A mold test apparatus includes a mold support plate having a top surface on which a mold is mounted, wherein the mold support plate includes a plurality of test suction pipes communicating with paths in the mold, vacuum pipes each having one end connected to one of the plurality of test suction pipes, a pump connected to the other end of the pipe, and at least one pressure sensor configured to measure a pressure of the vacuum pipe, wherein the paths communicate with adsorption holes provided in a top surface of the mold, and wherein the at least one pressure sensor includes a determining unit configured to determine whether the adsorption holes are clogged by using the measured pressure.

Provided is a resin molding apparatus that can suppress a molding problem caused by a variation in a thickness of an object to be molded or suppress a variation in a thickness of a resin molded part, and can perform a mold releasing operation. A resin molding apparatus includes: a molding mold having one mold and the other mold; one mold wedge mechanism; and one mold cavity block driving mechanism. In a state that a height position of one mold cavity block is set using the one mold cavity block driving mechanism and a position in a direction away from the other mold in the one mold cavity block having been moved to the height position is fixed to be limited using the one mold wedge mechanism, a mold releasing operation can be performed using the one mold wedge mechanism and the one mold cavity block driving mechanism.

A manufacturing equipment, for manufacturing a molded circuit board assembly of a camera module, includes an upper mould, a lower mould, a mould fixing arrangement, and a temperature controlling arrangement, wherein the mould fixing arrangement controls opening and closing of the upper mould and the lower mound. When a substrate board is placed between the upper mould and the lower mound, a molding cavity is further formed between the upper mould and the lower mound, wherein in the molding cavity, a supporting frame forming groove is formed for forming the module support, and a light window forming element is used for forming a light window. The temperature controlling arrangement provides a molding temperature, the module supporting frame is integrally molded on the substrate board to form the molded circuit board assembly.

A method for manufacturing an electronic assembly and electronic assemblies are presented. The method includes obtaining a substrate film for accommodating electronics, providing at least an electrical contact pad to the substrate film, coupling an electrically conductive member to the electrical contact pad, and molding, such as injection molding, a material layer onto the substrate film to embed the elastic electrically conductive member utilizing a mold structure defining a cavity for molding. The elastic electrically conductive member is arranged to extend during the molding from the electrical contact pad through the cavity to be in contact with an element on a different side of the cavity with respect to the electrical contact pad for maintaining at least a part of the elastic electrically conductive member accessible after the molding to provide an electrical connection through the material layer to the electrical contact pad.

A method for manufacturing, by a transfer mold method, a power module equipped with a heat conductive insulating sheet in which an inorganic filler including secondary aggregated particles formed by aggregation of primary particles of scaly boron nitride is dispersed in a thermosetting resin, where curing of an uncured or semi-cured heat conductive insulating sheet during transfer molding is advanced under specific conditions. The method for manufacturing a power module equipped with a heat conductive insulating sheet has excellent thermal conductivity and electric insulation ability.

A method, for manufacturing an electronic assembly, such as an antenna or a capacitive sensing device or a coupled inductor, comprising at least a first electrically conductive element and a second electrically conductive element is presented. The method comprises obtaining said electrically conductive elements, such as patch elements, arranging said electrically conductive elements, such as inside of a cavity defined by a mold structure, at a pre-defined distance from each other for establishing an electromagnetic coupling between said electrically conductive elements, and molding, such as injection molding, a molding material layer at least between said electrically conductive elements, wherein the molding material layer has a thickness between said electrically conductive elements defined by the pre-defined distance. In addition, electronic assemblies, antennas, capacitive sensing devices and coupled inductors are presented.

A method for manufacturing an electronic assembly and electronic assemblies are presented. The method includes obtaining a substrate film for accommodating electronics, providing at least an electrical contact pad to the substrate film, coupling an electrically conductive member to the electrical contact pad, and molding, such as injection molding, a material layer onto the substrate film to embed the elastic electrically conductive member utilizing a mold structure defining a cavity for molding. The elastic electrically conductive member is arranged to extend during the molding from the electrical contact pad through the cavity to be in contact with an element on a different side of the cavity with respect to the electrical contact pad for maintaining at least a part of the elastic electrically conductive member accessible after the molding to provide an electrical connection through the material layer to the electrical contact pad.

A method for manufacturing an electronic assembly and electronic assemblies are presented. The method includes obtaining a substrate film for accommodating electronics, providing at least an electrical contact pad to the substrate film, coupling an electrically conductive member to the electrical contact pad, and molding, such as injection molding, a material layer onto the substrate film to embed the elastic electrically conductive member utilizing a mold structure defining a cavity for molding. The elastic electrically conductive member is arranged to extend during the molding from the electrical contact pad through the cavity to be in contact with an element on a different side of the cavity with respect to the electrical contact pad for maintaining at least a part of the elastic electrically conductive member accessible after the molding to provide an electrical connection through the material layer to the electrical contact pad.

An apparatus includes a mold chase, which includes a top portion and an edge ring having a ring-shape. The edge ring is underlying and connected to an edge of the top portion. The edge ring has an injection port and a venting port. A molding guide kit is configured to be inserted into the injection port. The molding guide kit includes a front sidewall having a curved front edge.

A manufacturing method of a molded photosensitive assembly of an array imaging module includes the steps of providing an enclosing element at a mold engaging surface of a first mold body of a mold; receiving the circuit board in the mold and positioning between the first mold body and a second mold body; introducing a fluid state mold material into the closed mold to fill the mold cavity and enclose the electronic elements; solidifying the mold material in the mold cavity and forming a molded base integrated with the circuit board and the electronic elements; and separating the first mold body and the second mold body and obtaining a molded photosensitive assembly which is an integrated body of the circuit board, the electronic elements.