We disclose herein a semiconductor device sub-assembly comprising: a plurality of semiconductor units laterally spaced to one another; a semiconductor unit locator comprising a plurality of holes, wherein each semiconductor unit is located in each hole of the semiconductor unit locator; a plurality of pressure means for applying pressure to each semiconductor unit, and a conductive malleable layer located between the plurality of pressure means and the semiconductor unit locator.

A semiconductor package of a pin-grid-array type includes a bump pad on a first substrate, a metal socket on a second substrate, a core material for reverse reflow on the bump pad, and solder paste or a solder bump forming a solder layer on the core material for reverse reflow. The solder paste or the solder bump is in contact with the bump pad. The core material for reverse reflow and the solder paste or the solder bump bonded to the core material for reverse reflow are used as a pin and detachably attached to the metal socket. The core material for reverse reflow includes a core, a first metal layer directly coated on the core, and a second metal layer directly coated on the first metal layer.

A power semiconductor module includes a plurality of power semiconductor chips. A housing accommodates the power semiconductor chips. A first module electrode on a first side of the housing electrically is connected to a first chip electrode of the power semiconductor chips. A second module electrode on a second side of the housing electrically is connected to a second chip electrode. A surge arrester arrangement with a surge arrester is accommodated in the housing such that a first electrode of the surge arrester arrangement is provided at the first side of the housing and a second electrode of the surge arrester arrangement is provided at the second side of the housing. The power semiconductor chips are arranged in an annular region in the housing and the surge arrester arrangement is arranged within the annular region.

Various embodiments include a power module comprising: a first power electronics device arranged on a first substrate board; and a second power electronics device mounted on a second substrate board. The first substrate board, the first device, the second substrate board, and the second device are arranged on a first baseplate stacked above one another or in planar fashion beside one another.

A power module (PM) includes: an insulating substrate; a semiconductor device disposed on the insulating substrate, the semiconductor device including electrodes on a front surface side and a back surface side thereof; and a graphite plate having an anisotropic thermal conductivity, the graphite plate of which one end is connected to the front surface side of the semiconductor device and the other end is connected to the insulating substrate, wherein heat of the front surface side of the semiconductor device is transferred to the insulating substrate through the graphite plate. There is provide an inexpensive power module capable of reducing a stress and capable of exhibiting cooling performance not inferior to that of the double-sided cooling structures.

An object of the invention is to improve the reliability of a power semiconductor device. The power semiconductor device according to the invention includes a semiconductor element, a first terminal and a second terminal that transmit current to the semiconductor element, a first base and a second base that are disposed to face each other while interposing a part of the first terminal, a part of the second terminal, and the semiconductor element between the first base and the second base, and a sealing material that is provided in a space between the first base and the second base. The second terminal includes an intermediate portion formed in such a way that a distance from the first terminal increases along a direction away from the semiconductor element. The intermediate portion is provided between the first base and the second base and in the sealing material.

It is an object to provide a technique allowing for suppression of the height of a protrusion from the surface of a semiconductor module. A semiconductor device includes: a semiconductor module having a first groove; a Belleville washer having a recess in an outer surface and a protrusion on an inner surface; and a screw passing through the hole of the Belleville washer and the first groove of the semiconductor module to fasten the semiconductor module and an attached body. A head of the screw is accommodated in the recess of the Belleville washer, and at least portion of the protrusion of the Belleville washer is accommodated in the first groove of the semiconductor module.

A semiconductor module parallel circuit includes: a plurality of power semiconductor modules; and a multilayer substrate that interconnects the plurality of power semiconductor modules, each of the power semiconductor modules includes: a power semiconductor switching element; a first signal terminal connected to a gate potential of the power semiconductor switching element; and a second signal terminal connected to a source potential of the power semiconductor switching element, the multilayer substrate includes: an external connection terminal; first signal terminal connection patterns connected to the first signal terminals of the power semiconductor modules; and second signal terminal connection patterns connected to the second signal terminals of the power semiconductor modules, and inductances of gate wiring for the plurality of power semiconductor modules, from the external connection terminal to the first signal terminal connection pattern and from the second signal terminal connection pattern to the external connection terminal are equal to one another.

The present invention relates to a power module comprising: a lower ceramic substrate (200); an upper ceramic substrate (300) which is disposed above the lower ceramic substrate (200) and has a semiconductor chip (G) mounted on the lower surface thereof; a PCB substrate (400) disposed above the upper ceramic substrate (300); and a connection pin (800) which extends through through holes (320 and 420) formed in the upper ceramic substrate (300) and the PCB substrate (400), and vertically connects electrode patterns (a, b, c, and d) formed on the upper ceramic substrate (300) and the PCB substrate (400). The present invention provides a shortened electrical connection distance between the upper ceramic substrate and the PCB substrate, and thus can minimize a current path and enhance the moving efficiency of a high-speed current.

A semiconductor structure includes an insulating encapsulant, a semiconductor element, a redistribution layer and an insulating layer. The semiconductor element is embedded in the insulating encapsulant. The redistribution layer is disposed over the insulating encapsulant and electrically connected to the semiconductor element. The insulating layer is disposed in between the insulating encapsulant and the redistribution layer, wherein an uneven interface exists between the insulating layer and the insulating encapsulant, and a planar interface exists between the insulating layer and the redistribution layer.