A communication outlet for use with a communication plug comprising a plurality of plug contacts. The outlet includes contact pads, contact members, and a biasing member. The contact members each have an electrically conductive portion attached to an electrically non-conductive portion. Each of the conductive portions forms an electrical connection with a different corresponding one of the contact pads. Each of the contact members is movable with respect to its corresponding contact pad. The contact members are movable with respect the plug contacts. The biasing member is attached to the non-conductive portion of each of the contact members and is configured to bias the conductive portion of each of the contact members toward a different corresponding one of the plug contacts when the plug is inserted into the outlet.

A spring loaded direct plug-in terminal with a direct plug-in connector for the connection of a conductor includes a housing with a chamber and a plug-in channel for plugging the conductor into the chamber. The terminal also includes a busbar, a clamping spring arranged in the chamber and acting as a compression spring for fixing the electrical conductor on the busbar in the area of a clamping site. The clamping spring includes a pivotable clamping arm which can be adjusted from a locked state in a locked position into a clamping state in which it is unlocked from the locked state and presses the electrical conductor against the busbar. An actuation element which is movable in the housing is provided which, together with the clamping arm of the clamping spring, can be locked in the locked state. The mobility of the actuation element in the housing in the locked state can be arrested by a locking element which is movable at an angle relative to the movement direction of the actuation element.

A connector includes a first connector and a second connector mounted on an external device. The first connector includes a contact including a contact portion electrically connected to a connection terminal of the second connector by pressing the connection terminal in a predetermined direction; a flexible conductor connected to the contact; a protection member that protects the contact portion by covering a periphery of the contact; a base body that accommodates the contact, the flexible conductor, and the protection member; and an elastic member that is formed separately from the contact and presses the contact and the protection member in a direction opposite to the predetermined direction.

A contact pin to electrically connect a first electrical component to a second electrical component and contact with the first and second electrical components at a sufficiently large contact pressure. The contact pin includes a first plunger with a first contact portion and a second plunger with a second contact portion. An expandable meander portion is formed on the second plunger. A contact piece to conduct electricity between the first and second plungers is provided to guide the expanding and shrinking operation of the meander portion. The first and second plungers are conducted via the contact piece when the first electrical component is electrically connected to the second electrical component, and the meander portion is shrunk to bring the first contact portion of the first plunger and the second contact portion of the second plunger into contact with the first and second electrical components at a sufficiently large contact pressure.

A contact has a flat surface and a side surface that is parallel to the flat surface. At least a part of the side surface is curved so as to swell. At least a part of the contact is able to be elastically deformed in parallel to the flat surface.

A vertical spring contact that is constructed of a single piece of electrical conductor, having a central spine that acts as a spring and does not bulge horizontally during compression. This contact is also provided with a pair of arms extending downwards from a top member, flanking both sides of the central spine without being in contact with the central spine. The lower tips of the arms are bent inwards. The central spine structurally connects the top member to a bottom member. The bottom member is provided with recesses that are adapted to loosely receive the lower tips of the arms. In this way, when the contact is compressed, the lower tips of the arms are pressed into the recesses, thus establishing more contact points for a current to pass through.

An example contact head includes coaxial contacts configured for transmission of radio frequency (RF) signals or digital signals between a test system and a device under test (DUT). Each of the coaxial contacts is configured to target a specific impedance. Each of the coaxial contacts includes a coaxial structure having an open-curve shape. The coaxial structure includes a spring material that bends in response to applied force and that returns to the open-curve shape absent the applied force. The coaxial structure includes a center conductor terminating in a contact pin and a return conductor separated by a dielectric from the center conductor. At least part of the center conductor and the return conductor include an electrically-conductive material. Flexible contacts on the coaxial contact include the electrically-conductive material.

A contactor including a bellows body, a fixed portion connected to one end of the bellows body, and a movable portion connected to the other end of the bellows body, where the bellows body, the fixed portion and the movable portion are integrally molded by electroforming, and the movable portion is configured to be depressed to compress the bellows body, so that adjacent arc portions of the bellows body are brought into contact with each other to cause a short circuit.

An electrical connector includes an insulative housing defining a top surface and a bottom surface opposite to each other and a plurality of electrical contacts received in the insulative housing. Each electrical contact is formed by stamping a metal plate and includes a contacting portion exposed to the top surface, a mounting portion extending out of the bottom surface and an elastic portion disposed between the contacting portion and the mounting portion and in the insulative housing, wherein the elastic portion includes a first elastic portion and a second elastic portion disposed on two opposite sides of the contacting portion.

The present invention intends to suppress a contact probe from interfering with a guide plate to produce shavings. The present invention has stacked structure that sandwiches an intermediate metallic layer 12 between outer metallic layers 11 and 13, and includes: a contact part 2 that is brought into abutting with a test object; an elastic deformation part 4 that is elastically deformed so as to be curved in a predetermine direction of curvature N by compression force in the longer direction; and a fore end part 3 that is formed between the contact part 2 and the elastic deformation part 4 and supported by a through-hole 121 of a guide plate 120 so as to make the contact part 2 movable in the longer direction, in which side surfaces of the fore end part 3 formed in the direction of curvature N and a direction N′ opposite to the N of the elastic deformation part 4 are configured to include the three metallic layers 11 to 13, and on the side surfaces, the intermediate metallic layer 12 is configured to protrude relative to the outer metallic layers 11 and 13.