Provided is a technique for improving product attachment. In a semiconductor device, the following expression is satisfied by an angle A formed by an imaginary line connecting two attachment holes together and an imaginary line connecting together a lowest point of one of two projections positioned in a surrounding portion of one of the two attachment holes and a contact point between a bulge and a heat sink, with a screw fastened to the heat sink through the one attachment hole, where M represents a vertical direction between the lower end of a body and the lower end of a case, where W represents a bulge amount of the bulge, where T represents a height of the projection, where L represents a horizontal distance from the outer peripheral end of the case to the outer peripheral end of the heat dissipation plate: 0<A<arctan((M+WT)/L).

A stacked heat exchanger includes: passage tubes stacked with each other to support a heat exchange object, a passage being defined in the passage tube for a heat medium to exchange heat with the heat exchange object; and a pipe connected to one of the passage tubes located at one end in a stacking direction of the plurality of passage tubes. Each of the passage tubes has a protruding pipe portion protruding in the stacking direction and communicating with the adjacent passage tube in the stacking direction. The one of the passage tubes located at the one end in the stacking direction is an in/out passage tube. The pipe has a surface at one end in a longitudinal direction of the pipe, and the surface intersects the longitudinal direction of the pipe and is joined to the in/out passage tube.

An electromagnetic wave absorption sheet is arranged to contact an upper surface and side surfaces of an electronic component mounted on a wiring board, a heat conduction plate is arranged to contact the electromagnetic wave absorption sheet, a heat transfer sheet is arranged to contact the heat conduction plate, and a heat dissipation member is arranged to contact the heat transfer sheet. Heat conductive particles contained in the heat transfer sheet contact a flat surface portion of the heat conduction plate. The electromagnetic wave absorption sheet, the heat conduction plate, and the heat transfer sheet are interposed between the heat dissipation member and the electronic component, as a heat conduction member for conducting heat generated in the electronic component and the like to the heat dissipation member.

An optical module includes a housing having an upper cover and a lower cover; a substrate having a circuit device mounted on its first surface; a heat dissipation member configured to be in contact with the circuit device mounted on the substrate; and at least one inner case having stiffness, wherein the upper cover is disposed facing the first surface of the substrate, and the lower cover is disposed facing a second surface of the substrate, and the inner case is disposed so as to press the substrate from the second surface of the substrate toward the upper cover.

The present embodiments provide a photoelectric conversion device having a laminate structure of a substrate, a transparent electrode, an active layer, and a counter electrode, stacked in this order. In the device, a cavity is provided on the counter electrode-side. The cavity penetrates through the counter electrode and has an opening area larger in the counter electrode than in the active layer.

Provided is a technique for improving product attachment. In a semiconductor device, the following expression is satisfied by an angle A formed by an imaginary line connecting two attachment holes together and an imaginary line connecting together a lowest point of one of two projections positioned in a surrounding portion of one of the two attachment holes and a contact point between a bulge and a heat sink, with a screw fastened to the heat sink through the one attachment hole, where M represents a vertical direction between the lower end of a body and the lower end of a case, where W represents a bulge amount of the bulge, where T represents a height of the projection, where L represents a horizontal distance from the outer peripheral end of the case to the outer peripheral end of the heat dissipation plate: 0<A<arctan ((M+WT)/L).

Manufacturing method for an electronic device comprises a step of placing a substrate 10, which has a metal plate 11 on a back-surface side, on a back-surface-side mold 110 having a mold recessed part 111, a step of placing a front-surface-side mold 120 on the back-surface-side mold so as to cover the substrate 10; and a step of pouring resin between the front-surface mold 100 and the back-surface-side mold 110, when the substrate 10 is pressed against the back-surface-side mold 110. Circumferential part of the metal plate 11 is in contact with an edge of the mold recessed part 111 when the substrate 10 is pressed against the back-surface-side mold 110 in the step of pouring resin.

A clamping assembly includes a configuration of mechanically clamped components disposed one on top of the other to form a stack. A clamping device generates a mechanical compressive force on the configuration of the components and a pressure element transmits the mechanical compressive force from the clamping device to the configuration. The pressure element contains a metal foam for a planar, homogeneous transmission of the compressive force. A sub module of a converter having at least one series circuit of power semiconductor switching units implemented as the clamping apparatus is also provided.

A power semiconductor module having a pressure application body, a circuit carrier, which is embodied with a first conductor track, a power semiconductor element arranged thereon and an internal connecting device, and also having a housing which is embodied with a guide device arranged therein, with a connecting element. The connecting element is embodied as a bolt with first and second end sections and an intermediate section therebetween, wherein the first end section rests on the circuit carrier and is electrically conductively connected thereto; the second end section projects out of the housing through a cutout; and wherein the connecting element is arranged in the assigned guide device. The pressure application body has a first rigid partial body and a second elastic partial body, wherein the second partial body protrudes out of the first partial body in the direction of the housing.

The present invention relates to a lightweight liquid-cooling-plate assembly having a plastic frame and a heat dissipation system using the same. The liquid-cooling-plate assembly includes a plastic frame and at least one coolant chamber unit. The plastic frame includes a plurality of lateral walls, at least one accommodation opening, and a plurality of fastening elements. The lateral walls are connected with each other to form and define the at least one accommodation opening. The fastening elements are disposed on a part of the lateral walls. The coolant chamber unit is connected with the plastic frame and embedded in the at least one accommodation opening, and includes at least one surface exposed.