The energy content of supercapacitor is determined by its capacitance value and working voltage. To attain a high capacitance and a high voltage, several pieces of electrodes and separators are spirally wound with edge sealing to form a bipolar supercapacitor in cylindrical, oval or square configura
The energy content of supercapacitor is determined by its capacitance value and working voltage. To attain a high capacitance and a high voltage, several pieces of electrodes and separators are spirally wound with edge sealing to form a bipolar supercapacitor in cylindrical, oval or square configuration. While the winding operation effectively provides a large surface area for high capacitance, the bipolar packaging instantly imparts a unitary roll a minimum working voltage of 5V on using an organic electrolyte. The bipolar roll is a powerful building block for facilitating the assembly of supercapacitor modules. Using containers with multiple compartments, as many bipolar rolls can be connected in series, in parallel or in a combination of the two connections to fabricate integrated supercapacitors with high energy density as required by applications.
대표청구항▼
1. A high energy-density supercapacitor, comprising:an anode;a cathode;at least one bipolar electrode interposed between the anode and the cathode;a plurality of separators disposed after the anode, the cathode and the at least one bipolar electrode, respectively; andan electrolyte impregnating the
1. A high energy-density supercapacitor, comprising:an anode;a cathode;at least one bipolar electrode interposed between the anode and the cathode;a plurality of separators disposed after the anode, the cathode and the at least one bipolar electrode, respectively; andan electrolyte impregnating the separators, whereinthe anode, the cathode, the at least one bipolar electrode and the separators are spirally wound to form a jelly roll with an electric lead attached to the anode and a separate electric lead attached to the cathode, wherein the jelly roll is sealed at starting ends of all electrodes and separators, at very ends of all electrodes and separators, at a top of the jelly roll, as well as at a bottom of the jelly roll using a curable polymer. 2. The high energy-density supercapacitor according to claim 1, wherein the electric leads attached to the anode and the cathode are at the top of the jelly roll. 3. The high energy-density supercapacitor according to claim 1, wherein the jelly roll is edge sealed at four sides. 4. The high energy-density supercapacitor according to claim 3, wherein an edge sealant for sealing edges of the jelly roll comprises one selected from the group consisting of epoxies, polyacrylates, polyurethanes and polyesters. 5. The high energy-density supercapacitor according to claim 3, wherein the bipolarity of the at least one bipolar electrode is created by edge sealing, and no electric lead is attached to the the at least one bipolar electrode. 6. The high energy-density supercapacitor according to claim 1, wherein the high energy-density supercapacitor is operated at voltages equal to or above 5V, with a capacitance value equal to or above 1F and an equivalent series resistance (ESR) value below 30 mΩ. 7. The high energy-density supercapacitor according to claim 1, wherein the electrolyte impregnating the separators comprises an organic electrolyte. 8. The high energy-density supercapacitor according to claim 1, wherein the jelly roll is in a cylindrical, oval or square configuration. 9. The high energy-density supercapacitor according to claim 1, further comprising:a plurality of said jelly rolls; anda multiple-compartment container for containing the jelly rolls, wherein each jelly roll is disposed in a compartment of the multiple-compartment container for series connection, parallel connection or a combination of the two. 10. A high energy-density supercapacitor, comprising:a plurality of capacitor rolls, each comprisingan anode;a cathode;a bipolar electrode;a plurality of separators disposed after the anode, the cathode and the bipolar electrode, respectively; andan electrolyte impregnating the separators, wherein the anode, the cathode, the bipolar electrode and the separators are spirally wound to form a jelly roll with an electric lead attached to the anode and a separate electric lead attached to the cathode; anda multiple-compartment container for containing the jelly rolls, wherein each jelly roll is disposed in a compartment of the multiple-compartment container for series connection, parallel connection or a combination of the two. 11. The high energy-density supercapacitor according to claim 10, wherein the electric leads connected to the anode and the cathode of each jelly roll are at the same end of the jelly roll defined as a top of the jelly roll. 12. The high energy-density supercapacitor according to claim 10, wherein each jelly roll is sealed at starting ends of all electrodes and separators thereof, at very ends of all electrodes and separators thereof, at the top thereof, as well as at a bottom thereof using a curable polymer. 13. The high energy-density supercapacitor according to claim 12, wherein each jelly roll is edge sealed at four sides thereof. 14. The high energy-density supercapacitor according to claim 13, wherein an edge sealant for sealing edges of each jelly roll includes one selected from the group consisting of epoxies, polyacrylates, polyurethanes and polyesters. 15. The high energy-density supercapacitor according to claim 10, wherein the electrolyte impregnating the separators comprises an organic electrolyte. 16. The high energy-density supercapacitor according to claim 10, wherein the multi-compartment container has at least two compartments. 17. The high energy-density supercapacitor according to claim 16, wherein the container has two detachable parts including a cover and a base, wherein the cover is for hermetic sealing, and the base is for containing the capacitor rolls in the compartments therein. 18. The high energy-density supercapacitor according to claim 17, wherein all parts of the container are made of a material selected from the group consisting of PE, PP, reinforced PE and reinforced PP. 19. The high energy-density supercapacitor according to claim 17, wherein the cover and the base are consolidated by a potting material. 20. The high energy-density supercapacitor according to claim 16, wherein the device formed by series connection of plural number of capacitor rolls in the container is operated at voltages equal to or above 5V, with a capacitance value equal to or above 1F and an equivalent series resistance (ESR) value below 30 mΩ.
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