Fabricating a capacitor includes using a fluid jet to form a conduit in a sheet of material. A capacitor can include at least a portion of the sheet of material in an anode. In some instances, the sheet of material is porous before the fluid jet is used to form the conduit.

An electrode holder and a method for producing an electrode for an aluminum electrolytic capacitor are provided that enable prevention of exfoliation of a porous layer during chemical formation even when the porous layer is formed on an aluminum electrode so as to have a thickness of 200 micrometers or greater. When an aluminum electrode 10 having at least one surface 11 on which a porous layer 17 having a thickness of 200 micrometers or greater is formed is subjected to chemical formation in a chemical formation solution, the aluminum electrode 10 is held by an electrode holder 50. The electrode holder 50 includes: an insulating first support plate 51 configured to overlap the one surface 11 of the aluminum electrode 10; an insulating second support plate 52 configured to overlap the other surface 12 of the aluminum electrode 10; and a connecting part 53 configured to connect the first support plate 51 and the second support plate 52 to each other. A portion of the first support plate 51 that overlaps the porous layer 17 while being in contact therewith is formed with a porous member 510.

Fabricating a capacitor includes using a fluid jet to form a conduit in a sheet of material. A capacitor can include at least a portion of the sheet of material in an anode. In some instances, the sheet of material is porous before the fluid jet is used to form the conduit.

Fabricating a capacitor includes using a fluid jet to form a conduit in a sheet of material. A capacitor can include at least a portion of the sheet of material in an anode. In some instances, the sheet of material is porous before the fluid jet is used to form the conduit.

A multilayer electronic component includes: a body including internal electrodes alternately disposed with dielectric layers in a first direction, wherein when a region in which the internal electrodes overlap each other in the first direction is a capacitance forming portion, the internal electrodes include internal electrodes that are curved at end portions thereof in the capacitance forming portion and internal electrodes that are flat in the capacitance forming portion, and in a cross-section of the body in the first and second directions, (F1+F2)/D1?100 is 35 or less, where F1 is a maximum distance from an uppermost internal electrode to an uppermost flat internal electrode in the first direction, F2 is a maximum distance from a lowermost internal electrode to a lowermost flat internal electrode in the first direction, and D1 is a size of the capacitance forming portion in the first direction at the center thereof in the second direction.

A multilayer electronic component includes: a body including internal electrodes alternately disposed with dielectric layers in a first direction, wherein when a region in which the internal electrodes overlap each other in the first direction is a capacitance forming portion, the internal electrodes include internal electrodes that are curved at end portions thereof in the capacitance forming portion and internal electrodes that are flat in the capacitance forming portion, and in a cross-section of the body in the first and second directions, (F1+F2)/D1?100 is 35 or less, where F1 is a maximum distance from an uppermost internal electrode to an uppermost flat internal electrode in the first direction, F2 is a maximum distance from a lowermost internal electrode to a lowermost flat internal electrode in the first direction, and D1 is a size of the capacitance forming portion in the first direction at the center thereof in the second direction.

The electrode manufacturing system comprises a cutting device. The cutting device cuts an electrode material along one direction of the electrode material to manufacture electrodes. The electrode material comprises first sections and a second section. The first section includes an active material doped with alkali metal, and extends in the one direction. The second section is located between two adjacent first sections of the first sections. In the second section, the active material doped with alkali metal is absent. The cutting device cuts the second section.

An capacitor processing apparatus, and a method for processing a capacitor, may include a clamping module grabbing or releasing a capacitor to transport the capacitor, and processing modules matched with each other to process and test leads of the capacitor, and simultaneously perform various processes through different processing units formed in the processing modules. These various processes may include separating, bending, and cutting the leads of the capacitor. The testing and processing provided by the current invention make it is possible to process a larger amount of capacitors assembled to a capacitor assembly, and to identify and remove defective capacitors before assembly.

An capacitor processing apparatus, and a method for processing a capacitor, may include a clamping module grabbing or releasing a capacitor to transport the capacitor, and processing modules matched with each other to process and test leads of the capacitor, and simultaneously perform various processes through different processing units formed in the processing modules. These various processes may include separating, bending, and cutting the leads of the capacitor. The testing and processing provided by the current invention make it is possible to process a larger amount of capacitors assembled to a capacitor assembly, and to identify and remove defective capacitors before assembly.