A connector includes a pushing member having a projection, and a contact having a projection accommodating portion, the projection accommodating portion having a protruding portion that is situated in an inner surface of the projection accommodating portion with protruding from the inner surface of the projection accommodating portion toward an inside of the projection accommodating portion and approaches a lateral surface of the projection when the projection is inserted into the projection accommodating portion, and a gap forming portion that is situated in the inner surface of the projection accommodating portion around the protruding portion and forms a predetermined gap between the gap forming portion and the lateral surface of the projection when the projection is inserted into the projection accommodating portion, the predetermined gap being wider than a distance between the protruding portion and the lateral surface of the projection.

A sensor set is provided for sensing of a body characteristic, such as glucose. The sensor set includes a mounting base for the sensor and a connector to connect to the mounting base and has an improved structure for connecting the mounting base to the connector. The connector may contain sensor electronics for wired or wireless communication to an external monitor or display. The mounting base includes latch arms and the connector adapted to fit and lock into latch recesses on the connector and includes anti-rotation arms adapted to fit into anti-rotation arm recesses on the connector.

A sensor set is provided for sensing of a body characteristic, such as glucose. The sensor set includes a mounting base for the sensor including a shim adapted to prevent pull up of the sensor and a connector to connect to the mounting base and has an improved structure for connecting the mounting base to the connector. The connector may contain sensor electronics for wired or wireless communication to an external monitor or display. The mounting base includes latch arms and the connector adapted to fit and lock into latch recesses on the connector and includes anti-rotation arms adapted to fit into anti-rotation arm recesses on the connector.

Provided is a connector including at least one plate-like housing body, a plurality of groove-like terminal housing chambers each opened in an upper surface of the housing body and parallelly arranged, a plurality of connection terminals provided at ends of a plurality of electrical wirings and housed and disposed in the terminal housing chambers, respectively, and a cover part overlapping with the upper surface of the housing body to cover the terminal housing chambers, wherein an elastic locking claw, which allows each of the connection terminals to be inserted into each of the terminal housing chambers by elastic deformation and is locked to each of the connection terminals to prevent each of the connection terminals from coming out of each of the terminal housing chambers by elastic restoring, is provided to protrude from a bottom surface of each of the terminal housing chambers.

The application relates to a flexible flat cable assembly and a battery pack connecting assembly. The flexible flat cable assembly has a flexible flat cable and an adaptor terminal, wherein the flexible flat cable has an insulation sheath, a conductor body wrapped by the insulation sheath, and a connecting end which is provided to be integrated with the conductor body and comprises a connecting portion and a crimping portion extending continuously from the conductor body; the adaptor terminal has a terminal body and a pair of first crimping wings which are disposed on the terminal body and protrude from the terminal body; the crimping portion is in contact with the terminal body, and the first crimping wings surround the crimping portion to form a crimping region in which the crimping portion has a multilayer structure. The present application can ensure a secure connection during use, and is safe and convenient to use.

A connector for clothing includes a first substrate and a first connector being mounted on the first substrate. The first connector includes a first conductive metallic case with a first bottom portion surrounded by an annular first side portion. At least two first wire through holes are configured to the first side portion. A first wire module including at least three first wires and at least one ground wire is configured to the first connector. Three first wires are passed through one of the first wire through hole and the ground wire is electrically connected with a surface of the first case. A first circular board is configured inside but insulated from the first case. At least three first electric junctions are electrically attached on a surface of the first circular board and each first wire is electrically connected with each first electric junction.

An electrical cable assembly is presented herein. The electrical cable assembly includes a multiconductor flat cable including a first and second electrically conductive wire arranged in a coplanar fashion with each other and encased within a planar dielectric structure. A slot is defined in the planar dielectric structure intermediate the first and second wires, thereby forming first wing features in the dielectric structure extending from the first wire and second wing features extending from the second wire. Exposed portions of the first and second wires extend beyond the first and second wing features. A method of forming the electrical cable assembly, an apparatus for forming the electrical cable assembly, and an electrical terminal configured for use in the electrical cable assembly is also presented.

A connector includes a connector body, a first elastic member, and a second elastic member. The connector body has an insertion hole that allows a connection member to be inserted thereinto. The connection member has a plate shape or a sheet shape. Each of the first and second elastic members is a conductive member that includes a base fixed to the connector body. The first and second elastic members are elongated in a thickness direction of the connection member and butted against each other so as to partially block the insertion hole. The thickness direction intersects an insertion direction of the connection member.

An electrical connector includes an insulative portion, a plurality of terminals supported by the insulative portion and are disposed in a row, and a lossy member. Each of the terminals includes a first end, a mounting end, and an intermediate portion. The lossy member includes a body portion elongated in a row direction and a plurality of projections extending from the body portion toward the first ends of a subset of the terminals. Each of the terminals includes a first surface and a second surface opposite the first surface, with the first face including a first contact region. The projections of the lossy member are aligned with the second surfaces of the subset of terminals. Upon mating the electrical connector to a complementary connector, the terminals may deflect towards the projections of the lossy member, improving contact with the lossy member and thus improving its effectiveness.

A connector assembly comprises a main connector, a first wiring sheet and a second wiring sheet. The main connector has a receiving portion. The first wiring sheet has a first positioned portion, a first deformable portion extending from the first positioned portion and a first contact provided on the first deformable portion. The second wiring sheet has a second positioned portion, a second deformable portion extending from the second positioned portion and a second contact provided on the second deformable portion. When the connector assembly is assembled, the first positioned portion and the second positioned portion are positioned by a positioning jig. Then, the first deformable portion and the second deformable portion are pressed downward to be pushed into the receiving portion so that the first contact and the second contact are located within the receiving portion to be in contact with each other.