Abstract: A wire terminal assembly is disclosed in which a conductive terminal is connected to a conductive cable core along a conductive connection interface. A coating is disposed over the conductive connection interface that is the product of a free radical polymerization reaction of a coating composition applied over the conductive connection interface, the coating composition including: (1) an oligomer comprising at least two active unsaturated bonds, (2) a monomer comprising an unsaturated bond, and (3) a compound comprising a plurality of thiol groups.

Abstract: An electrical connector assembly is presented herein. The electrical connector includes a pair of connector blocks each defining a groove in an end surface that is configured to have an electrical conductor of an electrical cable partially disposed within it, e.g. a carbon nanotube conductor. The electrical connector also includes a housing configured to receive connector blocks, align the groove of one connector block with the groove of the other connector block, and hold the connector blocks together such that the electrical conductors within the grooves are in direct physical and electrical contact with the one another and are compressed. An electrical cable assembly incorporating such as connector and an method of manufacturing a cable assembly using such a connector is also presented.

Abstract: A data transmission cable assembly includes an elongate first conductor, an elongate second conductor, and a sheath at least partially axially surrounding the first and second conductors. The sheath contains a plurality of electrically conductive particles interspersed within a matrix formed of an electrically insulative polymeric material. The conductive particles may be formed of a metallic material or and inherently conductive polymer material. The plurality conductive particles may be filaments that form a plurality of electrically interconnected networks. Each network is electrically isolated from every other network. Each network contains less than 125 filaments and/or has a length less than 13 millimeters. The bulk conductivity of the sheath is substantially equal to the conductivity of the electrically insulative polymeric material. The data transmission cable assembly does not include a terminal that is configured to connect the sheath to an electrical ground.

Abstract: An electrically conductive hybrid polymer material is described herein. The hybrid polymer material includes 0.01% to 1% by weight of carbon nanoparticles, 1% to 10% by weight of a conductive polymeric material, 1% to 20% of electrically conductive fibers having a metallic surface and 69% or more by weight of a nonconductive polymeric base material. The carbon nanoparticles may be carbon nanotubes, graphite nanoparticles, graphene nanoparticles, and/or fullerene nanoparticles. The conductive polymeric material may be an inherently conductive polymer, a radical polymers, or an electroactive polymer. The electrically conductive fibers may be stainless steel fibers, metal plated carbon fibers, or metal nanowires. The nonconductive polymeric base material may be selected from materials that are pliable at temperatures between ?40° C. and 125° C. or materials that are rigid in this temperature range.

Abstract: A method of enhancing surface electrical conductivity of an article formed of a conductive polymer material, such as a conductive polymer film, includes the step of providing an article formed of a conductive polymer. The conductive polymer is made up of a dielectric polymeric material and conductive fibers. A desired pressure is applied to at least a portion of the article while simultaneously heating at least a portion of the article to a desired temperature. The desired pressure and the desired temperature are maintained on at least a portion of the article for a desired time period. This method reduces a polymer-rich skin layer on the surface of the conductive polymer material and helps to randomize the orientation of the conductive fibers on the surface.