A power storage cell includes a cathode, an anode, a separator, and a sealing portion. The sealing portion includes a first resin layer, a second resin layer, a third resin layer provided between the first resin layer and the second resin layer and welded to the first resin layer and the second resin layer, and a welded area formed by an outer edge portion of the first resin layer, an outer edge portion of the second resin layer, and an outer edge portion of the third resin layer being integrated with each other by welding. An inner edge of the welded area is positioned outward of an inner edge of a bonded area between the first resin layer and the current collector and an inner edge of a bonded area between the second resin layer and the current collector.

A electric storage device that includes a device body having a first end face that has a first portion and a second portion, and second end face that has a third portion and a fourth portion. The second portion is inclined relative to the first portion, and the fourth portion is inclined relative to the third portion. A first electrode film extends from the first portion to the second portion, and a second electrode film extends from the third portion to the fourth portion.

Disclosed is an aluminum ion capacitor, including a separator, an anode and a cathode, between which the separator is interposed, and an electrolyte contacting the anode and the cathode, wherein the anode contains aluminum, the electrolyte contains aluminum ions, and an electrical double layer is formed at the cathode and intercalation and deintercalation of aluminum ions are performed at the anode. Accordingly, a supercapacitor having increased energy density can be effectively manufactured at lower cost than lithium ion capacitors, and also, the supercapacitor has high material stability and thus is not limited as to electrode configuration, and an electrode configuration that has a low manufacturing cost and is able to increase energy density and power density can be adopted.

Disclosed is an aluminum ion capacitor, including a separator, an anode and a cathode, between which the separator is interposed, and an electrolyte contacting the anode and the cathode, wherein the anode contains aluminum, the electrolyte contains aluminum ions, and an electrical double layer is formed at the cathode and intercalation and deintercalation of aluminum ions are performed at the anode. Accordingly, a supercapacitor having increased energy density can be effectively manufactured at lower cost than lithium ion capacitors, and also, the supercapacitor has high material stability and thus is not limited as to electrode configuration, and an electrode configuration that has a low manufacturing cost and is able to increase energy density and power density can be adopted.

An electrochemical device includes multiple electrode bodies and electrolyte. Each electrode body includes: an electrode unit constituted by positive electrodes and negative electrodes that are stacked together alternately with separators in between; a first lithium ion pre-doping supply source which includes a first current collector being a metal foil having no through holes; and a second lithium ion pre-doping supply source which sandwiches the electrode unit together with the first lithium ion supply source, and which includes a second current collector being a metal foil having no though holes. The multiple electrode bodies are stacked in a manner attaching the first current collector of one electrode body to the second current collector of another electrode body. The negative electrodes provided in each electrode unit are pre-doped with lithium ions derived from the first lithium ion pre-doping supply source and the second lithium ion pre-doping supply source.

An electric double layer capacitor that includes a first electrode having a first polarizable electrode on a first collector electrode; a second electrode having a second polarizable electrode on a second collector electrode; and a separator interposed between the first polarizable electrode and the second polarizable electrode. The separator includes a bonding part filled with a resin. The bonding part extends to a surface of the separator closer to the first polarizable electrode, and the separator and the first polarizable electrode are bonded to each other by the bonding part.

A lithium ion energy and power system including: a housing containing: at least three electrodes including: at least one first electrode including a cathodic faradaic energy storage material; at least one second electrode including an anodic faradaic energy storage material; and at least one third electrode including a cathodic non-faradaic energy storage material, wherein the at least one first, second, and third electrodes are adjacent as defined herein, and the at least one second electrode is electrically isolated from the electrically coupled at least one first electrode and the at least one third electrode; a separator between the electrodes; and a liquid electrolyte between the electrodes. Also disclosed is a method of making and using the disclosed lithium ion energy and power system.

A lithium ion energy and power system including: a housing containing: at least three electrodes including: at least one first electrode including a cathodic faradaic energy storage material; at least one second electrode including an anodic faradaic energy storage material; and at least one third electrode including a cathodic non-faradaic energy storage material, wherein the at least one first, second, and third electrodes are adjacent as defined herein, and the at least one second electrode is electrically isolated from the electrically coupled at least one first electrode and the at least one third electrode; a separator between the electrodes; and a liquid electrolyte between the electrodes. Also disclosed is a method of making and using the disclosed lithium ion energy and power system.

This disclosure provides collector plates for an energy storage device, energy storage devices with a collector plate, and methods for manufacturing the same. In one aspect, a collector plate includes a body. One or more apertures extend into the body. The apertures are configured to allow a portion of a free end of a spirally wound current collector of a spirally wound electrode for an energy storage device to extend into the one or more apertures.

An electrical energy store having a spatially-optimized electrode interconnection. The electrical energy store (1) comprises flat electrodes (3), flags (7) projecting laterally from the electrodes (3), and external terminals (9). A plurality of electrode regions are respectively stacked, one on top of another, to form an electrode stack (14). A plurality of flags (7) are arranged one on top of another in a flag stack (15), and are respectively materially bonded, both mutually and with an associated external terminal (9). The energy store is characterized in that each flag (7) of a plurality of flags (7) in a flag stack (15), which is bonded to the associated external terminal (9), is materially bonded to a respectively adjoining flag (7) in a region in which the flag (7) is oriented in an inclined direction at an angle () to the surface (11) of the associated external terminal (9).