A connector, in particular an electrical connector. The connector includes a guide plate, which is configured to be electrically insulating, and a plurality of electrical contact wires, which are in particular stamped, in particular contact pins. The contact wire has an angular, in particular quadrilateral, cross section and is guided through an aperture in the guide plate and projects from the guide plate. In a direction extending through the thickness of the guide plate, the aperture includes a guide shaft. The guide shaft includes at least one planar wall, for guiding a flat side of the contact wire. The guide shaft also includes, on the opposite side to the planar wall, at least one wall region that extends obliquely to it and is configured to touch a corner of the contact wire.

In a connecting method, when a flexible conductor is exposed on a top surface of a connection object, a contact is disposed on the top surface of the connection object at the predetermined position in a state where the connection object is kept as it is, and when the flexible conductor is exposed on a bottom surface of the connection object, the contact is disposed on the top surface of the connection object at the predetermined position in a state where a part of the connection object where the connection part is disposed is inverted such that the connection part faces a top surface side of the connection object while being retained at the predetermined position.

A circuit board assembly includes a circuit board substrate defining an aperture extending therethrough and configured to accept a planar male terminal from a first side of the circuit board substrate. The assembly further includes a female terminal extending from a second side of the circuit board substrate opposite the first side that defines a slot in a U-shaped portion on the second side of the circuit board substrate. The slot has an open end and a closed end. The slot is sized and arranged to receive the male terminal extending through the aperture be in an interference fit with the male terminal. The female terminal has a pair of tines, each tine having a fixed end attached to a base portion and a free end. The free end of one of the tines is disposed within a mounting hole in the circuit board substrate located adjacent the aperture.

A floating electrical connector includes a housing with a tubular portion. An axis is defined in a center of the tubular portion. Several floating terminals are arranged around the axis and are partially connected. Each floating terminal has an inner terminal sheet on an inner side and a spring structure on an outer side. Each spring structure is connected to one of the inner terminal sheets. A portion of the inner terminal sheet is inserted into the tubular portion and arranged along an inner peripheral surface of the tubular portion. The portion of each inner terminal sheet located in the tubular portion has an electronic contact bulging inward. Several external pins are electrically connected around the floating terminals. When a conductive pin is inserted into the tubular portion, the spring structures could elastically deform, allowing the tubular portion to adapt to a horizontal deviation or a skew deviation of the conductive pin, providing a greater tolerance for alignment deviations.

Disclosed herein are various implementations of communications connectors. In some implementations, a communications plug may include a housing and a body positioned in the housing. A flexible printed circuit board (PCB) may be wrapped at least partially around the body, a and a plurality of metal contact pads may be positioned on the flexible PCB to mate with plug interface contacts (PICs) of a communications jack when the communications plug is inserted into the communications jack.

Provided are a motor drive device that reduces the likelihood of mounting error during manufacture, and a method for manufacturing the same. The motor drive device is provided with: a substrate; a first mounting region for mounting first circuit component; a second mounting region for mounting a second circuit component; a first pair of connection points for connecting a first connecting wire member, constituting a first path for supplying electric current to the first circuit component, onto the substrate such that at least a part of the first connecting wire member overlaps the second mounting region; and a second pair of connection points for connecting second connecting wire member, constituting a second path for supplying electric current to the second circuit component, onto the substrate such that at least a part of the second connecting wire member overlaps the first mounting region.

An interposer includes a housing having a plurality of through-holes penetrating a first surface and a second surface and a signal contact pair composed of a pair of signal contacts. Each of the signal contacts includes a base portion press-fitted in one of the through-holes, a first contact beam extending from the base portion beyond the first surface, and a second contact beam extending from the base portion beyond the second surface. The pair of signal contacts are positioned adjacently to each other widthwise and are each asymmetrical with respect to a width direction. The signal contact pair has a plane-symmetrical shape with respect to the width direction.

The present disclosure provides a method for manufacturing a board-to-board connection structure. The method includes defining a first through hole in a first circuit board, disposing a first connector within the first through hole by a first conductive paste, and connecting the first connector to a second circuit board on which a second connector is installed, thereby realizing a connection of the two circuit boards, and reducing a height of the two circuit boards after the connection. That is, the height of the board-to-board connection structure is reduced. Additionally, since the first connector is received within the first through hole, the first connector is not easy to be damaged and oxidized. The present disclosure further provides a board-to-board connection structure manufactured by the above method.

A sensor assembly for a vehicle including a sensor module having a main printed circuit board (PCB). A plurality of auxiliary printed circuit boards (PCBs) are coupled to the main PCB and electrically connected to the main PCB. Each of the plurality of auxiliary PCBs has at least one sensor that is configured to generate a signal. Each of the plurality of auxiliary PCBs are coupled to each other in a defined position relative to each other. A plurality of attachment elements couple the plurality of auxiliary PCBs and the main PCB to at least partially maintain the defined positions of the auxiliary PCBs relative to each other and to electrically connect the plurality of auxiliary PCBs to the main PCB. A retainer abuts the plurality of auxiliary PCBs.

A surface mount technology (SMT) terminal header is described for providing an electrical connection to a first printed circuit board (PCB). The SMT terminal header includes multiple first electrically conductive connector elements each having a base configured for surface mount attachment to the first PCB, and an insulative housing having multiple cells and a fixation member configured to attach the housing to the first PCB. Each of the multiple cells is configured to at least partially house one of the multiple first electrically conductive connector elements. Each of the first electrically conductive connector elements includes a position assurance member configured to attach the first electrically conductive connector element to at least one of the multiple cells of the insulative housing.