An electrical connector assembly includes an electrical terminal attached to a wire cable, a connector housing defining a cavity in which the electrical terminal is disposed, and a resilient damping element disposed intermediate the electrical terminal and an inner wall of the cavity. The damping element is configured to reduce the amplitude and/or change the frequency of vibratory mechanical energy transmitted to the electrical terminal in the electrical connector through the wire electrical cable attached to the terminal.

Provided are a charging gun cooling system and a charging gun, relating to the technical field of charging guns. In the charging gun cooling system, a head cooling assembly includes a support frame and a cooling cavity, the cooling cavity is provided with a liquid inlet and a liquid outlet, the support frame is configured to accommodate a connection end of a first terminal and a connection end of a second terminal, the cooling cavity is disposed in the support frame and between the first terminal and the second terminal, a liquid inlet pipe communicates with the liquid inlet, a liquid outlet pipe communicates with the liquid outlet, a first cable is laid on the outer surface of the liquid inlet pipe, and a second cable is laid on the outer surface of the liquid outlet pipe.

A photovoltaic assembly comprising: (a) at least two photovoltaic components that are adjacent to each other, each photovoltaic component comprising: (i) a partial connector channel in communication with a partial connector channel in an adjacent photovoltaic component and (ii) one or more connector receptors; (b) a connector located at least partially in the partial connector channel of the photovoltaic component and at least partially in the partial connector channel of the adjacent photovoltaic component so that the connector connects the photovoltaic component to the adjacent photovoltaic component, the connector comprising: a housing having: (1) a top housing and (2) a bottom housing, wherein the top housing and the bottom housing each include a first end and a second end; one or more flexible electrical conductors that extend from the first end to the second end; wherein the top housing and the bottom housing each include one or more mechanical flexing regions that allow the housing to mechanically flex.

Power socket extension lead

An extension lead having a body provided with at least one power socket area for receiving connecting plugs of the “Schuko” type, and having inside it electrical connection means, and a cable for connecting to the electrical power network with a connecting plug at its end that exits from the said body, characterised in that the body has externally two flexible covers, one upper cover and one lower cover, which form an internal cavity that encircles the said body and allows the electrical power network connecting cable to be housed in wound form.

An electronic connector includes a housing and a plug extending from the housing. The plug includes at least one flexible region that provides flexing of the plug. In some example embodiments, the plug also includes at least one rigid region. The plug has at least one interconnect. Each interconnect includes a lead and a contact. The contacts are exposed on an exterior surface of the plug, such exposure being provided so as to enable electrical coupling between the plug and an electronic receptacle into which the plug may be removably inserted.

A circuit board with circuit components mounted thereon is integrally molded with a sealing resin having a sealed end face part that is a thermosetting resin. A cylindrical intermediate adapter is bonded and fixed to the sealed end face part with an opening into which a receptacle body of a connector housing is inserted. A resilient contact connected to a lead wire is caused to be in electrical contact with a copper foil trace terminal of the circuit board. The connector housing and the intermediate adapter are made of a thermoplastic resin resistant to crack failure, which improves handling capability for inserting and withdrawing a connector.

A connector (F) includes an inner housing (11). Terminal fittings (72) fixed to front end parts of wires (71) are inserted into the inner housing (11) from behind. An outer housing (37) is mounted relatively displaceably with respect to the inner housing (11) and is held out of contact with the terminal fittings (72). Two resilient positioning members (55) are configured to position the inner housing (11) and the outer housing (37) and spaced apart in a circumferential direction.

An electrical connector includes a terminal module enclosed within a metallic shield wherein the terminal module includes an insulative housing with two rows of contacts and a metallic shielding plate therebetween. The terminal module includes a rear portion and a front portion extending forwardly from the rear portion. The shield includes a stopping wall with an opening extending therethrough in a front-to-back direction so that the rear portion of the terminal module abuts against the stopping wall while the front portion of the terminal module extends through the opening forwardly.

A receptacle connector includes an insulating housing, a plurality of terminals fastened to the insulating housing, a clamping element and two pairs of reinforcing blocks. A middle of a front surface of the insulating housing is recessed inward to form an insertion space. Two opposite sides of the insulating housing define two clamping grooves. The clamping element has a fixing board fastened to the insulating housing. Two opposite sides of the fixing board are bent frontward to form two clamping arms. Tail ends of the two clamping arms are connected with two clamping portions. The two pairs of reinforcing blocks are fastened in top walls and bottom walls of the two clamping grooves, respectively.

A connector housing includes a housing main body and a latch arm having a latch arm main body and a latch portion protruding from the latch arm main body. The latch arm main body is formed of a first material, extends like a cantilever from the housing main body, and is elastically deformable with respect to the housing main body. The latch portion is formed of a second material having a higher rigidity than the first material and latches with a latched member. A transition region between the first material and the second material has a continuously changing mixing ratio between the first material and the second material.