To provide an electrical connector with flat-type conductors, a counterpart electrical connector, and an electrical connector assembly, in which the size of the connector is not increased in the thickness direction of the flat-type conductors when using two flat-type conductors disposed in parallel opposite each other.

An electrical connector assembly includes a housing defining an interior space and a slot and a spring pin terminal disposed within the slot of the housing. The spring pin terminal includes a first contact portion, a second contact portion, and an intermediate portion that extends between the first contact portion and the second contact portion. The first contact portion includes a contact point that engages a first electrically conductive structure and a retention force support that engages a portion of the intermediate portion of the spring pin terminal. The second contact portion includes a contact point that engages a second electrically conductive structure and a retention force and alignment support that engages the intermediate portion of the spring pin terminal.

A connector that is attachable to an end of a flat cable and is connectable to a counterpart connector includes a housing having a plate-shaped portion and a terminal accommodating portion, and a socket terminal housed in the terminal accommodating portion. The socket terminal has a box portion in which a pin terminal of the counterpart connector is to be inserted, and a spring portion having a cantilever shape, the spring portion extending from the box portion and protruding onto the plate-shaped portion. The end of the flat cable is to be interposed between the plate-shaped portion and the spring portion of the socket terminal. The terminal accommodating portion receives part of force that the spring portion receives from the flat cable.

Systems and methods for an electrical connector (e.g., of a vehicle) include a housing and a terminal at least partially disposed in the housing, defining a set of angled blade terminals, and configured to electrically connect to (i) an electrical system along a first axis and (ii) a set of exposed conductive circuit traces of a flexible circuit (FC) arranged along a second axis, wherein an acute angle is defined between the first and second axes and corresponds to the set of angled blade terminals.

The cable assembly includes a first wire assembly. The first wire assembly is connected to a first connector and a second connector. The first connector includes a shell and the shell includes an extension. The extension extends away from the rear of the connector. In one embodiment, the extension is integral with the shell. The extension includes one or more openings. The first wire assembly is bent in a controlled manner at first bend. The first opening in the extension maintains the first wire assembly in the bent position to maintain control of the radius in first bend. The radius is controlled to allow the first wire assembly to fit in a small space.

A wire-clamping connector assembly includes a wire-clamping connector and a mating connector. The wire-clamping connector includes a first main body that has a retaining groove, a cover, a conductive cable, and multiple first and second conductive terminals that are embedded in the first main body. The second and the first conductive terminals are opposite to each other and are in a staggered arrangement. Each of the first conductive terminals has one of multiple first upper contact portions, and each of the second conductive terminals has one of multiple second upper contact portions. The conductive cable is disposed on the first main body. The cover is disposed on the conductive cable, and is detachably fixed to the first main body. Each conductor in the conductive cable is in electrical contact with one of the first upper contact portions or one of the second upper contact portions.

It is aimed to reduce a load to fixing portions of a flat cable and terminal fittings. A connector (A) includes a flat cable formed such that a plurality of conductors are arranged in parallel on a flexible insulating sheet, a plurality of terminal fittings held in a housing and individually fixed to front end parts of the plurality of conductors, and a reinforcing plate laminated on and integrated with a region of the insulating sheet including fixing portions of the conductors and the terminal fittings. The reinforcing plate is provided with hooking portions. The housing is formed with stoppers for restricting a rearward displacement of the flat cable with respect to the housing by being brought into contact with the hooking portions. A low-rigidity portion is formed in a region of the reinforcing plate rearward of the fixing portions and forward of the hooking portions.

The housing has a locking portion, which is positioned within the range between the circuits positioned at the outermost ends in the strip width direction of the flat-type conductor and is lockable to the counterpart electrical connector, and a holding space, which holds the retainer along with the front end section of the flat-type conductor, the front end section of the flat-type conductor has formed therein a pass-through portion extending through the flat-type conductor in the thickness direction of said flat-type conductor at a location at least partially overlapping with the locking portion in the strip width direction, and the retainer has a protrusion that protrudes in the thickness direction of the flat-type conductor and enters the pass-through portion of the flat-type conductor, thereby making it possible to limit the rearward movement of the flat-type conductor with the help of said protrusion.

There is described an edge assembly for attaching to flexible substrates. An example assembly may comprise at least a first edge component and a compression retainer component. The first edge component may include at least one conductor to mate with one or more conductors on a surface of a flexible substrate after the first edge component is affixed to an edge of the flexible substrate by the compression retainer component. The edge assembly may also comprise a second edge component, wherein the flexible substrate may be compressed between the first and second edge components and held in place by the compression retainer component. The first edge component may further comprise an extension, including the at least one conductor, that may be used to convey power from a power source to the flexible substrate. The extension is accessible from outside the flexible substrate via a port in the compression retainer component.

Provided are a cable securing clamp and a data transmission device. The cable securing clamp includes a clamp body and a snap member. The clamp body is provided with a first through hole, a side wall of the clamp body is provided with a second through hole communicating with the first through hole, and the first through hole is configured to allow a cable to pass through. A first end of the snap member is pivotally connected to the clamp body, a second end of the snap member is in interference fit with the second through hole, a surface of the second end of the snap member is provided with a tooth structure, and the tooth structure is configured to snap the cable in the first through hole such that the cable is secured in an extending direction of the first through hole.