A solid electrolyte capacitor includes a bottomed cylindrical housing having a bottom surface portion, a side surface portion raised from the bottom surface portion and an opening portion formed on an end portion of the side surface portion; a capacitor element housed in the inside of the housing, the capacitor element being formed by winding an anode foil and a cathode foil in an overlapping state with a separator interposed therebetween and by filling a solid electrolyte between the anode foil and the cathode foil; and a sealing member sealing the opening portion of the housing in a state where the capacitor element is housed in the inside of the housing, wherein an oxide film repairing body made of a hydrophilic synthetic resin is disposed at least one of between the bottom surface portion and the capacitor element of the housing and between the capacitor element and the sealing member.

A solid electrolytic capacitor that includes a capacitor element having a linear through conductor made of a valve function metal, a dielectric layer disposed on the through conductor, and a cathode-side functional layer disposed on the dielectric layer. The through conductor includes a core portion and a porous portion covering a peripheral surface of the core portion. Both end faces of the core portion of the through conductor are in contact with a pair of anode terminals on the pair of end faces of the body, respectively. A cathode terminal is electrically connected to the cathode-side functional layer.

An energy storage apparatus includes an outer case, and an energy storage device housed in an inside of the outer case. The outer case includes a ventilation chamber which makes the inside and an outside of the outer case communicate with each other. The ventilation chamber includes a front wall in which a through hole communicating with the outside is formed, a back wall disposed at a position where the back wall opposedly faces the front wall, a first wall disposed between the through hole and the back wall, and a first side wall disposed in an extending manner along a first direction which intersects with the front wall with a gap formed between the first side wall and the first wall. The gap is formed over a distance from the front wall to the back wall along the first direction.

An energy storage apparatus includes an outer case, and an energy storage device housed in an inside of the outer case. The outer case includes a ventilation chamber which makes the inside and an outside of the outer case communicate with each other. The ventilation chamber includes a front wall in which a through hole communicating with the outside is formed, a back wall disposed at a position where the back wall opposedly faces the front wall, a first wall disposed between the through hole and the back wall, and a first side wall disposed in an extending manner along a first direction which intersects with the front wall with a gap formed between the first side wall and the first wall. The gap is formed over a distance from the front wall to the back wall along the first direction.

A hermetically sealed capacitor and method of manufacturing are provided. The hermetically sealed capacitor includes an anode element having an anode wire and a feed through barrel, a cathode element, a first case portion having a first opening portion and a second case portion having a second opening portion. The first and second opening portions form an opening configured to mate with the feed through barrel. The first opening portion may include a slot portion configured to receive the feed through barrel. The hermetically sealed capacitor may also include electrolytic solution disposed between the first and second case portions.

A hermetically sealed capacitor and method of manufacturing are provided. The hermetically sealed capacitor includes an anode element having an anode wire and a feed through barrel, a cathode element, a first case portion having a first opening portion and a second case portion having a second opening portion. The first and second opening portions form an opening configured to mate with the feed through barrel. The first opening portion may include a slot portion configured to receive the feed through barrel. The hermetically sealed capacitor may also include electrolytic solution disposed between the first and second case portions.

A solid electrolytic capacitor comprising a capacitor element disposed on an insulating substrate, in which a positive electrode lead-out structure electrically connected to a positive electrode member of the capacitor element comprises a first positive electrode connection member disposed on the insulating substrate, a positive electrode terminal disposed on the insulating substrate, a pillow member configured to electrically connect the positive electrode member to the first positive electrode connection member, and a positive electrode bonding member. The first positive electrode connection member has a recessed portion or a through hole. The positive electrode bonding member partially enters the recessed portion or the through hole, and is in contact with an edge of a bottom surface of the pillow member at a position above the recessed portion or the through hole, or at the nearby position.

A solid electrolytic capacitor comprising a capacitor element disposed on an insulating substrate, in which a positive electrode lead-out structure electrically connected to a positive electrode member of the capacitor element comprises a first positive electrode connection member disposed on the insulating substrate, a positive electrode terminal disposed on the insulating substrate, a pillow member configured to electrically connect the positive electrode member to the first positive electrode connection member, and a positive electrode bonding member. The first positive electrode connection member has a recessed portion or a through hole. The positive electrode bonding member partially enters the recessed portion or the through hole, and is in contact with an edge of a bottom surface of the pillow member at a position above the recessed portion or the through hole, or at the nearby position.

An energy storage device includes an electrode assembly, a case, a terminal part, and a current collector, wherein the terminal part has: an external terminal having at least a part exposed to outside of the case; a conduction member configured to make the external terminal and the current collector conductive; a decoupling mechanism configured to decouple the conduction member, or hinder a conduction state of the conduction member; and an auxiliary terminal disposed spaced from the external terminal, and having at least a part exposed to the outside of the case, the auxiliary terminal being electrically connected to the current collector.

A solid electrolytic capacitor that includes a resin molding, a first external electrode, and a second external electrode. The resin molding includes a laminate of multiple capacitor elements, and a sealing resin sealing the laminate. The following are satisfied: t.sub.1<t.sub.2, t.sub.3<t.sub.4, t.sub.1<t.sub.3, and t.sub.4/t.sub.3<t.sub.2/t.sub.1, where t.sub.1 is the thickness of an inner portion of the cathode lead-out layer, the inner portion not being exposed at the second end surface; t.sub.2 is the thickness of an exposed portion of the cathode lead-out layer, the exposed portion being exposed at the second end surface; t.sub.3 is the thickness of an inner portion of the valve-action metal substrate, the inner portion not being exposed at the first end surface; and t.sub.4 is the thickness of an exposed portion of the valve-action metal substrate, the exposed portion being exposed at the first end surface.