A cooler (1) has a cooling plate (1a), a cooling fin (1b) provided on a center portion of a lower surface of the cooling plate (1a), and a lower projection (1c) provided on a peripheral portion of the lower surface of the cooling plate (1a). A semiconductor device (3) is provided on an upper surface of the cooling plate (1a). A bus bar (5) is connected to the semiconductor device (3). A cooling mechanism (8) encloses a lower surface and a lateral surface of the cooler (1). An O-ring (9) is provided between a lower surface of the lower projection (1c) and a bottom surface of the cooling mechanism (8). A bolt (10) penetrates a sidewall of the cooling mechanism (8) and screws the cooler (1) to the cooling mechanism (8).

A component (9) includes a first ceramic substrate (1), a ceramic fin cooler or a ceramic cooler through which liquid flows, having an upper face (1b) and a lower face (1a). A metallization (2) is applied to the upper face (1b), on which metallization a circuit (4) is mounted by its lower face. The circuit (4) of the component (9) is cooled on both sides by elements having high thermal conductivity and at the same time high electrical conductivity and thus the efficiency of the assembly is increased. A ceramic electrical/thermal conduction substrate (6) is attached by its lower face to the upper face of the circuit by a connection, and a second ceramic substrate (8) is arranged on the upper face of the electrical/thermal conduction substrate (6) via a metallization (7). The substrate (8) contains metal-filled thermal-electrical vias (11) and/or cooling channels to guide a coolant.

Provided is a joined body including: a first member; a second member; and a sintered metal layer that joins the first member and the second member. The sintered metal layer includes a structure that is derived from flake-shaped copper particles which are oriented in approximately parallel to an interface between the first member or the second member, and the sintered metal layer, and the amount of copper contained in the sintered metal layer is 65% by volume or greater on the basis of a volume of the sintered metal layer.

Provided are a semiconductor device which is provided with a circuit board and capable of suppressing an increase in its footprint, and a power conversion apparatus including the semiconductor device. The semiconductor device includes a circuit board, a power semiconductor element, an insulating block, a control signal terminal, a first main terminal, and a second main terminal. The insulating block is disposed so as to surround the power semiconductor element. The control signal terminal is inserted into the insulating block and thereby fixed to the insulating block. The control signal terminal includes a bent portion which partially protrudes above the power semiconductor element from the insulating block, and is bonded to the power semiconductor element. The first main terminal is bonded to the same power semiconductor element as the power semiconductor element to which the control signal terminal is bonded. The second main terminal is bonded to the circuit board.

A semiconductor device that is capable of suitably dissipating heat from a semiconductor chip is proposed. The proposed semiconductor device may include a semiconductor chip provided with a semiconductor substrate and a surface electrode provided on a surface of the semiconductor substrate; and a conductive plate provided with a plate shape portion and a convex portion protruding from the plate shape portion. An end surface of the convex portion may be corrected to the surface electrode. A width of the end surface of the convex portion may be narrower than a width of a base portion of the convex portion on a plate shape portion side.

A power semiconductor package includes a first direct bonded copper (DBC) substrate having a plurality of connection traces on a first face of the first DBC substrate. A plurality of die are coupled to the connection traces, each die coupled to one of the connection traces at a first face of the die. A second DBC substrate includes connection traces on a first face of the second DBC substrate. A second face of each die is coupled to one of the connection traces of the first face of the second DBC substrate. A cavity between the first face of the first DBC substrate and the first face of the second DBC substrate is filled with an encapsulating compound. Terminal pins may be coupled to connection traces on the first face of the first DBC substrate. More than two DBC substrates may be stacked to form a stacked power semiconductor package.

In a semiconductor device, a plurality of semiconductor chips included in an upper-arm circuit are connected in parallel between a pair of upper-arm plates, while a plurality of semiconductor chips included in a lower-arm circuit are connected in parallel between a pair of lower-arm plates. In each of the arm circuits, the plurality of semiconductor chips are arranged in a direction perpendicular to a direction in which emitter electrodes and pads are arranged, the pads are disposed on the same side of the emitter electrodes, and signal terminals extend in the same direction. A series-connecting part between the upper- and lower-arm circuits includes a joint part 20 continued to respective side surfaces of the corresponding upper- and lower-arm plates. Each of inductances of respective parallel-connecting parts of the upper- and lower-arm plates which connect the semiconductor chips in parallel is smaller than an inductance of the series-connecting part.

A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, the semiconductor chip having an upper surface on which a first electrode is disposed and a lower surface on which a second electrode is disposed; a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; a first clip frame disposed on the upper surface of the semiconductor chip; a first clip conductive connection member disposed between the first electrode on the semiconductor chip and a lower surface of the first clip frame, the first clip conductive connection member electrically connecting the first electrode of the semiconductor chip and the lower surface of the first clip frame; and a sealing resin for sealing the semiconductor chip, the die pad frame, the first clip frame, the first clip conductive connection member, and the conductive connection member for die pad.

A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; a first clip frame disposed on the upper surface of the semiconductor chip; a first dip conductive connection member disposed between the first electrode on the semiconductor chip and a lower surface of the first clip frame, the first clip conductive connection member electrically connecting the first electrode of the semiconductor chip and the lower surface of the first clip frame and a sealing resin.

An electronic device has a first bus bar (conductor plate) connected to a first semiconductor device (semiconductor part) having a first power transistor; and a second bus bar (conductor plate) connected to a second semiconductor device (semiconductor part) having a second power transistor. The first and second bus bars have first portions facing each other with an insulating plate interposed therebetween and extending in a Z direction intersecting with an upper surface (main surface) of a board. The first bus bar has a second portion located between the first portion and a terminal (exposed portion) and extending in an X direction away from the second bus bar and a third portion located between the second portion and the terminal and extending in the X direction. An extension distance of the third portion in the Z direction is shorter than an extension distance of the second portion in the X direction.