Provided are a semiconductor device and an inverter device with a decrease in yield being suppressed by preventing the adhesive from leaking into the inside of the semiconductor device. A heat sink, a wiring board provided on the heat sink, a semiconductor chip provided on the wiring board, a case housing provided on the heat sink so as to surround the wiring board and the semiconductor chip, an adhesive that adheres a lower surface joint portion of the case housing and an upper surface joint portion of the heat sink, a sealing material that fills the case housing and covers the wiring board and the semiconductor chip, and a convex portion provided on the lower surface joint portion of the case housing or the upper surface joint portion of the heat sink, that separates the adhesive from the sealing material are included.

A semiconductor device includes: an insulating substrate; a first conductor portion and a second conductor portion that are formed on the insulating substrate; a semiconductor element disposed on the first conductor portion; a first terminal that is connected to a first electrode of the semiconductor element; a second terminal that is connected to the first conductor portion; a connection member electrically connecting a control electrode of the semiconductor element and the second conductor portion to each other; a support member that is disposed at a predetermined distance from the second conductor portion; a pin terminal having that is supported in a state of being inserted through the support member and connected to the second conductor portion; and a sealing resin that seals the insulating substrate, the first conductor portion, the second conductor portion, the semiconductor element, the connection member, and the support member.

A terminal member connected to a connection target portion includes: a bent portion bent toward the connection target portion; and a tip connection portion provided at a tip part of the bent portion, in which the tip connection portion is connected to the connection target portion via a conductive bonding material.

A semiconductor device includes: plural conductor portions formed on an insulating substrate; a semiconductor element disposed on one of the plural conductor portions on the insulating substrate; a support member that is disposed at a predetermined distance from one of the plural conductor portions on the insulating substrate; a columnar pin terminal that is supported by the support member and is connected to the one of the plural conductor portions on the insulating substrate from which the support member is disposed at the predetermined distance; and a sealing resin that seals the insulating substrate, the plural conductor portions, the semiconductor element, and the support member. The support member has a through-hole having a polygonal shape and penetrating in a plate thickness direction of the support member, and the pin terminal is supported by the support member in a state in which the pin terminal is inserted through the through-hole.

Provided is a semiconductor package having a package housing in an engraved surface form and a method of manufacturing the same, wherein the semiconductor package includes: at least one substrate on which at least one semiconductor chip is installed; at least one terminal lead electrically connected to the substrates; electrical connectors for connecting the semiconductor chips to the substrates or the terminal leads; a package housing covering the semiconductor chips, the electrical connectors, and the at least one substrate; at least one stopper which is formed of a material same as that of the package housing, is higher by a certain height than exposed surfaces of the substrates, is disposed on the exposed surfaces of the substrates, or covers at least a part of the exposed surfaces; and at least one heat sink transmitting heat from the semiconductor chips and radiating heat, wherein the at least a part of the exposed surfaces of the at least one substrate is formed on the upper surface, the lower surface, or the upper and lower surfaces of the package housing and the exposed surfaces of the at least one substrate are joined to the heat sinks by using heat transfer connectors interposed therebetween. Accordingly, the full thickness of the heat transfer connectors may be uniformly maintained.

A semiconductor package includes a package substrate; semiconductor devices disposed on the package substrate; a package ring disposed on a perimeter of the package substrate surrounding the semiconductor devices; a cover including silicon bonded to the package ring and covering the semiconductor devices; and a thermal interface structure (TIS) thermally connecting the semiconductor devices to the cover.

The present invention relates to a power module comprising: an upper ceramic substrate (300); a PCB substrate (400) disposed spaced apart from the upper ceramic substrate (300); a plurality of semiconductor chips (G1, G2, G3, G4) spaced apart from each other, arranged in parallel, and mounted on the lower surface of the upper ceramic substrate (300); and a plurality of capacitors (310) mounted on the top surface of the PCB substrate (400) to correspond to locations between the semiconductor chips (G1, G2, G3, G4). The present invention has the advantage of forming a short current path through which the semiconductor chips and the capacitors are connected, thereby increasing a circuit stabilization effect.

A low parasitic inductance power module featuring staggered interleaving conductive members, including: at least one base extending in a length direction; a substrate on which at least one input bus bar and at least one output bus bar are provided; a first unit including a first circuit base portion disposed on the base in a width direction, a plurality of first power devices being disposed on the first circuit base portion, each first power device having a first current input end and a first current output end which are parallel connected, the first current input end or the first current output end being conducted to the first circuit base portion; and a second unit. The units are serially-connected to the bus bars via input conductive members and output conductive members arrayed in a staggered interleaving mode, whereby to create individual inductances counteracting with each other, reducing overall parasitic inductance.

A cooling device including a rectangular top plate in a plan view having a front surface on which a semiconductor module is disposed and a rear surface having a sidewall connection region, a flow pass region, and an outer edge region. The flow pass region includes a cooling region and first and second communicating regions that sandwich the cooling region therebetween from a short-side direction of the top plate. The sidewall connection region surrounds an outer periphery of the flow pass region. The outer edge region is outside of the sidewall connection region and closer to an edge of the top plate than is the flow pass region. The cooling region has a first thickness, and the outer edge region has a second thickness that is greater than the first thickness.

A semiconductor device includes: an insulating substrate; a semiconductor chip; a base plate; a first heat dissipating material; and a case. The semiconductor chip and a sealing material for sealing the semiconductor chip are housed in the case. The insulating substrate includes an insulating layer and a conductor pattern provided on an upper surface of the insulating layer. The semiconductor chip is joined onto the conductor pattern by a joining material. A lower surface of the insulating substrate and an upper surface of the base plate are in contact with each other with interposition of the first heat dissipating material. The insulating substrate and the base plate are not fixed to each other.