An electronic device includes first and second capacitors, a case, a coil, and first to fourth conductive terminals. The first capacitor includes first and second terminal electrodes. The second capacitor includes third and fourth terminal electrodes. The case includes an accommodation recess for accommodating the first and second capacitors. The coil is separated from the first and second capacitors by a part of the case and disposed outside the accommodation recess. The first terminal is connected to the first electrode and partly disposed on a mounting-side bottom surface of the case. The second terminal is connected to one end of the coil and the second electrode and partly disposed on the surface. The third terminal is connected to the other end of the coil and the third electrode and partly disposed on the surface. The fourth terminal is connected to the fourth electrode and partly disposed on the surface.

The invention relates to a capacitive block for electrical equipment, including a housing, at least one capacitive element (5) having a first end housed in said housing and a second end (9), which is opposite to the first end (7) and which extends out of said housing, an end-stop (11), said end-stop (11) being fixed to the second end (9) of the capacitive element (5), at least one spacer (13), which butts against said end-stop (11), so as to determine the distance between the second end (9) of the capacitive element (5) and a bottom of said housing.

A capacitor includes a bus bar. The bus bar includes a bus bar body member and a terminal formation member configured to be superposed on and fixed to a terminal formation part of the bus bar body member. In the terminal formation part, a plurality of first connection terminal parts are formed so as to be arranged in one direction, by portions of the terminal formation part being cut and raised. In the terminal formation member, a plurality of second connection terminal parts are formed so as to be arranged in one direction, by portions of the terminal formation member being cut and raised, and second openings are formed in places where the portions have been cut and raised. The first connection terminal parts and the second connection terminal parts are alternately arranged in one direction, by the first connection terminal parts being passed through the second openings.

Various embodiments include a capacitor structure comprising: a plurality of capacitors disposed in a support structure, wherein each of the plurality of capacitors includes a first capacitor electrode and a second capacitor electrode. The support structure includes a first electrode and a second electrode. Each of the plurality of capacitors makes electrical contact with the first electrode via the respective first capacitor electrode and with the second electrode via the respective second capacitor electrode. The support structure includes a mounting side for surface mounting, the mounting side comprising a first contact area of the first electrode and a second contact area of the second electrode. The support structure defines a cuboid interior and the capacitors are disposed in the cuboid interior. An outer side of the support structure defines an additional structural framework outside the mounting side.

What is described is a mounting aid for mounting electrical components, in particular electrolytic capacitors or chokes, on a printed circuit board, said mounting aid comprising a body, which has compartments for receiving the electrical components, wherein the compartments have a base with openings for the insertion of connection wires of the electrical components, and metal parts fastened to the body, which metal parts each form at least one contact pin on the underside of the body and each from a busbar for connection to electrical components in a plurality of compartments of the body.

A capacitor assembly, configured for a high-voltage application, contains an active capacitor part, a housing for accommodating the active capacitor part and an insulating medium for the electrical insulation of the active capacitor part. A flexible-shape inlay is arranged between the insulating medium and the housing and connected electrically thereto. Ideally the capacitor assembly is part of a converter assembly.

An electrical connector includes a housing having contact chambers between a top and a bottom configured to be mounted to a circuit board. A rear wall of the housing includes lead slots open at the top to receive leads of an electrical component. The electrical connector includes a cover coupled to the top of the housing above the leads. The electrical connector includes contacts received in corresponding contact chambers. Each contact includes a base having a solder pad at a bottom configured to be soldered to a circuit board conductor of the circuit board. Each contact includes contact beams extending from the base to form a socket proximate to the top of the housing that receives the lead of the electrical component from above to electrically connect to the lead of the electrical component.

The invention relates to a capacitor (1), particularly an intermediate circuit capacitor for a multiphase system, having a plurality of identical capacitor elements (10), which are connected in parallel and together form the capacitor (1), wherein at least one intermediate space (20) is formed between the capacitor elements (10), at least one intermediate capacitor element (30) is arranged in the intermediate space (20) and is connected in parallel to the capacitor elements (10), and thus together with the capacitor elements (10) forms the capacitor (1).

A vacuum-capacitor-type instrument voltage transformer (1) is equipped with a main capacitor (2) and an insulating tube (3) that accommodates the main capacitor (2). A voltage dividing capacitor (4) is connected to the main capacitor (2) in series. The main capacitor (2) is equipped with a plurality of vacuum capacitors (2a) to (2c) that are connected in series. A high-voltage-side electrode (6) is provided on a high-voltage side of the insulating tube (3), and a ground-side electrode (7) is provided on its low-voltage side. The high-voltage-side electrode (6) is equipped with a high-voltage shield (8). Electrostatic capacity of the vacuum capacitor (for example, the vacuum capacitor (2a)) disposed on the high-voltage side is set to be greater than electrostatic capacity of the vacuum capacitor (for example, the vacuum capacitor (2b)) disposed on the low-voltage side.

This electricity storage module includes: a plurality of electricity storage device; a device holder; a first external output terminal and a second external output terminal which are configured to be electrically connected to the plurality of electricity storage devices; and a terminal holder having one end portion and another end portion, the one end portion being configured to have the first external output terminal attached thereto, the other end portion being configured to have the second external output terminal attached thereto. The first external output terminal includes a coupling terminal part protruding to an outer side of a terminal holder in a direction in which the first external output terminal and the second external output terminal are arranged. The second external output terminal includes an external connection terminal part capable of being connected to an external terminal or the coupling terminal part on an inner side of the terminal holder.