Abstract: Power connector modules are provided that can be plug connectors, receptacle connectors, or a system of plug and receptacle connector modules and optionally other modules, that mate together. Each connector has an uncoupled contact feature. The uncoupled contacts have exposed surfaces to dissipate heat resulting from Joule effects. The uncoupled contacts for the plug connector converge to form a blade structure at one side. The uncoupled contacts for the receptacle connector form a receiving section that engages the blade structure of the plug connector when the plug connector and receptacle connector are used together.

Abstract: A multilayer electrical device, such as a printed circuit board, having a tooth structure including a metal layer set in a dielectric. The device includes a base; a conductive layer adjacent to the base; a dielectric material adjacent to conductive layer; a tooth structure including a metal layer set in the dielectric material to join the dielectric material to the metal layer; and wherein the metal layer forms a portion of circuitry in a circuit board having multiple layers of circuitry.

Abstract: Power connector modules are provided that can be plug connectors, receptacle connectors, or a system of plug and receptacle connector modules and optionally other modules, that mate together. Each connector has an uncoupled contact feature. The uncoupled contacts have exposed surfaces to dissipate heat resulting from Joule effects. The uncoupled contacts for the plug connector converge to form a blade structure at one side. The uncoupled contacts for the receptacle connector form a receiving section that engages the blade structure of the plug connector when the plug connector and receptacle connector are used together.

Abstract: A multilayer electrical device, such as a printed circuit board, having a tooth structure including a metal layer set in a dielectric. The device includes a base; a conductive layer adjacent to the base; a dielectric material adjacent to conductive layer; a tooth structure including a metal layer set in the dielectric material to join the dielectric material to the metal layer; and wherein the metal layer forms a portion of circuitry in a circuit board having multiple layers of circuitry.

Abstract: A laminated terminal is provided for an electrical connector and includes a plurality of flat metal layers juxtaposed to form a laminated structure. Each metal layer includes a joining section, a contact section and a terminating section. A plurality of projections on the joining sections of the layers are interengaged within a respective plurality of recesses in adjacent layers to align the layers and provide a strong mechanical and good electrical joint between the layers. Solder tails extend linearly along the bottom edge of each joining section to form a plurality of rows of solder tails, and the terminating portions of the metal layers are bent outwardly to separate the rows of solder tails from each other. The contact section of one metal layer may include a generally planar finger which is coplanar with a planar finger of another of the metal layers.

Abstract: A laminated terminal is provided for an electrical connector and includes a plurality of flat metal layers juxtaposed to form a laminated structure. Each metal layer includes a joining section, a contact section and a terminating section. A plurality of projections on the joining sections of the layers are interengaged within a respective plurality of recesses in adjacent layers to align the layers and provide a strong mechanical and good electrical joint between the layers. Solder tails extend linearly along the bottom edge of each joining section to form a plurality of rows of solder tails, and the terminating portions of the metal layers are bent outwardly to separate the rows of solder tails from each other. The contact section of one metal layer may include a generally planar finger which is coplanar with a planar finger of another of the metal layers.

Abstract: A blade terminal is provided for an electrical power connector which is mountable on a printed circuit board. The terminal includes at least a pair of flat metal layers juxtaposed to form a laminated structure, with a non-conductive layer disposed between the metal layers. The metal layers include contact blade ends separated from each other a first distance by the non-conductive layer, for mating with one or more appropriate terminals of a complementary connecting device. The metal layers include board mounting ends separated from each other a second distance greater than the first distance, for mounting to the printed circuit board.

Abstract: A multilayer electrical device, such as a printed circuit board, having a tooth structure including a metal layer set in a dielectric. The device includes a base; a conductive layer adjacent to the base; a dielectric material adjacent to conductive layer; a tooth structure including a metal layer set in the dielectric material to join the dielectric material to the metal layer; and wherein the metal layer forms a portion of circuitry in a circuit board having multiple layers of circuitry.

Abstract: A multilayer electrical device, such as a printed circuit board, having a tooth structure including a metal layer set in a dielectric. The device includes a base; a conductive layer adjacent to the base; a dielectric material adjacent to conductive layer; a tooth structure including a metal layer set in the dielectric material to join the dielectric material to the metal layer; and wherein the metal layer forms a portion of circuitry in a circuit board having multiple layers of circuitry.

Abstract: A multilayer electrical device such as a printed circuit board, and method for making the electrical device, having a tooth structure for joining at least one of the layers. The method includes the following steps: providing a base; preparing the base and adding a conductive layer to the base; applying a dielectric material to the conductive layer; preparing the applied dielectric material for receipt of the conductive coating; forming openings (vias) through holes in the applied dielectric coating; etching cavities in the applied dielectric material; applying a conductive coating to the cavities in the applied dielectric material; and forming a metal layer on the conductive coating to produce a tooth structure set in the dielectric coating. The tooth structure preferably has obtuse teeth in the range of 1-2 tenths of a mil deep that mechanically join a dielectric material to a subsequently added metal layer.