A connecting method includes: arranging the connection terminal such that a rear surface of a base portion in a flat plate shape of the connection terminal comes into contact with a front surface of the flexible substrate; with a rising portion of the connection terminal extending from the rear surface side of the base portion toward the base portion and a tip end bending portion of the connection terminal extending from a tip end of the rising portion in a direction inclined with respect to the rising portion, displacing the rising portion toward the base portion so that the tip end bending portion protrudes from a front surface of the base portion; and holding a part of the flexible substrate between a pressing portion formed at the rising portion and a pressed portion formed at the base portion, whereby the conductive portion of the flexible substrate is electrically connected to at least one of the pressing portion and the pressed portion.

Disclosed herein is an electrical connector. The electrical connector comprises a flexible printed circuit comprising electrical elements on a flexible substrate. The electrical elements each comprises a solder pad and contact pad connected by a link. The electrical connector also comprises a base to at least partially surround the flexible printed circuit. The base comprises a connection interface to facilitate electrical connection with the flexible printed circuit through the base. The electrical connector further comprises a receptacle to couple to the base to partially enclose the flexible printed circuit. The receptacle exposes a portion of the flexible printed circuit to facilitate selective electrical connection with the flexible printed circuit through the receptacle.

Disclosed herein is an electrical connector. The electrical connector comprises a flexible printed circuit comprising electrical elements on a flexible substrate. The electrical elements each comprises a solder pad and contact pad connected by a link. The electrical connector also comprises a base to at least partially surround the flexible printed circuit. The base comprises a connection interface to facilitate electrical connection with the flexible printed circuit through the base. The electrical connector further comprises a receptacle to couple to the base to partially enclose the flexible printed circuit. The receptacle exposes a portion of the flexible printed circuit to facilitate selective electrical connection with the flexible printed circuit through the receptacle.

A wire soldered structure includes a substrate including a main body, a first conducting layer disposed on the main body, and a through hole extending through the main body and the first conducting layer; a wire including a soldered portion that is disposed on the first conducting layer and that is adjacent to the through hole; and a solder disposed in the through hole; wherein the soldered portion of the wire is soldered to the first conducting layer of the substrate via the solder.

Cable connectors for connecting two multicore cables are provided including a clamping sleeve, having a ceramic insulator with openings on each side of the sleeve, for accommodating core conductors. The clamping sleeve includes contact inserts passing through the clamping sleeve. Clamping elements are provided to clamp the core conductors to the contact inserts to electrically connect the multicore cables. The cable connector has a heat shrink tube that surrounds the clamping sleeve and the cables. Furthermore, cable termination including a clamping sleeve with a ceramic insulator with openings for core conductors is provided. Contact inserts are situated behind the openings to clamp the core conductors on the contact inserts establishing mechanical fixing of the core conductors on the clamping sleeve. The cable termination includes a heat shrink tube as according to the first aspect.

Cable connectors for connecting two multicore cables are provided including a clamping sleeve, having a ceramic insulator with openings on each side of the sleeve, for accommodating core conductors. The clamping sleeve includes contact inserts passing through the clamping sleeve. Clamping elements are provided to clamp the core conductors to the contact inserts to electrically connect the multicore cables. The cable connector has a heat shrink tube that surrounds the clamping sleeve and the cables. Furthermore, cable termination including a clamping sleeve with a ceramic insulator with openings for core conductors is provided. Contact inserts are situated behind the openings to clamp the core conductors on the contact inserts establishing mechanical fixing of the core conductors on the clamping sleeve. The cable termination includes a heat shrink tube as according to the first aspect.

A sensor for measuring the position of a component that is displaceable relative to the sensor, includes a circuit board and a metal body. The circuit board includes a first region in which a detector is located, and a second region in which electronic components are located, which are electrically connected to the detector. The metal body includes a first layer having a first area as well as a second layer having a second area. The first region of the circuit board is fixed in place in the first area and the second region of the circuit board is fixed in place in the second area. The first layer and the second layer of the metal body are situated between the first region and the second region of the circuit board so that the first region is located in a first plane and the second region is located in a second plane.

A sensor for measuring the position of a component that is displaceable relative to the sensor, includes a circuit board and a metal body. The circuit board includes a first region in which a detector is located, and a second region in which electronic components are located, which are electrically connected to the detector. The metal body includes a first layer having a first area as well as a second layer having a second area. The first region of the circuit board is fixed in place in the first area and the second region of the circuit board is fixed in place in the second area. The first layer and the second layer of the metal body are situated between the first region and the second region of the circuit board so that the first region is located in a first plane and the second region is located in a second plane.

A connector includes a flat plate portion and one or more guide pins protruding formed on a surface of the flat plate portion, each of the one or more guide pins having a first fitting portion disposed on a root side of the guide pin and fitted with a first circuit board and a second fitting portion disposed on a tip side of the guide pin and fitted with a second circuit board, the first fitting portion being larger in size than the second fitting portion in a direction perpendicular to a connecting direction.

A cable connection structure includes a round cable, a flat cable, a holder holding an end portion of the round cable and an end portion of the flat cable and pulling out the round cable and the flat cable to overlap each other in a same direction, a connecting portion in which a core wire exposed from the end portion of the round cable and a conductor exposed from the end portion of the flat cable held by the holder are connected to each other, and a mold resin portion collectively covering the outer circumference of the holder and the outer circumference of the round cable and the flat cable pulled out from the holder.