A retention structure which provides both soldering and vibration stabilization of a capacitor as the capacitor is mounted to a printed circuit board (PCB) of an electronic module. An aperture is part of the PCB to stabilize and prevent the capacitor from rolling during manufacturing. Once secured to the PCB, Room Temperature Vulcanization (RTV), or similar adhesive bead, is placed onto a rigidizer or base plate (typically a casted or aluminum sheet plate). Once the capacitor is soldered in place and fixated on the PCB, the assembly is then placed onto the rigidizer such that the PCB is attached to the rigidizer using an adhesive, and the RTV bead contacts and is deformed by the capacitor, connecting the capacitor to the rigidizer to provide vibration stabilization support. The electronic module includes a cover, and optional dampening/constraint pads are attached to the cover of the electrolytic capacitor for additional vibration stabilization.

A capacitor is described. The capacitor comprises a first casing member having a first face wall extending to a first surrounding sidewall in turn extending to a first annular edge defining a first open end. A second casing member has a second face wall extending to a second surrounding sidewall in turn extending to a second annular edge defining a second open end. The second casing member is supported on the first annular edge to thereby close the first open end of the first casing member and provide a first capacitor enclosure comprising the first and second casing members in a stacked relationship. A cover is secured to the second annular edge to close the second casing member and provide a second capacitor enclosure. An anode, for example of tantalum, and a cathode active material, for example of ruthenium oxide, reside in capacitive association with each other inside each of the first and second capacitor enclosures. A working electrolyte is also contained in the capacitor enclosures. Finally, leads extend from each anode through insulative seals structures supported by the casing members for making electrical connection to the capacitor.

An electrolytic capacitor module for installation in a housing of a motor vehicle control device, a method for producing an LC module and a corresponding motor vehicle control device with an electrolytic capacitor module. The electrolytic capacitor module includes a cylindrical electrolytic capacitor with a capacitor can and a cover at each end of the can. The covers secure a capacitor winding inside the capacitor can. The electrolytic capacitor module also has a support plate with a chamber for accommodating the electrolytic capacitor. The capacitor can has at least one opening and, on the inside of the electrolytic capacitor, the interstice between the inner wall of the capacitor can and the capacitor winding is at least partially filled with casting compound. The capacitor is at least partially surrounded by the same casting compound on the outside thereof in the region of the chamber.

An electrolytic capacitor module for installation in a housing of a motor vehicle control device, a method for producing an LC module and a corresponding motor vehicle control device with an electrolytic capacitor module. The electrolytic capacitor module includes a cylindrical electrolytic capacitor with a capacitor can and a cover at each end of the can. The covers secure a capacitor winding inside the capacitor can. The electrolytic capacitor module also has a support plate with a chamber for accommodating the electrolytic capacitor. The capacitor can has at least one opening and, on the inside of the electrolytic capacitor, the interstice between the inner wall of the capacitor can and the capacitor winding is at least partially filled with casting compound. The capacitor is at least partially surrounded by the same casting compound on the outside thereof in the region of the chamber.

A capacitor includes a capacitor element having electrode foils on the anode side and the cathode side laminated via separators, connecting parts of terminal components being disposed inside a laminated portion of the electrode foils and the separators, the connecting parts being connected to the electrode foils on the anode side and the cathode side; and a case that includes a storage part storing the capacitor element and having an opening portion sealed by a sealing body, that has a crimped part crimped from the outside of the storage part toward a side surface of the capacitor element, and that holds the capacitor element with the crimped part. The case is crimped to form the crimped part while avoiding a position at which the electrode foils of the capacitor element in the storage part overlap with tip portions of the connecting parts of the terminal components.

A capacitor that includes: a capacitor layer including a first electrode layer and a second electrode layer facing each other in a thickness direction with a dielectric layer interposed therebetween; and a coaxial through-hole conductor penetrating through the capacitor layer in the thickness direction, wherein the coaxial through-hole conductor includes: a first through-hole conductor electrically coupled to an end surface of the first electrode layer; and a second through-hole conductor inside the first through-hole conductor and electrically coupled to the second electrode layer, wherein the first through-hole conductor and the second through-hole conductor are insulated from each other.

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 wet electrolytic surface mount capacitor has a body defining an interior area and having a fill port formed through a wall of the body. A capacitive element is positioned in an interior of the body and is isolated from the body. A surface mount anode termination is in electrical communication with the capacitive element and isolated from the body. A surface mount cathode termination is in electrical communication with the body. An electrolyte is contained in the interior area of the body, and is introduced into the interior area of the body through the fill port. A fill port plug is positioned adjacent the fill port. A fill port cover compresses the fill port plug against the fill port to seal the fill port, and may be welded in place. A method of forming the capacitor is also provided.

A wet tantalum capacitor of a dual anode design is described. The anodes are housed in their own casing compartments, which are separated from each other by an intermediate partition. Preferably, the casing comprises two clamshell-shaped members that house respective anodes. The clamshells face each other, but are prevented from direct contact by the intermediate partition. The clamshells are welded to opposite sides of the partition to hermetically seal the casing. Prior to sealing, however, cathode active material is contacted to inner face walls of the clamshells and the opposite sides of the partition. The cathode active material is aligned in a face-to-face relationship with major surfaces of the anodes. Preferably, a polymeric restraining device prevents the anode from contacting the case. The hermetically sealed casing is filled with electrolyte thru a port. The fill port is hermetically sealed to complete the capacitor.

A wet tantalum capacitor of either a single anode design or of multiple anode configurations having cathode active material supported on the casing and sealed in its own separator material is described. The separator covers' the cathode active material and is adhered directly to the casing. For a multiple anode design, an inner cathode foil positioned between opposed anode pellets is sealed in its own separator bag. Preferably, a polymeric restraining device prevents the anode from contacting the casing. The completed anode/cathode electrode assembly is sealed in the casing, which is filled with electrolyte thru a port. The fill port is hermetically sealed to complete the capacitor.