A manufacturing method of a symbol button for a vehicle includes: preparing a button body comprising a side portion, a top portion formed of a polymer material on which a metal is able to be plated; forming an electrically conductive layer on an outside of the button body using a conductive polymer material; forming a plating shielding layer in a form of a symbol using a material on which a metal is not able to be plated on the electrically conductive layer; and performing metal plating on the outside of the button body having the plating shielding layer.

A manufacturing method of a symbol button for a vehicle includes: preparing a button body comprising a side portion, a top portion formed of a polymer material on which a metal is able to be plated; forming an electrically conductive layer on an outside of the button body using a conductive polymer material; forming a plating shielding layer in a form of a symbol using a material on which a metal is not able to be plated on the electrically conductive layer; and performing metal plating on the outside of the button body having the plating shielding layer.

A conductive member module has a pair of conductive members formed in a plate shape and facing each other, and a sealing part for sealing the pair of conductive members. The conductive member module is produced by performing an accommodation step, a sealing step, and an extraction step. In the sealing step, the conductive members are sealed with a resin injected into a die while a force is applied by the resin to the individual conductive members in directions to approach each other in a facing orientation of the pair of conductive members.

A steering wheel is provided with a heater element on the rim. The heater element is mounted at least on a part of a core of the rim, and a cladding layer formed from synthetic resin foam covers an outer circumference of the heater element. The heater element includes a cord-shaped heater and a base material. The base material includes an insulation sheet that is formed from synthetic resin foam and disposed to face towards the core and a permeable sheet that is formed from non-metal which allows permeation of the cladding layer. The insulation sheet and permeable sheet are bonded together and sandwich and support the cord-shaped heater there between.

The switch housing for capacitive switches has an outer contact surface and flat electrode structures which are arranged on the inside and in a position opposite the contact surface and which are placed by two-component injection molding in recessed regions of the housing body injected from a first, electrically non-conductive plastic component by a second, electrically conductive plastic component. Preferably, both plastic components are a polycarbonate, the second plastic component containing carbon fibers.

A conductive member module has a pair of conductive members formed in a plate shape and facing each other, and a sealing part for sealing the pair of conductive members. The conductive member module is produced by performing an accommodation step, a sealing step, and an extraction step. In the sealing step, the conductive members are sealed with a resin injected into a die while a force is applied by the resin to the individual conductive members in directions to approach each other in a facing orientation of the pair of conductive members.

A connector cavity assembly for a medical device, comprising at least one connector cavity comprising a plurality of electrically conductive electrode contacts spaced apart from each other and a plurality of electrically insulating insulation elements, wherein the electrode contacts and the insulation elements are arranged alternatingly; and a connector cavity housing. The connector cavity assembly is characterized in that the at least one connector cavity is removably arranged within the connector cavity housing, wherein the connector cavity housing exerts a pretension on the at least one connector cavity leading to a liquid-tight sealing between the insulation elements and the electrode contacts.

A method of encapsulating a panel of electronic components such as power converters reduces wasted printed circuit board area. The panel, which may include a plurality of components, may be cut into one or more individual pieces after encapsulation with the mold forming part of the finished product, e.g. providing heat sink fins or a surface mount solderable surface. Interconnection features provided along boundaries of individual circuits are exposed during the singulation process providing electrical connections to the components without wasting valuable PCB surface area. The molds may include various internal features such as registration features accurately locating the circuit board within the mold cavity, interlocking contours for structural integrity of the singulated module, contours to match component shapes and sizes enhancing heat removal from internal components and reducing the required volume of encapsulant, clearance channels providing safety agency spacing and setbacks for the interconnects. Wide cuts may be made in the molds after encapsulation reducing thermal stresses and reducing the thickness of material to be cut during subsequent singulation. External mold features can include various fin configurations for heat sinks, flat surfaces for surface mounting or soldering, etc. Blank mold panels may be machined to provide some or all of the above features in an on-demand manufacturing system. Connection adapters may be provided to use the modules in vertical or horizontal mounting positions in connector, through-hole, surface-mount solder variations. The interconnects may be plated to provide a connectorized module that may be inserted into a mating connector.

A conductive member module has a pair of conductive members formed in a plate shape and facing each other, and a sealing part for sealing the pair of conductive members. The conductive member module is produced by performing an accommodation step, a sealing step, and an extraction step. In the sealing step, the conductive members are sealed with a resin injected into a die while a force is applied by the resin to the individual conductive members in directions to approach each other in a facing orientation of the pair of conductive members.

A molded article includes a first plateable region spaced apart from a second plateable region the first plateable region by a barrier of electrically insulating material. Each of the plateable regions include an associated plateable layer of electrically conductive material for being electroplated with a different plateable finish. Several different geometries and configurations of the barrier and/or the plateable regions are provided to prevent migration of plating material from one of the plateable regions acting as bipolar electrode while another one of the plateable regions is being electroplated. A non-plateable insert may be disposed between the plateable regions to prevent migration of plating material from one of the plateable regions onto the other one of the plateable regions. A conducive robber in electrical communication with one of the one of the plateable regions, and which may be removable, may also be used to prevent migration of plating material.