A power module includes a substrate having a dielectric layer, a first power semiconductor device disposed on an upper part of the substrate, and a second power semiconductor device disposed on a lower part of the substrate.

A power semiconductor device including a first and second die, each including a plurality of conductive contact regions and a passivation region including a number of projecting dielectric regions and a number of windows. Adjacent windows are separated by a corresponding projecting dielectric region with each conductive contact region arranged within a corresponding window. A package of the surface mount type houses the first and second dice. The package includes a first bottom insulation multilayer and a second bottom insulation multilayer carrying, respectively, the first and second dice. A covering metal layer is arranged on top of the first and second dice and includes projecting metal regions extending into the windows to couple electrically with corresponding conductive contact regions. The covering metal layer moreover forms a number of cavities, which are interposed between the projecting metal regions so as to overlie corresponding projecting dielectric regions.

A power module apparatus includes a power module having a package configured to seal a perimeter of a semiconductor device, and a heat radiator bonded to one surface of the package; a cooling device having a coolant passage through which coolant water flows, in which the heat radiator is attached to an opening provided on a way of the coolant passage, wherein the heat radiator of the power module is attached to the opening of the cooling device so that a height (ha) and a height (hb) are substantially identical to each other. The power module in which the heat radiator is attached to the opening formed at the upper surface portion of the cooling device can also be efficiently cooled, and thereby it becomes possible to reduce degradation due to overheating.

A power module apparatus includes a power module having a package configured to seal a perimeter of a semiconductor device, and a heat radiator bonded to one surface of the package; a cooling device comprising a coolant passage through which coolant water flows, in which the heat radiator is attached to an opening provided on a way of the coolant passage, wherein the heat radiator of the power module is attached to the opening of the cooling device so that a height (ha) and a height (hb) are substantially identical to each other. The power module in which the heat radiator is attached to the opening formed at the upper surface portion of the cooling device can also be efficiently cooled, and thereby it becomes possible to reduce degradation due to overheating.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, amounting layer, switching elements, a moisture-resistant layer and a sealing resin. The substrate has a front surface facing in a thickness direction. The mounting layer is electrically conductive and disposed on the front surface. Each switching element includes an element front surface facing in the same direction in which the front surface faces along the thickness direction, a back surface facing in the opposite direction of the element front surface, and a side surface connected to the element front surface and the back surface. The switching elements are electrically bonded to the mounting layer with their back surfaces facing the front surface. The moisture-resistant layer covers at least one side surface. The sealing resin covers the switching elements and the moisture-resistant layer. The moisture-resistant layer is held in contact with the mounting layer and the side surface so as to be spanned between the mounting layer and the side surface in the thickness direction.

The invention relates to a power module. The power module has at least one power semiconductor and at least one further electronic component. The power module has a housing which is formed by a shaped body and is formed by an encapsulation compound. According to the invention, the housing is formed in at least two levels. At least one power semiconductor component is arranged in a first level and the at least one further electronic component is arranged in the second level. At least one electrically conductive layer, which forms an electrically conductive connecting structure, is formed on a surface of an inner boundary of the power module which extends between the levels. The connecting structure is applied directly to the surface. The at least one further electronic component is electrically conductively connected, in particular soldered or sintered, to the wiring structure. The power semiconductor component in the first level is electrically connected to the further component in the second level by means of the connecting structure.

A semiconductor package having a double-sided cooling structure includes an upper electrically conductive element having an outwardly exposed metal surface, a lower carrier substrate having an upper electrically conductive layer, a lower electrically conductive layer having an outwardly exposed surface, and an electrical insulation layer arranged between the upper and lower electrically conductive layers, a first electrically conductive spacer arranged between the upper electrically conductive element and the upper electrically conductive layer, a power semiconductor chip arranged between the upper electrically conductive element and the upper electrically conductive layer, a second electrically conductive spacer arranged between the upper electrically conductive element and the power semiconductor chip, and a shielding structure configured to electromagnetically shield a line of the semiconductor package.

A semiconductor module is disclosed. In one example, the module includes a carrier, at least one semiconductor transistor disposed on the carrier, at least one semiconductor diode disposed on the carrier, at least one semiconductor driver chip disposed on the carrier, a plurality of external connectors, and an encapsulation layer covering the carrier, the semiconductor transistor, the semiconductor diode, and the semiconductor driver chip. The semiconductor transistor, the semiconductor diode, and the semiconductor driver chip are arranged laterally side by side on the carrier.

The semiconductor device includes a semiconductor element, a first conductive member, a second conductive member, an insulating member, a first main terminal, and a second main terminal. The first main terminal and the second main terminal, respectively, extend from the first conductive member and the second conductive member. The first main terminal and the second main terminal, respectively, have a first projecting portion and a second projecting portion projecting outside of the insulating member. The first projecting portion and the second projecting portion, respectively, have a first facing portion and a second facing portion at which plate surfaces of the first and second projecting portions face each other across a gap, and a first non-facing portion and a second non-facing portion at which the plate surfaces of the first and second projecting portions do not face each other.

A semiconductor device includes a first die having ports and a second die having ports. The semiconductor device includes a multi-layer package substrate. The multi-layer package substrate includes a first layer patterned to include pads for the ports of the first die and the second die and a second layer patterned to provide vias between the pads for the ports of the first die and pads for the ports of the second die and a third layer of the multi-layer package substrate. The third layer is patterned to provide traces that couple the vias coupled to ports of the first die to vias coupled to ports of the second die to couple the first die to the second die, the traces of the third layer having a width. The multi-layer package substrate also includes a fourth layer underlying the third layer and a ground plane underlying the fourth layer.