A high current DC dispersing and converging connector comprises a dispersing and connecting terminal, a sheath I, a converging and connecting terminal and a sheath II, the dispersing and connecting terminal comprises three connecting ends I and a connecting end II; two connecting ends I are symmetrically fixed to the connecting end II; the sheath I is provided with three inserting ports I and an inserting port II; the sheath I is sleeved on an outer surface of the dispersing and connecting terminal; the tail of the connecting end II is provided with an inserting groove; the converging and connecting terminal is an umbrella-shaped copper-aluminum terminal; the sheath II is provided with two connecting ports; the sheath II is sleeved on an outer surface of the converging and connecting terminal; when the umbrella-shaped end is inserted into and fixed with the inserting groove, the inserting port II of the sheath I is inserted into and fixedly connected with the connecting port of the sheath II; and a seal ring is arranged at a contact position where the inserting port II and the connecting port are contacted. By improving the structure of the existing high current DC single-input and single-output connector, the solution reduces the convergence box, saves a connection space, makes processing more convenient, and also reduces processing time.

An electric connection member includes a busbar, a protector portion, and a cover. The busbar includes a live portion that is located between terminal connecting portions. The protector portion has a busbar mounting surface on which the live portion of the busbar is mounted, and insulates and protects the live portion. The cover is coupled to the protector portion and covers a surface of the live portion. The cover has an abutment portion that abuts against the surface of the live portion. The abutment portion includes a pressure contact surface that is in direct or indirect contact with the surface of the live portion while being pressed against the surface of the live portion in a state in which the cover is coupled to the protector portion.

In an embodiment, a multi-cell hold-down mechanism is clamped over multiple contact tabs aligned with respective cell terminals (e.g., positive and/or negative cell terminal(s). While clamped, the contact tabs are securely welded to respective cell terminals through respective gaps in the multi-cell hold-down mechanism. In another embodiment, a multi-cell hold-down mechanism is clamped over an electrically conductive part that is coupled to multiple cell rims which are configured as negative cell terminals. A respective negative contact tab is welded to the electrically conductive part through a gap in the multi-cell hold-down mechanism. In another embodiment, three (or more) battery cell terminals (e.g., positive or negative terminals) are coupled to an electrically conductive bar that is welded to a contact tab of a busbar.

Provided is a coupling structure of a bus bar equipped in a power part. The coupling structure of the bus bar includes a female type bus bar and a male type bus bar respectively coupled to different elements of the power part, wherein the female type bus bar is fitting-coupled to the male type bus bar. In the coupling structure of the bus bar, since bus bars of high voltage elements are connected to each other by a connecting method instead of a conventional bolting coupling structure, the miniaturization effect and cooling effect of an inverter may increase, and moreover, a tool used to couple bus bars may be omitted, thereby enabling power parts to be easily disposed.

A bus bar assembling structure includes a resin block main body for an electronic component block, a first bus bar, and a second bus bar. The resin block main body includes a bus bar assembling portion. The first bus bar and the second bus bar are accommodated in the bus bar assembling portion. The first bus bar has a first pushing portion that is pushed when the first bus bar is accommodated in the bus bar assembling portion, the first pushing portion being a bent piece. The first pushing portion has a through hole or a notch. The second bus bar has a second pushing portion that is inserted into the through hole or the notch and is disposed at a position corresponding to a position of a pushed surface of the first pushing portion.

A modular electrical signal supply assembly includes at least one power/data strip (PDS) configured to provide an electrical signal to an electrical device and at least one mounting clip configured to couple each PDS to a sub-floor surface structure. A vehicle includes an interior cabin with an electrical signal distribution system that includes at least one modular electrical signal supply assembly and at least one electrical devices. Each modular electrical signal supply assembly includes a PDS and a mounting clip. Each PDS is configured to provide an electrical signal to an electrical device and is electrically coupled to at least one other PDS.

The present disclosure provides a busbar (100), comprising: an insulating body (110); and a busbar conductor (120, 130, 140) comprising a conductor body partially encapsulated by the insulating body and a connection terminal (121, 131, 141) extending from the conductor body and configured for connecting an electrical device, and a portion of the connection terminal is surrounded by an insulating structure (10). The present disclosure further provides a power module (200) comprising the busbar and a method of manufacturing a busbar.

The object of the invention is an electrical device comprising: a housing comprising a cavity receiving an electronic component, and at least one first electrical conductor connected to the electronic component so as to supply it with electric power, said electrical device being characterised in that it comprises a first electrically insulating film being against a surface of the first conductor so as to electrically insulate it, said first insulating film having at least one holding member enabling the first insulating film to be attached to a mechanical element, in particular of the electrical device.

A busbar module includes a busbar holding plate and a busbar cover attached to the busbar holding plate. The busbar holding plate includes a busbar holding face and a bearing including a hole and a wall to define the hole. The busbar cover includes protrusions protruding toward each other in the axial direction at positions corresponding to the hole. The protrusions are opposed to each other with a gap less than a dimension of the hole in the axial direction. The protrusions are disposed in the hole to rotate the busbar cover about the protrusions between a covering position and an uncovering position. The busbar cover is flexible to deform such that the gap expands to allow the wall to pass through the gap during attachment of the bulbar cover to the busbar holding plate and restores its original shape when passing of the wall through the gap is complete.

A bussing connector is provided and includes bus bar connections, output elements and dielectric material. The bus bar connections each include an output section and an input section. The input sections cooperatively form a multiphase alternating current (AC) input. The output elements are arranged along and in electrical communication with the output sections of each of the bus bar connections. The dielectric material is configured to partially surround and partially electrically insulate the input and output sections and the output elements of each of the bus bar connections. The dielectric material is further configured to expose the multiphase AC input and portions of each of the outlet elements of each of the bus bar connections.