A capacitor and a method for producing a capacitor are disclosed. In an embodiment, a capacitor includes a winding having a cathode foil, an anode foil, separators arranged therebetween and a projection region in which the cathode foil projects beyond the anode foil, wherein, in the projection region, a plurality of layers of the cathode foil are arranged to form a bundle and are directly electrically connected to one another.

According to a manufacturing method of an electrolytic capacitor according to an embodiment, a fiber film, which serves as a separator, is formed on a surface of a substrate, which serves as an electrode, by ejecting a material liquid against the substrate. When the fiber film is formed, thicker fiber is formed at end parts of the substrate in a width direction, compared to a center part of the substrate in the width direction.

This disclosure relates to the manufacture an alkali metal quaternary crystalline nanomaterial. an alkali metal quaternary crystalline nanomaterial having general Formula A (I.sub.2-II-IV-VI.sub.4); and wherein I is sodium (Na) or lithium (Li), II and IV are Zn or Sn, and VI is a chalcogens selected from the group comprising: sulphur (S), selenium (Se) or tellurium (Te). The crystal phase of the alkali metal quaternary crystalline nanomaterial may be a primitive mixed Cu—Au like structure (PMCA) and may have a space group: P42m. The nanomaterials may be adapted to provide a solar cell. Methods of manufacture are also provided.

A capacitor (2) includes a capacitor main body (4), a base (6), and a resin layer (8-1). The capacitor main body includes an outer package case (10), an opening sealing member (14) attached to an opening of the outer package case, and a terminal lead (16-1, 16-2) extending through the opening sealing member. The base is disposed toward the opening sealing member of the capacitor main body and includes an insertion through hole (18-1, 18-2) into which the terminal lead is inserted to be exposed on a mounting surface side, and a protruding portion (20) surrounding the insertion through hole. The resin layer is arranged at least between the base and the opening sealing member. The base and the resin layer are in contact with or spaced apart from each other without at least partly adhering to each other.

A capacitor and a method of processing an anode metal foil are presented. The method includes electrochemically etching the metal foil to form a plurality of tunnels. Next, the etched metal foil is disposed within a widening solution to widen the plurality of tunnels. Exposed surfaces of the etched metal foil are then oxidized. The method includes removing a section of the etched metal foil, where the section of the etched metal foil includes exposed metal along an edge. The section of the etched metal foil is placed into a bath comprising water to form a hydration layer over the exposed metal on the section of the etched metal foil. The method also includes assembling the section of the etched metal foil having the hydration layer as an anode within a capacitor.

A miniaturization process of passive electronic components is revealed. The miniaturization process mainly includes the steps of reforming, reacting at high temperature, preparing paste, dipping in the paste, light curing, packaging, heat curing, cutting pins, coating silver paste, heating and drying, and engraving by laser. The miniaturization process makes production of the passive components with thinner, smaller, and lightweight deign easier and the more convenient. The service life of the passive components is also extended and applications of the passive components are broader.

A capacitor array that includes a plurality of solid electrolytic capacitor elements each of which has a first main surface and a second main surface facing each other in a thickness direction and includes an anode plate made of a valve action metal, a porous layer on at least one surface of the anode plate, a dielectric layer on a surface of the porous layer, and a cathode layer on a surface of the dielectric layer and including a solid electrolyte layer; a first sealing layer in a sheet-like shape and covering the first main surface of the plurality of solid electrolytic capacitor elements; and a second sealing layer in a sheet-like shape and covering the second main surface of the plurality of solid electrolytic capacitor elements.

When manufacturing an electrode for an electrolytic capacitor, in a first hydration step (ST1), an aluminum electrode is immersed in a first hydration processing solution having a temperature of at least 70° C. and comprising pure water or an aqueous solution to which phosphoric acid or a phosphate has been added so that the phosphorus concentration is no greater than 4 mass ppm. In a second hydration step (ST2), the aluminum electrode is immersed in a second hydration processing solution to which phosphoric acid or a phosphate has been added so that the phosphorus concentration is 4-5000 mass ppm, the second hydration processing solution having a pH of 3.0-9.0 and a temperature of at least 70° C. In a chemical conversion step (ST3), at least a boric acid chemical conversion process in which the aluminum electrode is chemically converted in a boric acid-based chemical conversion solution is included, and a chemical conversion coating having a coating withstand voltage of at least 200 V is formed on the aluminum electrode.

An electrolytic capacitor includes a capacitor element and a liquid component. The capacitor element includes an anode body that includes a dielectric layer on a surface of the anode body and a conductive polymer that covers a part of the dielectric layer. The liquid component includes a first solvent and a polyalkylene glycol component. The first solvent contains at least a glycerin component.

A capacitor assembly package structure and a method of manufacturing the same are provided. The capacitor assembly package structure includes a capacitor unit, an insulative package body, a conductive connection layer and an electrode unit. The capacitor unit includes a plurality of capacitors, and each capacitor includes a positive portion and a negative portion. The insulative package body partially encloses the capacitors, and the positive portion has a positive lateral surface exposed from a first lateral surface of the insulative package body. The conductive connection layer is electrically connected to the negative portion. The electrode unit includes a first electrode structure and a second electrode structure. The first electrode structure encloses a first portion of the insulative package body and electrically connects to the positive portion, and the second electrode structure encloses a second portion of the insulative package body and electrically connects to the conductive connection layer.