Provided is an energy storage apparatus including: a neighboring member disposed adjacently to an energy storage device; and a terminal member disposed adjacently to the neighboring member on a side opposite to the energy storage device, wherein the terminal member has: a body extending along the neighboring member; and a bolt member having a head portion and a shaft portion extending from the head portion, and mounted on the body in a state where the shaft portion is made to pass through the body from a neighboring member side, the neighboring member has a protruding portion protruding in an axial direction of the shaft portion, and the protruding portion is inserted into the body at a position where at least a portion of the protruding portion overlaps with a projection region of the shaft portion in the axial direction.

Polyphase electrical machine with n phases, n≥3, including a casing defining a longitudinal axis, a stator and a rotor including a mechanical drive shaft, the electrical machine being equipped with a power electronics and a coolant circuit and the power electronics is formed of n power electronic modules evenly distributed over an inner circumference of a longitudinal extension of the casing whose outer circumference is covered with a single annular DC bus decoupling capacitor electrically connected to the n power electronic modules, the coolant circuit including a plurality of U-shaped tubes with a tubular outgoing part extending over an entire length of the casing and including the longitudinal casing extension and a shorter tubular return part, extending over a casing length excluding the longitudinal casing extension.

A power storage device includes: a power storage stack which includes a plurality of power storage cells; a heating member that heats the power storage stack; a cooling member that cools the power storage stack; a first pressing member that presses the heating member against the power storage stack; a second pressing member that presses the cooling member against the power storage stack; and a sheet member covering the bottom of the power storage stack so that an enclosed space is formed between the sheet member and the power storage stack in a cross section of the power storage stack, wherein the sheet member has a first surface and a second surface, the cooling member is disposed on the first surface, within the enclosed space, and the heating member is disposed on the second surface, on an outer side of the enclosed space.

A capacitor includes a capacitor element, a bus bar connected to an electrode of the capacitor element, a case housing the capacitor element, and a filling resin filled in the case. The bus bar includes a first section and a second section. The first section is exposed from the filling resin and includes a connection terminal configured to be connected to an external terminal. The second section has a buried section buried in the filling resin and an exposed section exposed from the filling resin, and includes a connection part connected to the electrode. The exposed section is located away from the first section.

A capacitive block includes at least one capacitive element, a first electrical conductor that includes at least one electrically conductive plate abutting a first end of the at least one capacitive element so as to be electrically connected to the at least one capacitive element, and a first frame made of electrically insulating material coming into register with a peripheral edge of the at least one electrically conductive plate so as to electrically insulate the at least one electrically conductive plate from an environment of the capacitive block.

A wet capacitor is provided, and the use of an insulation fluid composition in such a capacitor. The capacitor includes a package of a metal foil and a polymeric insulating film, or of a metallized polymeric film, wherein the insulation composition includes a synthetic or natural aromatic oil and a polymer. The insulation composition is configured to undergo a thermo-reversible oil-to-gel transition at a predefined gel-point temperature. Further, methods of producing such wet capacitors are provided, optionally including additional filling materials, and methods of sealing leaks in such capacitors.

A winding-type capacitor package structure and a method of manufacturing the same are provided. The winding-type capacitor package structure includes a winding assembly, a package assembly, a conductive assembly, and a bottom carrier frame. The winding assembly includes a positive winding conductive foil and a negative winding conductive foil. The winding assembly is enclosed by the package assembly. The package assembly includes a casing structure and a filling body received inside the casing structure. The casing structure has an inner rough surface. The bottom carrier frame is disposed on a bottom portion of the casing structure. The filling body includes a plurality of layered structures, and each of the layered structure is connected between the winding assembly and the casing structure. Therefore, the filling body including the layered structures can be limited inside the casing structure through friction force provided by the inner rough surface.

A winding capacitor package structure and a method of manufactured the same are provided. The winding capacitor package structure includes a winding assembly, a package assembly, a conductive assembly, and a bottom carrier frame. The winding assembly includes a winding positive foil and a winding negative foil. The winding assembly is enclosed by the package assembly. The package assembly includes a casing structure and a filling body received inside the casing structure. The casing structure includes a main casing for enclosing the filling body and a retaining body inwardly bent from a bottom side of the main casing. The filling body includes a plurality of layered structures, and each of the layered structure is connected between the winding assembly and the casing structure. Therefore, the filling body including the layered structures can be retained and limited inside the casing structure through the retaining body.

In an embodiment, an energy storage apparatus includes a plurality of energy storage devices arranged in a first direction and a pair of insulators extending in the first direction along the plurality of energy storage devices and arranged at an interval from each other in a second direction orthogonal to the first direction, and each of the plurality of energy storage devices has an outer surface facing a third direction orthogonal to the first direction and the second direction, and each of the pair of insulators has a space forming part extending from a position on the outer surface in the first direction and the third direction, and forming a space between a facing surface, on which the energy storage apparatus is installed, and the outer surface.

An electronic control unit for a vehicle. The electronic control unit is defined by a housing comprising a cover, a base, a circuit board, a connector and a backup power supply, and means for mounting the cover to the base. A carrier is provided for supporting the backup power supply. The carrier is arranged inside the housing and mounted directly to the base.