacitor. 8. The method of claim 6, wherein said energy-storage device is a battery. 9. The method of claim 8, wherein said battery is a lithium-ion battery. 10. The method of claim 6, wherein said energy-storage device is a hybrid energy-storage device. 11. An energy-storage electrode core, comprising: a current collector; anda first plurality of carbon electrode elements disposed along a first side of the current collector, the carbon electrode elements spaced apart from each other such that a fold-zone demarcation region extends within a gap formed between adjacent pairs of carbon electrode elements;wherein the current collector and the first plurality of carbon electrode elements are folded along the fold-zone demarcation regions to form a modulated pattern of folds that extends annularly around a center axis. 12. The energy-storage electrode core of claim 11, wherein the modulated pattern of folds forms a substantially annular ring extending around the center axis. 13. The energy-storage electrode core of claim 12, wherein the annular ring forms a hollow core extending along the center axis. 14. The energy-storage electrode core of claim 11, further comprising a second plurality of carbon electrode elements disposed along a second side of the current collector and opposed to the first plurality of carbon electrode elements. 15. The energy-storage electrode core of claim 11, further comprising a second current collector separated from the first current collector by a separator element. 16. The energy-storage electrode core of claim 11, wherein the modulated pattern of folds comprises a sinusoidal modulated pattern of folds. 17. The energy-storage electrode core of claim 11, wherein the modulated pattern of folds comprises folds of differing widths. 18. The energy-storage electrode core of claim 11, wherein the current collector comprises an aluminum foil. 19. An ultracapacitor, comprising the energy-storage electrode core of claim 11. 20. The ultracapacitor of claim 19, further comprising electrolyte disposed within the energy-storage electrode core.
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