A semiconductor device having a semiconductor module. The semiconductor module includes first and second conductor layers facing each other, a first semiconductor element provided between the first and second conductor layers, positive and negative electrode terminals respectively provided on edge portions of the first and second conductor layers at a first side of the semiconductor module in a top view of the semiconductor module, control wiring that is electrically connected to the first control electrode, and that extends out of the first and second conductor layers at a second side of the semiconductor module that is opposite to the first side in the top view, and a control terminal that is electrically connected to the control wiring, that is positioned outside the first and second conductor layers in the top view, and that has an end portion that is aligned with the positive and negative electrode terminals.

A semiconductor device includes: multiple semiconductor elements each having a one surface and a rear surface in a plate thickness direction; a first member that sandwiches the multiple semiconductor elements and is electrically connected to an electrode on the one surface; a second member electrically connected to an electrode on the rear surface; and multiple terminals that are continuous from the first or second member. An area of the second member is smaller than that of the first member. Semiconductor elements are arranged in a longitudinal direction of the second member. The semiconductor device further includes a first joint portion that electrically connects each semiconductor element and the second member and a second joint portion that electrically connects a terminal and the second member. The multiple solder joint portions are symmetrically placed.

A method includes disposing a semiconductor die between a first high voltage isolation carrier and a second high voltage isolation carrier, disposing a first molding material in a space between the semiconductor die and the first high voltage isolation carrier, and disposing a conductive spacer between the semiconductor die and the second high voltage isolation carrier. The method further includes encapsulating the first molding material and the conductive spacer with a second molding material.

A method includes disposing a semiconductor die between a first high voltage isolation carrier and a second high voltage isolation carrier, disposing a first molding material in a space between the semiconductor die and the first high voltage isolation carrier, and disposing a conductive spacer between the semiconductor die and the second high voltage isolation carrier. The method further includes encapsulating the first molding material and the conductive spacer with a second molding material.

A planar power module includes a second substrate arranged parallel to a first substrate, with the substrates respectively having a dielectric layer interposed between two conductive layers, such that one of the conductive layers of each substrate together forms parallel external conductive surfaces of the power module. The power module includes direct current (DC) bus bars, alternating current (AC) bus bars, and semiconductor switching dies arranged between the substrates. The dies are electrically connected to the bus bars, with each respective die electrically connected to a conductive layers of the first or second substrates. A polymer molding material partially surrounds the substrates and the switching dies. An electric powertrain system includes an electric machine, a propulsion battery pack, and a traction power inverter module (TPIM) having the power module. The power module is a three-phase full-bridge inverter circuit. An electric powertrain and motor vehicle use the power module.

An electronic module has a first substrate 11, an electronic element 13, 23 disposed on one side of the first substrate 11, a second substrate 21 disposed on one side of the electronic element 13, 23, a first coupling body 210 disposed between the first substrate 11 and the second substrate 21, a second coupling body 220 disposed between the first substrate 11 and the second substrate 21, and shorter than the first coupling body 210, and a sealing part 90 which seals at least the electronic element. The first coupling body 210 is not electrically connected to the electronic element. The second coupling body 220 is electrically connected to the electronic element 13, 23.

A semiconductor device includes a first insulating circuit board, a semiconductor element on the first insulating circuit board, and an encapsulating body. The first insulating circuit board includes a first insulating substrate, and a first inner conductor layer, and a first outer conductor layer. The first inner conductor layer is electrically connected to a first electrode of the semiconductor element inside of the encapsulating body. The first outer conductor layer is exposed from a surface of the encapsulating body. The first inner conductor layer has a first thin-wall portion a thickness of which reduces toward an outer side, along an outer peripheral edge of the first inner conductor layer with a first width. The first outer conductor layer (i) does not have or (ii) has a second thin-wall portion along the outer peripheral edge of the first outer conductor layer with a second width.

A press-pack semiconductor fixture 200 includes a housing defining an interior passage. A first conductor and a second conductor are mechanically coupled with the housing. The mechanical coupling of the first conductor and the second conductor with the housing is effective to apply a clamping force to a press pack semiconductor. A number of apertures or openings are provided in the housing, the first conductor, and the second conductor to permit fluidic flow 290 between the interior passage 239 and spaces or structures exterior to the housing.

A press-pack semiconductor fixture 200 includes a housing defining an interior passage. A first conductor and a second conductor are mechanically coupled with the housing. The mechanical coupling of the first conductor and the second conductor with the housing is effective to apply a clamping force to a press pack semiconductor. A number of apertures or openings are provided in the housing, the first conductor, and the second conductor to permit fluidic flow 290 between the interior passage 239 and spaces or structures exterior to the housing.

A multiphase inverter apparatus includes: an insulating substrate; at least one low voltage bus and at least one high voltage bus on a first surface of the insulating substrate; a plurality of half-bridge circuits, each half-bridge circuit being electrically coupled between a respective one of the at least one low voltage bus and a respective one of the at least one high voltage bus; and a phase output lead for each half-bridge circuit. For each half bridge circuit, the phase output lead is arranged on and electrically coupled to at least one packaged low side switch and at least one packaged high side switch of the half bridge circuit such that each packaged low side switch and each packaged high side switch is arranged vertically between the phase output lead and the first surface of the insulating substrate.