An insulation displacement contact device comprises a blade assembly and a biasing element. The blade assembly has a plurality of blades disposed opposite one another each with a cutting edge. The cutting edges of the blades terminate into a contact slot disposed between the blades. The blade assembly is disposed in the biasing element. The biasing element is movable with respect to the blade assembly along a moving direction parallel to the contact slot.

An insulation displacement contact device comprises a blade assembly and a biasing element. The blade assembly has a plurality of blades disposed opposite one another each with a cutting edge. The cutting edges of the blades terminate into a contact slot disposed between the blades. The blade assembly is disposed in the biasing element. The biasing element is movable with respect to the blade assembly along a moving direction parallel to the contact slot.

A snap fastener system includes a conductive first snap fastener portion in electrical and physical contact with a first electronic component, a second snap fastener portion, and a snap ring including tines mated to one of the first and/or second snap fastener portions and including one or more conductive insulation displacement tines which cut through the insulation covering a wire to be electrically coupled to the first electronic component.

A snap fastener system includes a conductive first snap fastener portion in electrical and physical contact with a first electronic component, a second snap fastener portion, and a snap ring including tines mated to one of the first and/or second snap fastener portions and including one or more conductive insulation displacement tines which cut through the insulation covering a wire to be electrically coupled to the first electronic component.

Procedure mounting at least one power electronic unit of a transport segment of a long-stator linear motor onto the transport segment. At least one socket is arranged on the transport segment to accommodate at least one contact element of the drive coil arranged in the socket. At least one clamping element is inserted into the socket with a clamping section. The contact element of the drive coil, while creating an electroconductive connection to the clamping section of the clamping element, is fixed into the socket by the clamping element. At least one contact point of the at least one power electronic unit, while creating an electroconductive connection, is connected directly to a connecting section of the clamping element. The contact element is first arranged in the socket, then the clamping element is inserted into the socket, and then the contact point is connected directly to the connecting section.

Provided is a terminal for an electric wire connector including: a central erection piece configured to have cutting portions inclined downward and outward on both sides of its upper portion; a pair of outer erection pieces configured to be spaced apart at a desired interval on both sides of the central erection piece and have cutting portions that are inclined downward on the upper portion; a connector configured to connect the central erection piece and lower portions of the pair of outer erection pieces; an electrical wire entry portion configured to be a space through which the cutting portions face each other and be a path under which the electrical wire enters; and a core wire connector configured to be arranged on the lower portion communicating with the electric wire entry portion and be a space to connect the central erection piece and the outer erection piece.

A metallic contact for insertion into a modular telecommunications plug includes a generally planar body defining a top end, a bottom end, a front end, a rear end, and a length extending from the front end to the rear end. The bottom end is at least partially defined by a blade for piercing an insulation of a wire positioned within the plug. At least a portion of the top end is configured to electrically contact a conductor of a jack that receives the plug. The top end is defined at least in part by a first engagement surface that is separated from a second engagement surface by a notch. An uppermost portion of the first engagement surface defines a first push surface that is generally at the same height as a second push surface defined by an uppermost portion of the second engagement surface. The notch is defined by a front vertical wall spaced from a rear vertical wall, wherein the front vertical wall is positioned at a distance of at least half the length of the contact from the front end of the contact.

A metallic contact for insertion into a modular telecommunications plug includes a generally planar body defining a top end, a bottom end, a front end, a rear end, and a length extending from the front end to the rear end. The bottom end is at least partially defined by a blade for piercing an insulation of a wire positioned within the plug. At least a portion of the top end is configured to electrically contact a conductor of a jack that receives the plug. The top end is defined at least in part by a first engagement surface that is separated from a second engagement surface by a notch. An uppermost portion of the first engagement surface defines a first push surface that is generally at the same height as a second push surface defined by an uppermost portion of the second engagement surface. The notch is defined by a front vertical wall spaced from a rear vertical wall, wherein the front vertical wall is positioned at a distance of at least half the length of the contact from the front end of the contact.

A photosensor is provided with a sensor circuit assembly. The sensor circuit assembly includes alight emitter, a light receiver, a light-emitter support, a light-receiver support, and a connecting part. The light emitter and the light receiver face each other. The light-emitter support extends from and supports the light emitter. The light-receiver support extends from and supports the light receiver. The connecting part connects one end of the light-emitter support with one end of the light-receiver support. The connecting part includes a seal and a connection terminal that protrudes from the seal. The connection terminal includes a first press-contact part, and a first pressure part that presses the first press-contact part in a press-contact direction.

A photosensor is provided with a sensor circuit assembly. The sensor circuit assembly includes alight emitter, a light receiver, a light-emitter support, a light-receiver support, and a connecting part. The light emitter and the light receiver face each other. The light-emitter support extends from and supports the light emitter. The light-receiver support extends from and supports the light receiver. The connecting part connects one end of the light-emitter support with one end of the light-receiver support. The connecting part includes a seal and a connection terminal that protrudes from the seal. The connection terminal includes a first press-contact part, and a first pressure part that presses the first press-contact part in a press-contact direction.