An electrical connector includes an insulative housing, a plurality of slit type passageways, a plurality of blade type contacts retained with the corresponding slit type passageways, respectively, and a plurality of wires having the inner conductors soldered upon the tails of the contacts behind the rear face of the housing. The rear face forms a plurality of standoffs on which the front ends of the exposed inner conductor abut, respectively. A waterproof glue plate fills the back space of the housing behind the rear face to enclose the exposed inner conductors and the corresponding tails and seal the rear face of the housing.

A flex flat cable (FFC) structure includes metallic transmission wires arranged in parallel, first insulating jackets, and second insulating jacket. The metallic transmission wires includes one or more power wires and signal wires. The power wire is configured to transmit power. The signal wires are configured to transmit a data signal. Each of first insulating jackets encloses one of metallic transmission wires. The second insulating jacket surrounds the first insulating jackets. An embossment pattern is arranged on an external surface of the second insulating jacket. The embossment pattern includes meander lines in a top-view direction and in an extending direction for the metallic transmission wires. The meander lines are not arranged parallel.

A flexible printed circuit board according to one aspect of the present invention includes a base film having an insulating property and a conductive pattern laminated on one surface of the base film, and has a terminal connecting area toward one end edge of the conductive pattern, the flexible printed circuit board including a reinforcement member laminated on another surface of the base film and situated at least at a position opposite the terminal connecting area, wherein a shape of an end edge of the reinforcement member on the same side as an opposite end edge of the conductive pattern includes a periodic form constituted by curved lines.

An electrical connector comprising a male plug and a female plug, the female plug connected to the male plug through a circuit module, and the circuit module connected to the first electrode; in particular, a sheet body is configured between the male plug and the female plug. The sheet body comprises a conducting layer connected to the second electrode. The forward projection of the conducting layer on the sheet body forms a piercing zone. The male plug pierces the sheet body through the piercing zone, snaps together with the female plug, and is electrically connected to the conducting layer. The connector of the present invention differs from conventional connectors in both structure and usage, and can be applied in various fields.

An adaptor includes a substrate, a first housing, and a flat cable. The substrate comprises a terminal hole. The first housing includes a first insertion hole and a second insertion hole. The substrate is inserted into the first insertion hole. The flat cable includes a plurality of conductors. Each of the conductors includes a conductor terminal. The flat cable passes through the second insertion hole. The conductor terminal is connected to the terminal hole. A direction in which the substrate is inserted into the first insertion hole is perpendicular to a direction in which the flat cable passes through the second insertion hole.

A light assembly is provided with a circuit board, a connector and a first light emitting device. The circuit board is formed with a first conductive path and a second conductive path. The connector is supported by the circuit board and includes a first terminal connected to the first conductive path and at least two second terminals connected to the second conductive path. The at least two second terminals are arranged radially symmetrical about an axis and are adapted to engage mating terminals of a mating connector when the mating connector is oriented in both a first position and in a second position that is angularly offset from the first position about the axis. The first light emitting device is supported by the circuit board and in electrical communication with the first conductive path and the second conductive path.

A connector for connecting a flexible interconnect circuit includes a base, having a first set of protrusions and a second set of protrusions. The first set of protrusions and the second set of protrusions are configured to secure the flexible interconnect circuit at a first set of apertures and a second set of apertures of the flexible interconnect circuit, respectively. The first set of protrusions may be positioned at a first distance from the second set of protrusions on the base. The first set of apertures may be positioned on the flexible interconnect circuit at a second distance, greater than the first distance, from the second set of apertures. The base causes the flexible interconnect circuit into an arched configuration when the apertures are secured to the respective protrusions. The connector further includes a cover piece configured to secure the flexible interconnect circuit in the arched configuration.

An electrical connector includes a housing that is configured to receive a planar first substrate having an electrically conductive first circuit trace with a first contact region, such a flat cable. The housing is further configured to receive a planar second substrate having an electrically conductive second circuit trace with a second contact region, such as a printed circuit board or another flat cable. The housing is configured to align the first contact region with the second contact region. The connector also includes a force application device configured to apply a compressive contact force to the first and second substrates, thereby putting the first contact region in intimate compressive contact with the second contact region. The connector may also include an moveable actuating member that is configured to selectively increase the compressive contact force applied to the first and second substrates via interaction with the force application device.

In some embodiments, an apparatus comprises a biosensing garment and an electronics assembly. The biosensing garment includes a sensor, a conductive pathway, and a connection region including one or more connectors that are disposed on a PCB. The connection region is electrically coupled to the conductive pathway and the sensor. The connection region is further configured to be electronically coupled to the electronics assembly via at least one conductive contact. In some embodiments, the electronics assembly includes at least one conductive contact that is configured to be electronically coupled to at least one portion of the PCB.

A flexible printed circuit board according to one aspect of the present invention includes a base film having an insulating property and a conductive pattern laminated on one surface of the base film, and has a terminal connecting area toward one end edge of the conductive pattern, the flexible printed circuit board including a reinforcement member laminated on another surface of the base film and situated at least at a position opposite the terminal connecting area, wherein a shape of an end edge of the reinforcement member on the same side as an opposite end edge of the conductive pattern includes a periodic form constituted by curved lines.