An interface having a frame with a plurality of slots, a first pass-through insert in the frame and a second pass-through insert in the frame. The first pass-through insert and the second pass-through insert each have a housing and a contact with the type of contact in the first pass-through insert is different than the type of contact in the second pass-through housing.

An RF connector is disclosed herein. An exemplary embodiment of the present disclosure provides an RF connector including: a first printed circuit board on which a plurality of devices is mounted; a first bridge assembly mounted on an area adjacent to at least one side of the first printed circuit board and including a plurality of first signal transmission pins; a second printed circuit board disposed to be spaced apart from the first printed circuit board; a plurality of connection terminals disposed at an area adjacent to at least one side of the second printed circuit board so as to be in contact with at least one surface of the plurality of first signal transmission pins; a first push bar configured to apply a force to at least one surface of the plurality of first signal transmission pins to keep the contact between the plurality of first signal transmission pins and the plurality of connection terminals; and a first metal shielding plate fixed to the first push bar and the second printed circuit board, and configured to shield at least some of the second printed circuit board and the first push bar.

A receptacle coupler includes a coupler contact assembly having upper and lower contacts each having a front mating beam configured to mate with a front module circuit board and a rear mating beam configured to mate with a rear module circuit board with an intermediate portion therebetween. The coupler contact assembly includes a contact holder holding the upper and lower contacts. The receptacle coupler includes a coupler housing having a contact chamber receiving the coupler contact assembly and front and rear receptacles configured to receive the module circuit boards. The coupler housing holds the coupler contact assembly with the front mating beams in the front receptacle for mating with the front module circuit board and the rear mating beams in the rear receptacle for mating with the rear module circuit board.

An electrical connector assembly includes an electrical plug connector and an electrical receptacle connector corresponding to the electrical plug connector. The electrical plug connector includes a plug fixation housing, a plug movable housing, and plug terminals. The plug terminals are on the plug fixation housing, and the plug movable housing is floatingly arranged on the plug fixation housing. The electrical receptacle connector includes a receptacle fixation housing, a receptacle movable housing, and receptacle terminals. The receptacle terminals are on the receptacle fixation housing, and the receptacle movable housing is floatingly arranged on the receptacle fixation housing. An electrical plug connector and an electrical receptacle connector are also provided.

A plug connector provides an electrical connection to a conductor track connection of a printed circuit board. The plug connector has a first printed circuit board with a conductor track connection and a plugging region for plugging the printed circuit board into the plug connector. The plugging region extends parallel to the first printed circuit board. A contact element and/or a spring element is provided in the plug connector. The plugging region and the contact element and/or the spring element are arranged in such a way that, in a plugged state of the plug connector, the printed circuit board which is plugged into the plugging region is arranged parallel to the printed circuit board and the conductor track connection is arranged opposite the conductor track connection. An electrical connection of the conductor track connection to the conductor track connection is provided by the contact element and/or the spring element.

A substrate assembly includes a printed circuit (PC) substrate, first and second microchips, components or substrates mounted on a surface of the PC substrate, and a projection extending in spaced relation to the surface of the PC substrate. In one example, the projection extends between (i) a downward facing surface and/or an edge of a side facing surface proximate the downward facing surface of the first microchip, component or substrate and (ii) an upward facing surface and/or an edge of a side facing surface proximate the upward facing surface of the first microchip, component or substrate. The first and second microchips, components or substrates may be mounted on different levels of the PC substrate surface. In another example, the projection extends between a upward and/or side facing surface of a first microchip, component or substrate and a slot or cavity in a second microchip, component or substrate.

This application relates to the field of power supply packaging technologies, and in particular, to a PCB-pinout based packaged module, including a packaged module and a pin exposed outside the packaged module. The packaged module includes a PCB and a power component. The PCB has a first surface and a second surface that are disposed opposite to each other, and the power component is disposed on the first surface or the second surface of the PCB. The power component performs communication connection with a pin located on one side of the first surface or one side of the second surface of the PCB through surface-layer copper of the PCB. The pin located on one side of the first surface or one side of the second surface of the PCB is a surface-layer copper etching pattern that is located on the PCB and that is exposed outside the packaged module.

The present invention relates to a connector. Aforementioned connector includes a first connecting member, a second connecting member, and a third connecting member. The first connecting member includes a first case, a first insulator, and a first conductive terminal, wherein the first case defines a first receiving chamber therein, the first insulator is received in the first receiving chamber, an external sidewall of the first case is provided with a first step. The second case defines a containing hole, the PCB board is received in the containing hole, a first end and a second end of the second case each defines a latching groove, the latching grooves is in communication with the containing hole. The third connecting member includes a third case, a second insulator, and a second conductive terminal, wherein the third case defines a second receiving chamber therein. In above connector, because the electrical components coupled to opposite ends of the connector can slide along three directions which are perpendicular to each other, such that a problem of a difficulty of a connection between the connector and the electrical components which is caused by a deviation of the design of the structure of the electrical components can be avoided, thereby a tolerance insensitive of the connector is enhanced.

A card edge connector for use with high-speed signals. The card edge connector includes a shielding member held in a base portion of a housing of the card edge connector on a side of a first terminal row of the card edge connector facing away from a second terminal row and spaced apart from the first terminal row. The shielding member is configured to overlap at least intermediate portions of a plurality of pairs of first signal terminals, and to electrically connect a plurality of ground terminals to each other. Such a configuration enables the card edge connector to meet signal integrity requirements in connectors designed for 128 Gbps and beyond, while conforming to a standard that constrains mating and mounting interfaces.

An electrical connector includes wafer assemblies coupled to a housing. Each wafer assembly includes a leadframe, a wafer body holding the leadframe, and a ground frame coupled to the wafer body to provide electrical shielding for the leadframe. Each leadframe has signal contacts with mating ends extending from the wafer body for mating with mating signal contacts of a mating electrical connector. The mating ends are twisted 45° to define twisted mating interfaces. Each ground frame has ground shields extending from a ground plate along the mating ends of the signal contacts. The ground shields are twisted 45° relative to the ground plate to define twisted shield zones along the mating ends of the signal contacts.