Abstract: A solid electrolytic capacitor has a molded casing containing therein a capacitor element, a first lead member connected to its anode and a second lead member connected to its cathode through a fuse. The second lead member is designed such that a relatively large capacitor element can be contained inside the casing although it must also have a large enough hole to allow a portion of the casing to penetrate therethrough to fasten it to the casing.

Abstract: A capacitor has a bottomed outer casing housing a capacitor element therein, a lid closing the bottomed outer casing and having a pair of insertion holes defined therein, and a pair of electrode terminals mounted on the lid and connected to the extension leads. The capacitor element includes a plurality of current collectors with respective extension leads extending therefrom. Each of the electrode terminals has an insert inserted in one of the insertion holes with an insulator interposed between the insert and the lid, a flange contiguous to an end of the insert and held against a surface of the lid through the insulator, a joint projecting from the flange and connected to the extension lead, and a staked member contiguous to an opposite end of the insert and crimped over an opposite surface of the lid with the insulator interposed between the staked member and the lid.

Abstract: A basic cell for an electric double layer capacitor has a pair of polarizing electrodes each including a plurality of chip electrodes arranged in matrix or honeycomb pattern. The plurality of chip electrodes are electrically connected by direct contact between each adjacent two chip electrodes for increasing the capacitance and decreasing the internal resistance. Excellent charging or discharging characteristic can be obtained even if the sheet collectors for providing charging or discharging current for the chip electrodes have different specific resistivities along the surface of the sheet collectors. The chip electrodes may be of a truncated pyramid shape for improving resistance against distorting or bending stress applied to the basic cell.

Abstract: A method and assembly are provided for mounting a solid electrolytic capacitor onto a printed circuit board including an anode pad and a cathode pad. The capacitor includes a capacitor element which has an anode and a cathode electrically separated by a dielectric substance. The cathode includes an outer cathode terminal layer formed over the element. The method includes the steps of removing a part of the cathode terminal layer to expose a flat anode terminal surface, attaching the element to the printed circuit board for bringing the cathode terminal layer into electrical connection with the cathode pad, electrically connecting the flat anode terminal surface to the anode pad via a metal wire, and enclosing the element in a resin member for protection.

Abstract: An encapsulated solid electrolytic capacitor has an anode lead terminal, a cathode lead terminal, a capacitor element and a mold which is made of a synthetic resin material and encapsulates the capacitor element entirely. The capacitor element has an anode bar protruding longitudinally from a main body and is disposed between the anode lead terminal and the cathode lead terminal with the main body being electrically connected to the cathode lead terminal. The tip of the anode bar is welded to the anode lead terminal. The anode lead terminal has integrally formed with it a raised part which is L-shaped as seen longitudinally and is capable of having the anode bar inserted under its middle part, preventing it from becoming bent when it is soldered.

Abstract: A fixing part having a room in which a metal attachment leg is inserted to attach a capacitor unit is disposed on an outside face of a case. An electrode connected to a terminal of a capacitor element is disposed in the fixing part, and a lock part to be engaged with the inserted metal attachment leg is disposed, whereby when the metal attachment leg is inserted into the fixing part, the electrode of the fixing part is electrically contacted to the metal attachment leg by elasticity.

Abstract: A terminal element for compensating length tolerances of electrical capacitors, particularly electrolyte capacitors, that are secured to busbars in capacitor batteries is fashioned as a straddling dowel. The terminal element is attached as a length-compensating element in a blind hole located in the capacitor terminal.

Abstract: A package for electronic circuits can be made using a bottom plate, a top plate, and side walls which are stick capacitors. The top and bottom plates can be used as two of the terminations for the electronic circuit to provide a low impedance connection for heavy currents. The contact areas of the stick capacitor are bonded to the top and bottom plates, such as by reflow soldering. The top and bottom plates and the stick capacitor side walls provide a completely enclosed equivalent of a Faraday shield for superior EMI enclosure. Although the top and bottom are isolated electrically at DC by the dielectric layers of the capacitor, they are effectively short circuited at higher AC frequency. The stick capacitors can be drilled through to provide for additional conductors to the electronic circuit. In another embodiment of the invention, a stiffener for a printed circuit board comprises a stick capacitor as a filler for a laminated beam in which the top and bottom stress members are conductors.

Abstract: A circuit is provided which incorporates a solid electrolytic capacitor between a power source and a load. The capacitor comprises: a capacitor element including a chip body and an anode wire projecting from the chip body; an anode lead electrically connected to the anode wire; a cathode lead paired with the anode lead and electrically connected to the chip body; an auxiliary lead separate from the anode and cathode leads; a resin package enclosing the capacitor element, part of the anode lead, part of the cathode lead, and part of the auxiliary lead; and a fuse wire for electrically connecting the auxiliary lead to the anode lead within the resin package. Each of the anode, cathode and auxiliary leads has an inner end located in the resin package, and an outer end projecting from the resin package. Further, the anode lead of the capacitor is electrically connected to the power source without intervention of any other electronic element.

Abstract: A cover arrangement is intended for the pressure-tight closure of a capacitor can for electrolytic capacitors. The cover arrangement contains a cover part having at least one aperture, at least one connecting element inserted into the aperture in the cover part, and a valve element inserted into a further aperture in the cover part in a gas-tight manner. In order to produce a temperature-resistant and chemically-resistant cover arrangement which is of simple construction and can thus be produced cost-effectively, the cover part has a hard-paper core coated externally with respect to the can with an elastomerically flexible sealing layer and internally with respect to the can with a chemically resistant material layer. An elastomeric molding is arranged on the inside of the cover part which has at least one aperture aligned with each aperture in the cover part.

Abstract: Respective arc-shaped portions of two cathode lead terminals are arranged in opposition across a capacitor element to surround the side periphery of the capacitor element. These arc-shaped portions have straight portions at respective one open ends, which straight portion extends in axial direction of the capacitor element, namely in a direction along which an anode lead terminal provided on the end face of the capacitor element extends. The straight portions of the cathode lead terminals also arranged in opposition across the capacitor element. Accordingly, two straight portions of the cathode lead terminals are aligned across the anode lead terminal. By this, a three-terminal dip type capacitor which can achieve high reliability of connection between the cathode lead terminals and the capacitor element and reduction of production cost.

Abstract: A solid electrolytic capacitor comprises a capacitor element including a chip body and an anode wire projecting from the chip body, an anode lead electrically connected to the anode wire, a cathode lead paired with the anode lead, a first fuse wire connecting electrically between the chip body and the cathode lead, and a resin package enclosing the capacitor element, part of the anode lead, part of the cathode lead, and the first fuse wire. The capacitor further comprises an auxiliary lead separate from the anode and cathode leads, and a second fuse wire for electrically connecting the auxiliary lead to one of the chip body and the anode lead within the resin package. In an alternative embodiment, there is only a single fuse wire, the fuse wire acting both as a temperature fuse and as an overcurrent fuse.

Abstract: A polygonal capacitor including a polygonal capacitor case having an engaging portion at an inner surface thereof; a capacitor element accommodated in the polygonal capacitor case; a plurality of terminals respectively connected to a plurality of electrodes of the capacitor element through a base portion of each terminal; an insulating terminal base to which the terminals are fixed; and a resin filled in the polygonal capacitor case. An engaging member formed at the insulating terminal base is in pressure contact with the engaging portion of the polygonal capacitor case.

Abstract: The object of the invention is a lead frame for electrolytic capacitor anodes characterized by the fact that it comprises, for each anode to be connected, a tab with near its free end a window, the said window being sufficiently large to stop the rise by capillary action which can occur during manufacture of electrolytic capacitors.

Abstract: A metallized film capacitor and method of manufacture in which the tab connected to the bottom end of the wound capacitor section has insulating tape along the part of the length thereof which extends along the section and the section is within an insulating tube in the capacitor can. A second tab has one end connected to the top end of the capacitor section. A liner having a foldable section is attached to the ends of the terminal studs on the inside of the can cover and the uninsulated ends of the tabs which are connected to the terminal studs are insulated and protected from other parts of the capacitor by being sandwiched between the folded sections of the liner.

Abstract: In an electrolytic capacitor with connecting leads (6, 7) embedded in the side walls (4, 5) of a dish-shaped housing section (1) which receives a capacitor cell (18), the said leads extend at least for a portion, in the direction away from the base (2) of the dish-shaped housing section, essentially parallel to the capacitor cell, the ends (11, 12) of the connecting leads emerging into the receiving space for the capacitor cell and connected to the adjacent electrode connections (22, 23) of the capacitor cell being angled in an L shape towards the face of the capacitor cell facing away from the base of the dish-shaped housing section without making contact with each other (FIG. 6).