A heat pipe cooled capacitor includes a capacitor body having opposing first and second ends and an opening defined between the opposing ends. A first heat pipe is thermally and electrically connected to the first end of the capacitor body. A second heat pipe is positioned at least partially through the opening of the capacitor body. The second heat pipe is thermally connected to the second end of the capacitor body, and electrically isolated from the first heat pipe.

A heat pipe cooled capacitor includes a capacitor body having opposing first and second ends and an opening defined between the opposing ends. A first heat pipe is thermally and electrically connected to the first end of the capacitor body. A second heat pipe is positioned at least partially through the opening of the capacitor body. The second heat pipe is thermally connected to the second end of the capacitor body, and electrically isolated from the first heat pipe.

A capacitor is described. A casing for the capacitor has a surrounding sidewall extending to opposed first and second open ends. An inwardly extending ledge of the sidewall is intermediate the first and second open ends. A partition plate is supported on the ledge. A first lid is secured to the first annular edge to close the first capacitor compartment bounded by the partition plate, the surrounding sidewall and the first lid, and a second lid is secured to the second annular edge to close the second capacitor compartment bounded by the opposite side of the partition plate, the surrounding sidewall and the second lid. At least one anode resides in each of the first and second capacitor compartments spaced from cathode active material supported on the casing walls facing the anodes. There is also a separator intermediate the anode and cathode. Insulative seals supported by the casing electrically isolate anode leads connected to the respective anodes from the casing serving as a terminal for the cathode. Finally, a working electrolyte is provided in the first and second capacitor compartments in contact with the anodes and cathode active material.

A capacitor assembly for use in high voltage and high temperature environments is provided. More particularly, the capacitor assembly includes a capacitor element containing an anodically oxidized porous, sintered body that is coated with a manganese oxide solid electrolyte. To help facilitate the use of the capacitor assembly in high voltage (e.g., above about 35 volts) and high temperature (e.g., above about 175? C.) applications, the capacitor element is enclosed and hermetically sealed within a housing in the presence of a gaseous atmosphere that contains an inert gas. It is believed that the housing and inert gas atmosphere are capable of limiting the amount of moisture supplied to the manganese dioxide. In this manner, the solid electrolyte is less likely to undergo an adverse reaction under extreme conditions, thus increasing the thermal stability of the capacitor assembly. In addition to functioning well in both high voltage and high temperature environments, the capacitor assembly of the present invention may also exhibit a high volumetric efficiency.

A capacitor assembly for use in high voltage and high temperature environments is provided. More particularly, the capacitor assembly includes a capacitor element containing an anodically oxidized porous, sintered body that is coated with a manganese oxide solid electrolyte. To help facilitate the use of the capacitor assembly in high voltage (e.g., above about 35 volts) and high temperature (e.g., above about 175? C.) applications, the capacitor element is enclosed and hermetically sealed within a housing in the presence of a gaseous atmosphere that contains an inert gas. It is believed that the housing and inert gas atmosphere are capable of limiting the amount of moisture supplied to the manganese dioxide. In this manner, the solid electrolyte is less likely to undergo an adverse reaction under extreme conditions, thus increasing the thermal stability of the capacitor assembly. In addition to functioning well in both high voltage and high temperature environments, the capacitor assembly of the present invention may also exhibit a high volumetric efficiency.

An electric compressor includes a housing and a cover. The housing accommodates a compression portion and an electric motor. The cover is attached to an outer surface of the housing and cooperates with the outer surface of the housing to define an accommodation space. An inverter is accommodated in the accommodation space and configured to drive the electric motor. The inverter includes a circuit board, an electrolytic capacitor, and a capacitor cover at least partly covering the electrolytic capacitor. The electrolytic capacitor includes a cylindrical main body having a first end and a second end, a lead extending from the first end of the main body and connected to the circuit board, and a pressure relief vent on the second end of the main body. The capacitor cover is interposed between the circuit board and a peripheral edge of the second end of the electrolytic capacitor.

According to a hermetic terminal based on the present invention, a hermetic terminal (10) to be hermetically fixed to an aluminum electrolytic capacitor (20) includes: a base (11) which has a through hole, is to be attached to a case (16) of the aluminum electrolytic capacitor (20), and is made of a composite material having electrical conductivity; at least one lead (12) which is inserted into the through hole of the base (11), and is made of a composite material having electrical conductivity; and an insulating glass (13) which hermetically seals a gap between the base (11) and the lead (12). Surfaces of portions of the base (11) and the lead (12) which come into contact with an electrolytic solution within the case (16) are composed of a metal material having corrosion resistance to the electrolytic solution.

A capacitor having at least two side-by-side anodes with a cathode current collector disposed between the anodes and housed inside a casing is described. Cathode active material is supported on the opposed major faces of the current collector and the current collector/cathode active material subassembly is housed in a first separator envelope. The first separator envelope is positioned between the side-by-side anodes and this electrode assembly is then contained in a second separator envelope. The two anodes can be connected in parallel inside or outside casing, or they can be unconnected to each other. There is also cathode active material supported on inner surfaces of the casing in a face-to-face alignment with an adjacent one of the anodes. That way, the second separator envelope also prevents direct physical contact between the anode pellets and the cathode active material supported on the casing sidewalls.

A capacitor having at least two side-by-side anodes with a cathode current collector disposed between the anodes and housed inside a casing is described. Cathode active material is supported on the opposed major faces of the current collector and the current collector/cathode active material subassembly is housed in a first separator envelope. The first separator envelope is positioned between the side-by-side anodes and this electrode assembly is then contained in a second separator envelope. The two anodes can be connected in parallel inside or outside casing, or they can be unconnected to each other. There is also cathode active material supported on inner surfaces of the casing in a face-to-face alignment with an adjacent one of the anodes. That way, the second separator envelope also prevents direct physical contact between the anode pellets and the cathode active material supported on the casing sidewalls.

The present disclosure provides a wound capacitor package structure and a wound assembly thereof. The wound capacitor package structure includes a wound assembly, a package assembly, and a conductive assembly. The wound assembly includes a wound positive conductive foil, a wound negative conductive foil, and two wound separator papers. The package assembly is used for enclosing the wound assembly. The conductive assembly includes a first conductive pin electrically contacting the wound positive conductive foil and a second conductive pin electrically contacting the wound negative conductive foil. The wound positive conductive foil has a first predetermined width, the wound negative conductive foil has a second predetermined width, each of the two wound separator papers has a third predetermined width, and the first predetermined width of the wound positive conductive foil and the second predetermined width of the wound negative conductive foil are different.