To improve the characteristics of a compound adapted to create inside an electrically conductive track or area, the compound comprising a solvent, a polymer with double covalent conjugate bond, namely a heterocyclic compound formed by n carbon atoms and one atom of a different type linked in a ring structure; and a dispersion of conductive particles, there is added an agent adapted to slow down the precipitation of the conductive particles within the material.

Illustrative embodiments of anisotropic conductive adhesive (ACA) and associated methods are disclosed. In one illustrative embodiment, the ACA may comprise a binder curable using UV light and a plurality of particles suspended in the binder. Each of the plurality of particles may comprise a ferromagnetic material coated with a layer of electrically conductive material. The electrically conducting material may form electrically conductive and isolated parallel paths when the ACA is cured using UV light after being subjected to a magnetic field.

In a method for jetting a droplet of an electrically conductive fluid, a Lorentz force is generated in the electrically conductive fluid. The Lorentz force is directed into an actuation direction. The actuation direction is a direction opposite to the droplet ejection direction. A jetting device is provided for printing a droplet of an electrically conductive fluid.

Examples are disclosed that relate to magnetically aligned switching circuits. One disclosed example provides an electronic component comprising a first terminal, a second terminal, and a deformable host material arranged between the first terminal and the second terminal. Aligned magnetically within the host material is an ensemble of particles each comprising a ferromagnetic material, each particle having greater electrical conductivity than the host material. The ensemble of particles is configured to form at least one complete conduction path from the first terminal to the second terminal.

Electronics assemblies and methods of manufacturing electronics assemblies having improved thermal performance. One example of these electronics assemblies includes a printed circuit board (PCB), an integrated circuit package mounted to the PCB, the integrated circuit packing having a heat generating component, and a heat spreader soldered to the PCB such that the heat spreader is thermally coupled to the heat generating component of the integrated circuit package to dissipate heat generated by the heat generating component.

An apparatus is described. The apparatus includes a semiconductor chip package loading assembly having a heat sink and a first magnetic material, the first magnetic material to be mechanically coupled to a first side of a printed circuit board that is opposite a second side of the printed circuit board where input/outputs (I/Os) of the semiconductor chip package interface with the printed circuit board. The first magnetic material to be positioned between the printed circuit board and a second magnetic material. The first magnetic material is to be magnetically attracted to the second magnetic material to impede movement of the heat sink.

A manufacturing method of an anisotropic conductive film and an apparatus thereof are provided. The manufacturing method of an anisotropic conductive film includes steps of: (a) providing a first substrate having metal contacts; (b) disposing a resin layer on the first substrate and covering the metal contacts; (c) providing a press head having a suction pattern arranged corresponding to the metal contacts; (d) sucking the conductive particles by the press head; and (e) pressing the conductive particles into the resin layer by the press head. The conductive particles are disposed corresponding to the metal contacts of the substrate, so that the problem about the short circuit between contacts can be improved, and the product yield and reliability can also be improved.

There is provided a method for manufacturing a substrate with a sensor in which a sensor is disposed on a plate-shaped substrate. The method comprises: holding the sensor by a magnetic force from a position on an opposite surface of a surface of the plate-shaped substrate on which the sensor is disposed that corresponds to a position where the sensor is fixed; and fixing the sensor to the plate-shaped substrate by curing an adhesive attached to the sensor in a state where the sensor is held by the magnetic force.

The purpose of the present disclosure is to provide electro-conductive particles and a signal-transmitting connector having same, wherein the electro-conductive particles are improved to prevent the phenomenon of irregular scrub between the electro-conductive particles and to have improved signal delivery characteristics. Electro-conductive particles according to the present disclosure are provided on a signal-transmitting connector having multiple electroconductive portions supported by an insulating portion made of an elastic insulating material to be spaced apart from each other such that the signal-transmitting connector can be connected to an electronic component and can transmit electric signals.

The invention describes a method of manufacturing an LED carrier assembly, which method comprises the steps of providing a carrier comprising a mounting surface with mounting pads arranged to receive a number of LED dies; embedding an alignment magnet in the carrier; providing a number of LED dies, wherein an LED die comprises a number of magnetic die pads; and aligning the magnetic die pads to the mounting pads by arranging the LED dies over the mounting surface of the carrier within magnetic range of the alignment magnet. The invention also describes an LED carrier assembly.