Method for making a thin flexible primary battery for microelectronics applications
First Claim
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1. A flexible primary battery suitable for microelectronics applications, the battery comprising:
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a first flexible current collector comprising a first polymeric sheet having a first metal foil on a first surface of the first polymeric sheet and a first metal film on a second surface of the first polymeric sheet, the first polymeric sheet being exposed at the perimeter of the first surface;
a polymeric wall sealingly abutting the polymeric sheet along the perimeter of the first surface so as to form a cavity with the first flexible current collector;
a lithium anode disposed within the cavity and overlaying the first metal foil on the first surface of the first polymeric sheet;
a flexible lithium electrolyte membrane disposed within the cavity and overlaying the lithium anode;
a flexible cathode disposed within the cavity and overlaying the lithium electrolyte membrane, the cathode comprising an inorganic powder of lithium intercalation compound and lithium salts dispersed in a polymeric binder;
a second flexible current collector comprising a second polymeric sheet having a second metal foil on a first surface of the second polymeric sheet and a second metal film on a second surface of the second polymeric sheet, the second polymeric sheet sealingly abutting the polymeric wall at the perimeter of the first surface of the second polymeric sheet; and
leads associated with the first and second flexible current collectors;
wherein the first and second polymeric sheets and the polymeric wall form a sealed package which encloses the lithium anode, the lithium electrolyte membrane, and the cathode.
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Abstract
A method is provided for making a flexible primary battery suitable for microelectronics applications, and more particularly, for use with self-contained self-powered portable devices (SSPD) such as RF-ID tags. The method generally employs photolithography and etching techniques to minimize the thicknesses of metal foils required in the structure of the battery, as well as packaging methods which yield a flexible and durable battery having a thickness of not more than about 0.5 millimeter, and preferably about 0.3 millimeter or less, and a relatively small size on the order of a few square centimeters in surface area.
98 Citations
29 Claims
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1. A flexible primary battery suitable for microelectronics applications, the battery comprising:
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a first flexible current collector comprising a first polymeric sheet having a first metal foil on a first surface of the first polymeric sheet and a first metal film on a second surface of the first polymeric sheet, the first polymeric sheet being exposed at the perimeter of the first surface; a polymeric wall sealingly abutting the polymeric sheet along the perimeter of the first surface so as to form a cavity with the first flexible current collector; a lithium anode disposed within the cavity and overlaying the first metal foil on the first surface of the first polymeric sheet; a flexible lithium electrolyte membrane disposed within the cavity and overlaying the lithium anode; a flexible cathode disposed within the cavity and overlaying the lithium electrolyte membrane, the cathode comprising an inorganic powder of lithium intercalation compound and lithium salts dispersed in a polymeric binder; a second flexible current collector comprising a second polymeric sheet having a second metal foil on a first surface of the second polymeric sheet and a second metal film on a second surface of the second polymeric sheet, the second polymeric sheet sealingly abutting the polymeric wall at the perimeter of the first surface of the second polymeric sheet; and leads associated with the first and second flexible current collectors; wherein the first and second polymeric sheets and the polymeric wall form a sealed package which encloses the lithium anode, the lithium electrolyte membrane, and the cathode. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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12. A method for forming a flexible primary battery suitable for microelectronics applications, the method comprising the steps of:
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forming first and second flexible current collectors, each of which is formed by photolithographically developing a metal foil on a first surface of a polymeric sheet and etching the metal foil such that the polymeric sheet is exposed at the perimeter of the first surface, and depositing a metal film on a second surface of the polymeric sheet, such that the first and second flexible current collectors are free-standing and each has a thickness of less than 50 micrometers, the polymeric sheet constituting more than half of the thickness so as to promote the flexibility of the first and second flexible current collectors; forming a flexible foil cathode comprising an inorganic powder of lithium intercalation compound and a lithium salt dispersed in a polymeric binder; assembling the first and second flexible current collectors, a lithium foil anode, a flexible lithium salt-doped polymer electrolyte membrane, the flexible foil cathode and a polymeric wall, such that the lithium foil anode contacts the metal foil of the first flexible current collector, the flexible foil cathode contacts the metal foil of the second flexible current collector, the polymer electrolyte membrane is between the lithium foil anode and the flexible foil cathode, the polymeric wall circumscribes the metal foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane and the flexible foil cathode, and the polymeric wall abuts the polymeric sheets exposed along the perimeter of the first and second flexible current collectors, so as to form a battery assembly; heating the battery assembly such that the polymeric sheets of the first and second flexible current collectors, the polymer electrolyte membrane and the polymeric wall partially melt to form a sealed package which encloses the metal foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane, and the flexible foil cathode; and forming leads associated with the first and second flexible current collectors; wherein the thickness of the battery is not more than about 0.5 millimeter such that the battery is characterized as being flexible, and wherein the battery is characterized by a cell voltage of at least about 3 volts. - View Dependent Claims (13, 14, 22, 23, 24)
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15. A method for forming a flexible primary battery suitable for microelectronics applications, the method comprising the steps of:
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forming first and second flexible current collectors, each of which is formed by photolithographically developing a metal foil on a first surface of a polymeric sheet and etching the metal foil such that the polymeric sheet is exposed at the perimeter of the first surface, and depositing a metal film on a second surface of the polymeric sheet, such that the first and second flexible current collectors are free-standing and each have a thickness of less than 50 micrometers, the polymeric sheet constituting more than half of the thickness so as to promote the flexibility of the first and second flexible current collectors; forming a flexible foil cathode comprising an inorganic powder of lithium intercalation compound and a lithium salt dispersed in a polymeric binder; assembling the first and second flexible current collectors, a lithium foil anode, a flexible lithium salt-doped polymer electrolyte membrane, the flexible foil cathode and a polymeric wall, such that the lithium foil anode contacts the metal foil of the first flexible current collector, the flexible foil cathode contacts the metal foil of the second flexible current collector, the polymer electrolyte membrane is between the lithium foil anode and the flexible foil cathode, the polymeric wall circumscribes the metal foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane and the flexible foil cathode, and the polymeric wall abuts the polymeric sheets exposed along the perimeter of the first and second flexible current collectors, so as to form a battery assembly; and heating the battery assembly such that the polymeric sheets of the first and second flexible current collectors, the polymer electrolyte membrane and the polymeric wall partially melt to form a sealed package which encloses the metal foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane, and the flexible foil cathode; wherein the thickness of the battery is not more than about 0.5 millimeter such that the battery is characterized as being flexible, and wherein the battery is characterized by a cell voltage of at least about 3 volts. - View Dependent Claims (16, 17, 18, 20, 21)
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19. A method for forming a flexible primary battery suitable for microelectronics applications, the method comprising the steps of:
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forming first and second flexible current collectors, each of which is formed by photolithographically developing a copper foil on a first surface of a polymeric sheet and etching the copper foil such that the polymeric sheet is exposed at the perimeter of the first surface, and depositing a metal film on a second surface of the polymeric sheet, such that the first and second flexible current collectors are free-standing and each has a thickness of no more than about 40 micrometers, the polymeric sheet constituting more than half of the thickness so as to promote the flexibility of the first and second flexible current collectors; placing a lithium foil anode, on the copper foil of the first flexible current collector; placing a flexible lithium salt-doped polymer electrolyte membrane on the lithium foil anode, the polymer electrolyte membrane comprising about 4 to about 10 parts polyethylene oxide for each part of lithium salt; placing a flexible foil cathode on the polymer electrolyte membrane, the flexible foil cathode comprising an inorganic powder of lithium intercalation compound and a lithium salt dispersed in a polymeric binder, the inorganic powder of lithium intercalation compound constituting at least about 75 weight percent of the flexible foil cathode and the ratio of lithium salts to polymeric binder in the flexible foil cathode is about 1;
4 to about 1;
10;circumscribing the copper foil of the first flexible current collector, the lithium foil anode, polymer electrolyte membrane and flexible foil cathode with a polymeric wall which abuts the polymeric sheet exposed along the perimeter of the first flexible current collector; placing the second flexible current collector on the flexible foil cathode such that the copper foil of the second flexible current collector overlays the flexible foil cathode and such that the polymeric sheet exposed along the perimeter of the second flexible current collector abuts the polymeric wall, so as to form a battery assembly; heating the battery assembly such that the polymeric sheets of the first and second flexible current collectors, the polymer electrolyte membrane and the polymeric wall partially melt to form a flexible sealed package which encloses the copper foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane, and the flexible foil cathode; and forming leads associated with the first and second flexible current collectors; wherein the thickness of the battery is not more than about 0.5 millimeter such that the battery is characterized as being flexible, and wherein the battery is characterized by a cell voltage of at least about 3 volts, a capacity of at least about 3 milliamp-hours, a stand-by current of at least about 75 nanoamps, and a peak current of at least about 100 microamps for 10 milliseconds. - View Dependent Claims (26, 27, 28, 29)
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25. A method for forming a flexible primary battery suitable for microelectronics applications, the method comprising the steps of:
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forming first and second flexible current collectors, each of which is formed by photolithographically developing a copper foil on a first surface of a polymeric sheet and etching the copper foil such that the polymeric sheet is exposed at the perimeter of the first surface, and depositing a metal film on a second surface of the polymeric sheet, such that the first and second flexible current collectors are free-standing and each have a thickness of no more than about 40 micrometers, the polymeric sheet constituting more than half of the thickness so as to promote the flexibility of the first and second flexible current collectors; placing a lithium foil anode on the copper foil of the first flexible current collector; placing a flexible lithium salt-doped polymer electrolyte membrane on the lithium foil anode, the polymer electrolyte membrane comprising about 4 to about 10 parts polyethylene oxide for each part of lithium salt; placing a flexible foil cathode on the polymer electrolyte membrane, the flexible foil cathode comprising an inorganic powder of lithium intercalation compound and a lithium salt dispersed in a polymeric binder, the inorganic powder of lithium intercalation compound constituting at least about 75 weight percent of the flexible foil cathode and the ratio of lithium salts to polymeric binder in the flexible foil cathode is about 1;
4 to about 1;
10;circumscribing the copper foil of the first flexible current collector, the lithium foil anode, polymer electrolyte membrane and flexible foil cathode with a polymeric wall which abuts the polymeric sheet exposed along the perimeter of the first flexible current collector; placing the second flexible current collector on the flexible foil cathode such that the copper foil of the second flexible current collector overlays the flexible foil cathode and such that the polymeric sheet exposed along the perimeter of the second flexible current collector abuts the polymeric wall, so as to form a battery assembly; and heating the battery assembly such that the polymeric sheets of the first and second flexible current collectors, the polymer electrolyte membrane and the polymeric wall partially melt to form a flexible sealed package which encloses the copper foils of the first and second flexible current collectors, the lithium foil anode, the polymer electrolyte membrane, and the flexible foil cathode; wherein the thickness of the battery is not more than about 0.5 millimeter such that the battery is characterized as being flexible, and wherein the battery is characterized by a cell voltage of at least about 3 volts, a capacity of at least about 3 milliamp-hours, a stand-by current of at least about 75 nanoamps, and a peak current of at least about 100 microamps for 10 milliseconds.
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Specification