Apparatus and method for assigning a material value score to a waste printed circuit board or a portion thereof and system for sorting waste printed circuit boards.

A conveyor system is configured to transport the electronic substrates through cleaning modules of a cleaning apparatus. The conveyor system includes a first outer frame member, a second outer frame member, a bottom belt assembly disposed between the first outer frame member and the second outer frame member, and a top belt assembly spaced from the bottom belt assembly. The bottom belt assembly and the top belt assembly are configured to an electronic substrate therebetween to transport the electronic substrate along the conveyor system and through the at least one cleaning module. The bottom belt assembly or the top belt assembly includes a mesh material belt fabricated from heat resistant synthetic fibers. The conveyor system further includes a plurality of pins secured to the bottom belt assembly or the top belt assembly to create at least one lane along a length of the conveyor system.

A conveyor system is configured to transport the electronic substrates through cleaning modules of a cleaning apparatus. The conveyor system includes a first outer frame member, a second outer frame member, a bottom belt assembly disposed between the first outer frame member and the second outer frame member, and a top belt assembly spaced from the bottom belt assembly. The bottom belt assembly and the top belt assembly are configured to an electronic substrate therebetween to transport the electronic substrate along the conveyor system and through the at least one cleaning module. The bottom belt assembly or the top belt assembly includes a mesh material belt fabricated from heat resistant synthetic fibers. The conveyor system further includes a plurality of pins secured to the bottom belt assembly or the top belt assembly to create at least one lane along a length of the conveyor system.

Aspects of the invention include a press-fit pin for mechanically and electrically connecting to a through-hole of a substrate. The press-fit pin can include a press-fit portion configured to be deformed upon insertion into the through-hole against a plated surface of the through-hole. A surface mount technology (SMT) pad can be coupled to a first end of the press-fit portion. The SMT pad can include a conductive material. The press-fit pin can further include a trace extension coupled to the SMT pad. The trace extension can extend from the SMT pad in a direction perpendicular to the press-fit portion. The press-fit pin can include a tip portion coupled to a second end of the press-fit portion.

In some examples, a method may include coupling a printed board assembly (PBA) to a fixture. In some examples, the PBA may include a printed board and a plurality of components that are electrically and mechanically coupled to the printed board, where each of the plurality of components defines a respective surface. The method may further include planarizing at least one of the respective surfaces of the plurality of components using an abrasive tool. The method may further include attaching a heat sink to the respective surfaces of the plurality of components. A system for planarizing surfaces of components attached to printed boards is also described.

Technologies are described for shielding electronic components. In one embodiment, a conductive gasket includes a gasket body. A conductive shield has a plurality of projections extending therefrom sufficient to deform the gasket body to couple the conductive shield and the conductive gasket together. The projections can be pointed teeth designed for penetrating the conductive gasket so as to electrically and mechanically couple the conductive shield to the conductive gasket. The conductive gasket can be stacked onto the conductive shield to form a sidewall, which can be mounted on a PCB. A conductive cover can then be placed on the conductive gasket to create a cavity in which electronic components can be positioned.

Technologies are described for shielding electronic components. In one embodiment, a conductive gasket includes a gasket body. A conductive shield has a plurality of projections extending therefrom sufficient to deform the gasket body to couple the conductive shield and the conductive gasket together. The projections can be pointed teeth designed for penetrating the conductive gasket so as to electrically and mechanically couple the conductive shield to the conductive gasket. The conductive gasket can be stacked onto the conductive shield to form a sidewall, which can be mounted on a PCB. A conductive cover can then be placed on the conductive gasket to create a cavity in which electronic components can be positioned.

The invention relates to a motor vehicle component support, in particular a motor vehicle door lock (1), and to a method for the production thereof. Said motor vehicle component support is equipped with a strip conductor structure (3) composed of several strip conductors (7). According to the invention, the strip conductor structure (3) comprises at least two conductor strip sub-structures (3a, 3b) which are electrically interconnected by means of at least one connecting element (8) which is applied later.

The method for separation of metals from electronic cards includes a step of processing the electronic cards in an aqueous medium under supercritical conditions. The method also a later step of crushing solid materials coming from the treatment under supercritical conditions.

The method for separation of metals from electronic cards includes a step of processing the electronic cards in an aqueous medium under supercritical conditions. The method also a later step of crushing solid materials coming from the treatment under supercritical conditions.