A base plate having concave curved portions (rearward-convex parts) curved in a rearward direction to be convex and have a predetermined curvature, is fixed to a surface of a cooling fin while being in contact with the surface of the cooling fin at vertices of the rearward-convex parts. A stacked substrate is bonded on a front surface of the base plate, at an area opposing the rearward-convex part. A spacer is provided on a rear surface of the base plate, at a position closer than an edge of a solder layer to a perimeter of the base plate. The spacer is sandwiched between the base plate and the cooling fin when a screw for fixing the base plate to the cooling fin is tightened and the spacer has a function of suppressing deformation of the base plate.

A power electronic arrangement having a power semiconductor module and an external load-connecting element is provided with the external load-connecting element has a first connection device, and the power semiconductor module has a housing, a base plate and an internal load-connecting element with a second connection device, wherein the base plate has a first cut out through which the first connection device extends into the interior of the power semiconductor module and is connected there in a frictionally locking and electrically conductive fashion to a second connection device of the internal load-connecting element.

A semiconductor module includes: a printed circuit board having a first side and an opposite second side; a plurality of power semiconductor packages arranged over and electrically coupled to the first side of the printed circuit board, a first side of the power semiconductor packages facing the first side of the printed circuit board and an opposite second side being configured to be coupled to a heatsink; and at least one bus bar arranged over and electrically coupled to the first side of the printed circuit board. The bus bar is configured to carry a supply current and/or a ground current of at least some of the power semiconductor packages.

According to the present invention, a power module includes an insulating substrate, a semiconductor device provided on the insulating substrate, an internal terminal provided on the insulating substrate and electrically connected to the semiconductor device, a sealing material that seals the internal terminal, the semiconductor device and the insulating substrate so that an end portion of the internal terminal is exposed, a case that is separate from the sealing material and covers the sealing material and an elastic member that connects the case and the end portion of the internal terminal.

An apparatus including first and second substrates. The first and second substrates each include a base and at least one peripheral wall extending from the base. One of the at least one peripheral walls of the first or second substrates includes at least one well, and the other of the at least one peripheral walls of the first or the seconds substrate that does not include a well is mechanically anchored to the well. The apparatus includes a stack having a first and second end, and the stack is disposed on the base of the first and/or the second substrates at the first and/or second ends. The stack includes at least one element configured to generate energy. A method of assembling the apparatus by contacting the substrates.

A heat exchanger for cooling a plurality of heat-generating components with flat surfaces arranged in spaced parallel relation to one another has at least three flat, fluid-carrying panels, including a first end panel, a second end panel, and at least one middle panel. The middle panels have both of their opposed surfaces in thermal contact with a surface of a heat generating component. The end panels each have one surface in thermal contact with a surface of a heat-generating component. Inlet and outlet manifolds of the heat exchanger are in communication with the inlet and outlet openings of the middle panels. The inlet manifold communicates with the inlet opening of the first end panel, the outlet manifold communicates with the outlet opening of the second end panel, and the outlet opening of the first end panel communicates with the inlet opening of the second end panel.

In one general aspect, an apparatus can include a module including a semiconductor die. The apparatus can include a heatsink coupled to the module and including a substrate, and a plurality of protrusions. The apparatus can include a cover including a channel where the plurality of protrusions of the heatsink are disposed within the channel, and can include a sealing mechanism disposed between the cover and the module.

A microprocessor heat sink fastener, comprising a nut comprising a thermoplastic material and fibrous fill particles and a bore extending along an axis of the nut. The bore has internal threads. The internal threads comprise a surface. At least one of the fibrous fill particles has first and second ends extending from the surface into a sub-surface region.

A microprocessor carrier, comprising a frame comprising a metal. The first frame surrounds an aperture for receiving a microprocessor package. At least one hinge assembly is on a first frame edge, and at least one latch assembly is on a second frame edge. One or more alignment tabs coupled to the frame. The one or more alignment tabs extend orthogonally from at least one frame edge. The alignment tabs are to align the microprocessor package with a microprocessor socket. The hinge assembly and the latch assembly are to engage with a microprocessor loading mechanism coupled to a printed circuit board.

A microprocessor carrier comprising a lever having an elongate arm and a wedge structure extending from one end of the elongate arm, and a frame comprising and a fulcrum structure to receive the lever and a microprocessor. The fulcrum structure is to couple the lever to the frame.