Abstract: A method of fabricating a flexible battery comprises forming a first substrate on a first release liner, forming at least one current collector layer on each of the first and second substrate, forming an anode side of the battery by forming an anode on the current collector of the first substrate, forming a cathode side of the battery by forming a cathode on the current collector of the second substrate, depositing electrolyte on one or both of the anode and cathode, adhering and sealing the anode side and cathode side together such that the anode and cathode face one another with the electrolyte In between, and removing the flexible battery from the release liners. The battery may be a primary battery or a secondary battery. The method may be implemented using a roll-to-roll process.

Abstract: A rechargeable power device comprises one or more supercapacitors, at least one rechargeable battery and control electronics arranged to couple the supercapacitor(s) to the at least one rechargeable battery. The rechargeable power device may be operable to rapidly recharge and provide power to electronic equipment, whilst being flexible in structure. The rechargeable power device may be integrated into a user device and/or garment.

Abstract: This invention describes a layer-by-layer manufacturing process to create fully printable supercapacitors which are highly flexible in nature and can be formed into a specific shape or size allowing use in electronic devices including but not limited to large energy storage systems, electronic equipment and wearable devices. A polymer-based substrate material with superior flexibility is printed onto a release liner followed by deposition of successive layers of active materials. In this manner both the electrodes of a flexible supercapacitor can be prepared separately on the printed substrates before arranging them on top of each other with a thin layer of electrolyte in the middle. The assembled supercapacitors enclosed in the flexible polymer substrate can be removed afterwards from the release liner, providing a fully printed structure with outstanding flexibility. Supercapacitors developed in this manner are fully scalable and can be produced in a roll-to roll production facility.

Abstract: A method of fabricating a flexible battery comprises forming a first substrate on a first release liner, forming at least one current collector layer on each of the first and second substrate, forming an anode side of the battery by forming an anode on the current collector of the first substrate, forming a cathode side of the battery by forming a cathode on the current collector of the second substrate, depositing electrolyte on one or both of the anode and cathode, adhering and sealing the anode side and cathode side together such that the anode and cathode face one another with the electrolyte In between, and removing the flexible battery from the release liners. The battery may be a primary battery or a secondary battery. The method may be implemented using a roll-to-roll process.

Abstract: A printable active material formulation comprises a matrix comprising a gelation material and a solvent; and at least one conductive material. A printable cathode formulation comprises a matrix comprising a thermoplastic resin and a solvent; and at least one conductive material. An organic light emitting or photovoltaic device may be manufactured using these formulations, for example by roll-to-roll printing.

Abstract: A rechargeable power device comprises one or more supercapacitors, at least one rechargeable battery and control electronics arranged to couple the supercapacitor(s) to the at least one rechargeable battery. The rechargeable power device may be operable to rapidly recharge and provide power to electronic equipment, whilst being flexible in structure. The rechargeable power device may be integrated into a user device and/or garment.