Abstract: A semiconductor module includes: a mounting substrate including a mounting surface; a semiconductor element disposed on the mounting surface; a housing for the semiconductor element; a lid fixed to the housing and facing the mounting surface; an insulating sealing material disposed in a space inside the housing and sealing the semiconductor element; and a first adsorbent disposed between the lid and the insulating sealing material and is swollen by adsorption.

Abstract: A semiconductor device includes an insulated substrate, a semiconductor element mounted on a first main surface side of the insulated substrate, and a case housing that houses the insulated substrate and the semiconductor element so that a second main surface side of the insulated substrate is exposed. The outer circumferential portion of the insulated substrate is bonded to the case housing. The case housing is provided with a screw hole at a position facing the first main surface side of the insulated substrate. The semiconductor device further includes a screw that is screwed into a screw hole in the case housing and has a tip portion that contacts the first main surface side of the insulated substrate.

Abstract: A semiconductor module includes a semiconductor chip; an insulating circuit board that has on one of principal surfaces of an insulating substrate a circuit member electrically connected to the semiconductor chip, and a first metal member disposed in the other principal surface of the insulating substrate; a second metal member that is disposed on a side of an outer edge of the first metal member and is at least partially disposed further toward an outer side than the insulating substrate; a molding resin portion that seals the semiconductor chip, the insulating circuit board, and the second metal member such that a portion of the first metal member and a portion of the second metal member are exposed; a cooler; a first bonding member that bonds the cooler and the first metal member; and a second bonding member that bonds the cooler and the second metal member.

Abstract: A semiconductor module is provided, including: a cooling-target device; a first cooling unit on which the cooling-target device is placed and that has a flow channel through which a refrigerant for cooling the cooling-target device flows; and a second cooling unit to which the first cooling unit is fixed and that has a flow channel coupled with the flow channel of the first cooling unit. Also, a semiconductor module manufacturing method is provided, including: placing a cooling-target device on a first cooling unit that has a flow channel through which a refrigerant for cooling the cooling-target device flows; and fixing the first cooling unit to a second cooling unit that has a flow channel coupled with the flow channel of the first cooling unit.

Abstract: A semiconductor module is provided, including: a cooling-target device; a first cooling unit on which the cooling-target device is placed and that has a flow channel through which a refrigerant for cooling the cooling-target device flows; and a second cooling unit to which the first cooling unit is fixed and that has a flow channel coupled with the flow channel of the first cooling unit. Also, a semiconductor module manufacturing method is provided, including: placing a cooling-target device on a first cooling unit that has a flow channel through which a refrigerant for cooling the cooling-target device flows; and fixing the first cooling unit to a second cooling unit that has a flow channel coupled with the flow channel of the first cooling unit.

Abstract: A cooler 20 of a semiconductor device includes an inlet portion 27 and an outlet portion 28 for a cooling liquid, an inlet path 24, an outlet path 25, and a cooling flow path 26. The inlet path 24 and the outlet path 25 have asymmetrical planar shapes. A connection portion 271 between the inlet path 24 and the inlet portion 27 is opposed to the cooling flow path 26 of a part immediately below plural circuit substrates 13 arranged on the cooler 20. A connection portion 281 between the outlet path 25 and the outlet portion 28 is opposed to the cooling flow path 26 of a part immediately below plural circuit substrates 13 arranged on the cooler 20.

Abstract: A cooler 20 of a semiconductor device includes an inlet portion 27 and an outlet portion 28 for a cooling liquid, an inlet path 24, an outlet path 25, and a cooling flow path 26. The inlet path 24 and the outlet path 25 have asymmetrical planar shapes. A connection portion 271 between the inlet path 24 and the inlet portion 27 is opposed to the cooling flow path 26 of a part immediately below plural circuit substrates 13 arranged on the cooler 20. A connection portion 281 between the outlet path 25 and the outlet portion 28 is opposed to the cooling flow path 26 of a part immediately below plural circuit substrates 13 arranged on the cooler 20.

Abstract: A semiconductor module includes a semiconductor chip; an insulating circuit board that has on one of principal surfaces of an insulating substrate a circuit member electrically connected to the semiconductor chip, and a first metal member disposed in the other principal surface of the insulating substrate; a second metal member that is disposed on a side of an outer edge of the first metal member and is at least partially disposed further toward an outer side than the insulating substrate; a molding resin portion that seals the semiconductor chip, the insulating circuit board, and the second metal member such that a portion of the first metal member and a portion of the second metal member are exposed; a cooler; a first bonding member that bonds the cooler and the first metal member; and a second bonding member that bonds the cooler and the second metal member.

Abstract: A semiconductor module cooler for supplying a refrigerant from exterior into a water jacket and cooling a semiconductor device disposed on an outer surface of the cooler, includes a heat sink thermally connected to the semiconductor device; a first flow path extending from a refrigerant inlet and arranged with a guide portion having an inclined surface for guiding the refrigerant toward one side surface of the heat sink; a second flow path extending toward a refrigerant outlet and formed with a sidewall parallel to the other side surface of the heat sink; a flow velocity adjustment plate disposed in the second flow path and formed parallel to the other side surface of the heat sink at a distance therefrom; and a third flow path formed at a position communicating the first flow path and the second flow path. The heat sink is disposed in the third flow path.

Abstract: A method for producing a semiconductor device includes solder-connecting a semiconductor chip, onto an insulating substrate including a ceramic board and having conductor layers on two surfaces thereof, with a lead-free solder; warping a radiating base such that a surface of the radiating base on a side opposite to the insulating substrate is convex; and solder-connecting the insulating substrate onto the warped radiating base with the lead-free solder so as to provide a substantially flat solder-connected radiating base.

Abstract: Provided is a semiconductor device comprising a cooler in which, by improving the shape of the connecting portions of an inlet/outlet of a coolant or the like, the pressure loss in the connecting portion or the like can be reduced. A cooler 20 of a semiconductor device 1 includes: an inlet 27 and an outlet 28 provided on side walls 22b1, 22b2 of a case 22 opposing to each other at diagonal positions; an introduction path 24 which is connected to the inlet 27 and formed in the case 22; a discharge path 25 which is connected to the outlet 28 and formed in the case 22; and a cooling flow channel 26 between the introduction path 24 and the discharge path 25. The height of the opening of the inlet 27 is larger than the height of the introduction path 24, and a connecting portion 271 between the inlet 27 and the introduction path 24 includes an inclined surface 271b which is inclined from the bottom surface of the connecting portion 271 toward the longitudinal direction of the introduction path 24.

Abstract: A cooling device for a semiconductor module supplying a coolant from outside into a water jacket and cooling a semiconductor element, includes a heat sink thermally connected to the semiconductor element; a first flow channel extending from a coolant introducing port and including a guide section having an inclined surface for guiding the coolant toward one side surface of the heat sink; a second flow channel disposed parallel to the first flow channel and extending toward a coolant discharge port; a flow velocity adjusting plate disposed in the second flow channel and formed parallel to the other side surface of the heat sink at a distance therefrom; and a third flow channel formed to communicate the first flow channel and the second flow channel. The heat sink is disposed in the third flow channel.

Abstract: A semiconductor module cooler supplies a coolant to a water jacket from outside and cools a semiconductor device arranged on an outer surface of the cooler. The semiconductor module cooler has a heat sink thermally connected to the semiconductor device; a first flow channel arranged inside the water jacket with a guide section extending from a coolant inlet and having an inclined surface for guiding the coolant toward one side surface of the heat sink; a second flow channel arranged inside the water jacket in parallel to the first flow channel and extending to a coolant outlet; and a third flow channel formed inside the water jacket at a position connecting the first flow channel and the second flow channel. The coolant inlet and the coolant outlet are formed on a same wall surface of the water jacket, and the heat sink is arranged in the third flow channel.

Abstract: The characteristics of a heat radiation member used in a semiconductor module are improved. A heat radiation member (10A) including an aluminum type member (20) which contains aluminum and a copper type member (30) which contains copper, which is embedded in the aluminum type member (20), and sides of which are enclosed by the aluminum type member (20) is formed. A semiconductor element is thermally bonded to the heat radiation member (10A) to fabricate a semiconductor module. The heat radiation member (10A) includes the aluminum type member (20) and the copper type member (30). As a result, it is possible to realize light weight while ensuring certain heat radiation. In addition, the copper type member (30) is enclosed by the aluminum type member (20). Accordingly, the strength of the heat radiation member (10A) can be increased.

Abstract: Provided is a semiconductor device comprising a cooler in which, by improving the shape of the connecting portions of an inlet/outlet of a coolant or the like, the pressure loss in the connecting portion or the like can be reduced. A cooler 20 of a semiconductor device 1 includes: an inlet 27 and an outlet 28 provided on side walls 22b1, 22b2 of a case 22 opposing to each other at diagonal positions; an introduction path 24 which is connected to the inlet 27 and formed in the case 22; a discharge path 25 which is connected to the outlet 28 and formed in the case 22; and a cooling flow channel 26 between the introduction path 24 and the discharge path 25. The height of the opening of the inlet 27 is larger than the height of the introduction path 24, and a connecting portion 271 between the inlet 27 and the introduction path 24 includes an inclined surface 271b which is inclined from the bottom surface of the connecting portion 271 toward the longitudinal direction of the introduction path 24.

Abstract: A semiconductor module including a cooling unit by which a fine cooling effect is obtained is provided. A plurality of cooling flow paths (21c) which communicate with both of a refrigerant introduction flow path which extends from a refrigerant introduction inlet and a refrigerant discharge flow path which extends to a refrigerant discharge outlet are arranged in parallel with one another in a cooling unit (20). Fins (22) are arranged in each cooling flow path (21c). Semiconductor elements (32) and (33) are arranged over the cooling unit (20) so that the semiconductor elements (32) and (33) are thermally connected to the fins (22). By doing so, a semiconductor module (10) is formed. Heat generated by the semiconductor elements (32) and (33) is conducted to the fins (22) arranged in each cooling flow path (21c) and is removed by a refrigerant which flows along each cooling flow path (21c).

Abstract: A semiconductor device includes an insulating substrate; a semiconductor element mounted on the insulating substrate; and a cooler cooling the semiconductor element. The cooler includes a heat radiating substrate bonded to the insulating substrate; a plurality of fins provided on a surface opposite to a surface bonded with the insulating substrate of the heat radiating substrate; and a case accommodating the fins, and including an inlet and an outlet for a coolant. Upper end portions of side walls of the case include cutaways to arrange end portions of the heat radiating substrate. The heat radiating substrate is liquid-tightly bonded to the case.

Abstract: A semiconductor module and a cooler capable of cooling a semiconductor element efficiently. The semiconductor module supplies a refrigerant to a water jacket configuring the cooler, to cool a circuit element part disposed on an outer surface of a fin base. This semiconductor module has: a fin connected thermally to the circuit element part; a refrigerant introducing passage in the water jacket, which has a guide part that has one surface and another surface inclined to guide the refrigerant toward one side surface of the fin; a refrigerant discharge passage disposed in the water jacket to be parallel to the refrigerant introducing passage, which has a side wall parallel to another side surface of the fin; and a cooling passage formed in a position for communicating the refrigerant introducing passage and the refrigerant discharge passage with each other in the water jacket. The fin is disposed in the cooling passage.

Abstract: A semiconductor module cooler for supplying a refrigerant from exterior into a water jacket and cooling a semiconductor device disposed on an outer surface of the cooler, includes a heat sink thermally connected to the semiconductor device; a first flow path extending from a refrigerant inlet and arranged with a guide portion having an inclined surface for guiding the refrigerant toward one side surface of the heat sink; a second flow path extending toward a refrigerant outlet and formed with a sidewall parallel to the other side surface of the heat sink; a flow velocity adjustment plate disposed in the second flow path and formed parallel to the other side surface of the heat sink at a distance therefrom; and a third flow path formed at a position communicating the first flow path and the second flow path. The heat sink is disposed in the third flow path.

Abstract: A cooling device for a semiconductor module supplying a coolant from outside into a water jacket and cooling a semiconductor element, includes a heat sink thermally connected to the semiconductor element; a first flow channel extending from a coolant introducing port and including a guide section having an inclined surface for guiding the coolant toward one side surface of the heat sink; a second flow channel disposed parallel to the first flow channel and extending toward a coolant discharge port; a flow velocity adjusting plate disposed in the second flow channel and formed parallel to the other side surface of the heat sink at a distance therefrom; and a third flow channel formed to communicate the first flow channel and the second flow channel. The heat sink is disposed in the third flow channel.