A flat-conductor connection element for an electrically conductive structure applied to a pane, includes at least one conductor, containing a flat conductor, having a first connection region at a first end and a second connection region at a second end, the first connection region having a connection surface for electrically connecting to the electrically conductive structure and having a contact surface opposite the connection surface for contact with a soldering tool; an encapsulation layer made of an electrically insulating material, which encapsulation layer surrounds the conductor at least in a conductor portion containing the first connection region, the encapsulation layer having a through-hole, through which the connection surface and the contact surface of the first connection region are accessible, the first connection region of the conductor being within the through-hole in a view perpendicularly through the plane of the encapsulation layer.

An electrical connector and a manufacturing method for the same. The electrical connector comprises a housing member and a plugging module. One end of the housing member is provided with a mating interface. An accommodating space communicating with the mating interface is provided in the housing member. The plugging module comprises a first circuit board, a plurality of electrical conductors and a plurality of first soldering pads. The first circuit board is disposed in the accommodating space. The first circuit board comprises a first surface and a second surface opposite to the first surface. The plurality of electrical conductors are disposed on the first surface and/or the second surface and is close to the mating interface. The plurality of first soldering pads are disposed on the second surface and are electrically connected with the plurality of electrical conductors.

An electrical connector includes a housing defining a base portion and a tongue portion, two rows of terminals and a shielding shell. The tongue portion defines a thickened step at a root to the base portion, the base portion defines a front and a rear side, and an upper and a lower retaining slots. The shell is retained on the base portion and surrounding the tongue portion so as to define a mating cavity between the shell and the tongue portion. The shell defines an upper and a lower-front stopping portions inwardly received in corresponding retaining slots to prevent a forward movement of the housing. The upper and lower front stopping portions extend forwardly into the mating cavity across the front side of the base portion so as to prevent a mating connector from damaging the housing during the mating connector is inserted into the mating cavity.

A method of assembling a water-in-fuel sensor assembly. The method includes an initial step of providing a housing that has a recess, at least one pin located within the housing, a circuit board, and at least one terminal configured for engaging the at least one pin. The method also includes forming a board-mounting subassembly by coupling the at least one terminal to the circuit board. The method also includes positioning the board-mounting subassembly within the housing by engaging the at least one terminal with the at least one pin such that the board-mounting subassembly is disposed within the recess of the housing.

A connection strip is designed as a printed circuit board connector and has a strip-like connection housing, which is formed in one part or in a plurality of parts. The connection housing has a plurality of outer sides, the first outer side having a mating face side on which there are at least two or more mating face plug-in contacts, which can each be plugged together with a corresponding plug-in contact of a corresponding plug connector. The connection housing is further designed to have printed circuit board plug-in contacts on one, two or three of the other outer sides, which contacts project beyond the respective outer side so that on the one or more outer sides on which the printed circuit board plug-in contacts are provided, a printed circuit board can be soldered. A method for manufacturing the connection strip is also provided.

Methods and apparatuses to provide a pin, a pin combination structure and a package body are described. A baffle structure is sleeved on the pin. The baffle structure is used to prevent a plastic packaging material from overflowing from a cavity that accommodates the plastic packaging material. The cavity is in a mold for packaging the package body.

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.

A pin terminal includes a bar-like base material and a plating layer covering a predetermined region of the base material. A constituent material of the base material is pure copper or a copper alloy. The plating layer includes a tin-based layer made of metal containing tin. One end side of the base material includes a tip covering portion covering an entire region in a circumferential direction of the base material. The tin-based layer includes the tip covering portion. The tip covering portion includes a thin film portion and a thick film portion at positions different in the circumferential direction of the base material. The thin film portion is provided in contact with the base material. The number of whiskers present on a surface of the thin film portion is 15 or less in a square visual field having one side length of 0.35 mm.

The present disclosure relates to a connector and method for connecting a coaxial cable to a printed circuit board. The connector comprises: a connector, which comprises a cavity penetrating the connector, such that the connector body comprises a first opening and a second opening; an inner contact arranged in the cavity of the connector body, wherein the first end of the inner contact extends from the first opening and the second end of the internal contact is located in the cavity; a plurality of outer contacts arranged on the end face of the connector body, which extend in a direction perpendicular to the end face; a dielectric spacer provided in the cavity of the connector body for separating the inner contact from the plurality of outer contacts; and a bushing element being attachable to the outer conductor of the coaxial cable to form an electrical connection between the plurality of outer contacts of the connector and the outer conductor of the coaxial cable. The connector further comprises a recess formed by a third opening provided on its side, wherein the recess includes an inner peripheral surface and a bottom surface with a hole, and the bushing element can be placed in the recess.

A biocompatible electrical connection includes: a substrate; a ferrule having a concentric flange at a first end of the ferrule; a first adhesive; and a second adhesive. The substrate includes a hole having a diameter that is a specified amount larger than an outside diameter of the ferrule forming an annular space between the hole and the ferrule, the first adhesive adheres a first surface of the concentric flange of the ferrule to a first surface of the substrate, and the second adhesive fills the annular space between the hole and the ferrule.