A connector is provided which has a main body, a contact part, a tail part, and a plurality of terminals. The main body is made of an insulating material formed in a columnar shape extending in an inserting and extracting direction with a counterpart connector. The plurality of terminals are made of a conductive material loaded in the main body. The terminals are arranged around an axial wire extending in the inserting and extracting direction of the main body so that the position of the tail part forms a polygon in a plan view in a direction perpendicular to the axial wire. The main body includes a tail holding part extending in an axial wire direction. The tail part of each adjacent terminal is exposed at a different position in the axial wire direction in the tail holding part.

A shroud configured to connect a leadframe to a battery system for a hybrid motor vehicle is provided. The shroud is removably attachable to the leadframe. The shroud has at least one shroud alignment feature, the shroud being removably attached to the leadframe in a predetermined orientation wherein the shroud alignment feature is aligned with a complimentary leadframe alignment feature. The shroud may include a hollow cylindrical portion and at least one connecting feature configured to attach the shroud to the leadframe. The shroud may be provided as part of a connector system that includes the leadframe. In this case, the leadframe is configured to provide an electrical and mechanical connection between a power inverter and the battery system of the electric motor. The leadframe includes at least one leadframe alignment feature that is aligned with the shroud alignment feature.

An assembly of a printed circuit board and a card edge connector for interconnecting a memory module card is provided. The assembly includes a card edge connector and a printed circuit board for receiving the card edge connector. The card edge connector has an insulated housing and a plurality of terminals that are divided into an upper-row terminal group and a lower-row terminal group. The insulated housing has an elongated slot formed along a longitudinal direction. Each terminal group includes a first terminal, a second terminal and a third terminal. The printed circuit board has grounding via holes and plated through holes which are formed at two sides of the orthographic projection of the elongated slot. The high-frequency signal holes are separated by grounding traces or the grounding via holes, so as to provide good shielding effect for avoiding cross-talk interference.

A power outlet module, comprising an electrically insulating unitary body, said unitary body comprising a base and an outlet core extending from said base. Said outlet core comprises a plurality of recesses extending in longitudinal direction thereof. The power outlet module further comprises a plurality of terminals made of an electrically conductive material each positioned in one of the plurality of recesses. The terminals each extend in a plane, each terminal including two legs extending in parallel to each other, facing each other with a predetermined gap in-between. The two legs at one end merge into a merging portion, said legs being bendable via the merging portion in a direction parallel to the plane.

A magnetic latching connector for making electrical connections between cables, electrical power and signal sources, equipment and the like in a variety of medical and other applications in which it is desired to have the connection maintained with a predetermined amount of magnetic attractive force. The magnetic latching connector generally includes male and female connector components. The male and female connector components comprise male and female couplings and male and female coupling housings. The male and female coupling housings enclose electrical connections between the male and female couplings and electrical cables. Recessed within the male and female couplings are electrically conductive pins and sockets and male and female magnetic latching elements. When the male and female connector components are coupled, the pins and sockets provide electrical connections and the recessed magnetic latching elements provide a predetermined magnetic attraction force to maintain the connections.

A central shaft power connector for lighted ornaments is disclosed. A central support pole, such as for a Christmas tree is made in two parts joinable with an electrical and mechanical connector which joins the pole parts and simultaneously connects power or other circuits from one part to the other. The connector has two engaging sections and an outrigger platform which locates a connector off to the side of the poles but in alignment. Final alignment is obtained by a key and keyway in the connector parts.

An artificial tree including a first tree portion including a first trunk and first secured electrical connector. The first trunk comprises a first end, a main portion, and a second flared end defining second-end inside and outside diameters. The first connector is in the main portion and comprises a body with a diameter less than the second-end inside diameter for easy insertion through the second end and into the main portion. A second tree portion couples to the first, and includes a second trunk and a second secured electrical connector. The second trunk comprises a first end, an angled transition portion, a main portion, and a second end, the angled transition portion joining the first end and main portion. The second connector comprises a first portion aligned axially with a second portion, the second portion secured to the main portion, and the first portion inserted into the narrower first end.

A plug connection having: a plug connector with, arranged thereon, a first coding element with a coding pattern and an insertion location with, arranged thereon, a second coding element with a coding pattern that matches the coding pattern, wherein the plug connector can be inserted, in an insertion direction (S), into the insertion location as far as a coupling position, when the first coding element and the second coding element adopt a predefined relative position. The first coding element can be rotated on the plug connector about an axis of rotation (A) that runs parallel to the insertion direction (S), and/or the second coding element is held on the insertion location so as to be able to rotate about the axis of rotation (A).

An insertion-type connecting arrangement having at least one first and one second insertion-type connector and an arrangement of insertion points having at least one first and one second insertion point for the insertion of the insertion-type connectors, there being connected to the first insertion-type connector two or more cores laid up at a preset first lay length and to the second insertion-type connector two or more cores laid up at a preset second lay length, having a coding mechanism which allows the first insertion-type connector to be inserted in the first insertion point but not in the second one and which allows the second insertion-type connector to be inserted in the second insertion point but not in the first one.

A System of mated connectors includes a connector having one or more connector quadrants comprising electrical contacts and a mating connector detachably secured to the connector. The mating connector includes one or more mating quadrants and electrical contacts. The mating connector configured to provide electrical coupling to the connector detachably secured thereto. The electrical contacts of a first quadrant of connector quadrants have a first predetermined pin-out and the electrical contacts of a second quadrant of the connector quadrants have a second predetermined pin-out. The electrical contacts of each quadrant of a first pair of the mating quadrants have the first predetermined pin-out and the electrical contacts of each quadrant of a second pair of the mating quadrants have the second predetermined pin-out.