A first and second substrate, and electrically conductive first and second connection parts are provided in a method for establishing an electrically conductive connection between two substrates. The first connection part is mounted on the first substrate by a first releasable connection and the second connection part is respectively mounted on the second substrate by a releasable connection. An electrically conductive connection assembly containing the first connection part and the second connection part is established by either a cohesive connection between a connection portion of the first connection part and a connection portion of the second connection part or an electrically conductive crossmember provided and a cohesive connection of a first length portion of the crossmember to the connection portion of the first connection part and a second cohesive connection of a second length portion of the crossmember to the connection portion of the second connection part being established.

An objective of the present invention is to provide a conductor connecting structure which may enable miniaturization in the height direction. A conductor connecting structure is intended for connecting a conductor to an electric wire with a plurality of strands, wherein the conductor has a plate shape, and wherein it is configured so that the plurality of strands is butt-connected to an end face of the conductor, the plurality of strands having a same plate shape as the end face of the conductor in advance. This enables the electric wire to be connected to the end face of the conductor by configuring the plurality of strands constituting the electric wire in the same plate shape as the end face of the conductor in advance. This may enable the miniaturization in the height direction.

A semiconductor module includes a resin case housing a semiconductor element; an insulating layer extending outward from the resin case; and a first external connection terminal extending outward from the resin case, arranged above the insulating layer so as to face the insulting layer, the first external connection terminal having a non-contact portion that is not in contact with the insulating layer in a thickness direction of the insulating layer at a position overlapping the insulating layer in a plan view.

A braided part connection structure includes a braided part having a tubular shape covering an insulated wire along a longitudinal direction of the braided part connection structure and a shield member having a tubular shape and electrically connected and fixed to the braided part. The shield member includes a braided part joining portion having a plurality of openings arranged at intervals along a circumferential direction of the shield member in a portion of the shield member in the longitudinal direction, and a welding portion defined by two openings adjacent to each other of the plurality of openings. The braided part covers the braided part joining portion and is welded to the welding portion.

An electrical connector includes an inner signal contact, an outer shielding contact, and a cover. The outer contact has a crimping portion including a first crimp wing and a second crimp wing that are bendable towards each other to attach the outer shielding contact to a cable such that ends of the first crimp wing and the second crimp wing extend towards each other when the outer shielding contact is attached to the cable. The cover is configured to cover a braid or a protective layer of the cable that is arranged underneath the ends of the crimp wings when the outer shielding contact is attached to the cable.

A power socket includes a power socket body extending between a first end and a second end and having a tube being tubular shaped along at least a portion of the power socket body. The power socket includes a power pin termination at the first end and a cable termination at the second end. The power pin termination includes a socket configured to receive a mating end of a power pin and a spring band contact received in the socket having a plurality of mating interfaces. A first edge of the power socket body is rolled inward to form a retaining lip to retain the spring band contact in the socket. The cable termination includes a deformation terminated to an end of a cable conductor of a cable to electrically connect the power socket to the cable. The deformation transforms the tube from a tubular to a deformed shape.

An electric energy transmission aluminum part, an aluminum connector and a copper-aluminum joint. The electric energy transmission aluminum part includes an aluminum body (1) internally provided with a conical insertion hole (11) which penetrates through front and rear ends thereof. The conical insertion hole is provided with a maximum diameter end and a minimum diameter end. Both the aluminum connector and the copper-aluminum joint include the electric energy transmission aluminum part. The electric energy transmission aluminum part, the aluminum connector and the copper-aluminum joint not only avoid an insulation layer (3) from being crimped into a lead portion and increasing a resistance of the lead portion, but also prevent an indentation from being formed on the surface of the insulation layer (3) and causing breakdown, and further reduce an interference with a mating end environment, thus achieving a wide application range. In addition, the copper-aluminum joint can also save the processing working hours and resources.

A battery module includes a plurality of pouch-type secondary batteries arranged to be stacked in at least one direction, each secondary battery having an electrode lead, and a bus bar made of an electrically conductive material and bonded to at least two electrode leads of corresponding secondary batteries to electrically connect the corresponding secondary batteries to each other. Each bonded electrode lead may be configured to protrude from the corresponding secondary battery in a front and rear direction, and at least one of left and right side surfaces of each bonded electrode lead may be bonded to the bus bar.

A fixing structure of a splice part includes a plurality of electrical wires each having a splice part and mutually connected and a sheet material to which the splice part is fixed. The fixing structure of the splice part is considered to have a portion of the plurality of electrical wires fixed to the sheet material in addition to the splice part.

A signal connector positioning structure comprises a connector, a connecting component, a conductive connecting component, and a insulating component; the connector has a first opening, a second opening, and a first fixing structure; the connecting component has a first connection port and a first fixing component; the conductive connecting component has an opening; the insulating component has an opening; the conductive connecting component penetrates through the insulating component; wherein, the first fixing structure and the first fixing component are removably fastened in a screwed manner.