A device for orienting contact terminals on an electrical component such that they fit to a circuit board of an electric circuit is disclosed. In an embodiment the device includes a carrier element configured to receive the electrical component and a plurality of bending elements, wherein the carrier element has a plurality of holes, each hole penetrating the carrier element from an upper side to an underside, wherein a respective section of the bending elements is secured to the carrier element and a respective end of the bending elements projects into a respective hole of the carrier element, and wherein the bending elements are configured such that the respective end of the bending elements, upon insertion of a respective contact terminal of the electrical component into the respective hole from the upper side of the carrier element, is bent within the hole and clamps the respective contact terminal.

A semiconductor device includes a semiconductor element, a circuit board, metal wires, and an expanding member. The circuit board has an upper surface and a lower surface opposite the upper surface. The metal wires are formed on at least one of the upper surface and the lower surface. At least two connection terminals are formed in a terminal formation surface of the semiconductor element which is disposed so as to face the upper surface of the circuit board. The expanding member is fixed to the terminal formation surface of the semiconductor element, has a larger coefficient of linear thermal expansion than the semiconductor element, and has a size larger than the interval between adjacent two of the at least two connection terminals.

An apparatus is provided with a component configured with an interface comprising a resilient material. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to the temperature that meets or exceeds the transition temperature of interface causes the resilient material to undergo a state change. The state change of the interface alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment thereby mitigating damage to the substrate and/or component.

The protective housing can cover at least one component on the circuit board; the interior of the cover has several protrusions that are built, so that at least one part is displaced by raising the protective housing on at least one component, so that it is in contact with the exterior contour of the component and fastens it. Moreover, a circuit board is provided with at least one protective housing.

A ceramic electronic component includes an electronic component body and portions of first and second metal terminals covered with an outer resin material. The first metal terminal includes, connected in order, a first terminal joint portion, a first extension portion extending in a direction toward a mounting surface, and a first mount portion extending toward a side opposite to the electronic component body. The second metal terminal includes, connected in order, a second terminal joint portion, a second extension portion extending in the direction toward the mounting surface, and a second mount portion extending toward a side opposite to the electronic component body. The first and second mount portions respectively include first and second protrusions protruding toward the mounting surface. The outer resin material includes a protruding portion protruding toward the mounting surface.

A component embedded package carrier includes a core layer, at least one electronic component, a first insulating layer, a second insulating layer, a third patterned conductive layer, a fourth patterned conductive layer, a plurality of conductive blind via structures, a first protecting layer and a second protecting layer. The electronic component is disposed inside an opening of the core layer. The first and second insulating layers completely fill the opening and completely encapsulate the electronic component. The conductive blind via structures connect the third and fourth patterned conductive layers with a plurality of conductive through hole structures of the core layer, and connect the third and fourth patterned conductive layers with the electronic component. The first protecting layer covers the third patterned conductive layer and has a first roughness surface. The second protecting layer covers the fourth patterned conductive layer and has a second roughness surface.

The present disclosure provides a bracket for an electronic component. The bracket includes a bearing part configured to bear an electronic component and two side walls. The two side walls are oppositely arranged and disposed at the same side of the bearing part. The two side walls of the bracket are configured to be disposed on a mainboard and define together with the mainboard and the two side walls an accommodating space. The present disclosure further provides an electronic component assembly and a mobile terminal.

An apparatus is provided with a component configured to be operatively coupled to an interface. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to a thermal event that meets or exceeds a first temperature the resilient material is subject to undergo a state change to a second state. The state change includes a physical transformation of the interface, and includes a position change of the component.

The present disclosure relates to a substrate apparatus and a method of manufacturing a substrate apparatus capable of improving a manufacturing quality and reliability of the substrate apparatus as an electronic device. By laminating a plurality of sheet-like substrates on which a wiring pattern is formed, an individual substrate in which internal wiring is formed is formed, and the individual substrate physically and electrically connects two substrates. The present disclosure is capable of being applied to the substrate apparatus.

An apparatus is provided with a component configured with an interface comprising a resilient material. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to the temperature that meets or exceeds the transition temperature of interface causes the resilient material to undergo a state change. The state change of the interface alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment thereby mitigating damage to the substrate and/or component.