Abstract: An aspect of the present embodiment, there is provided a semiconductor device, including an insulating substrate, at least one semiconductor chip provided above the insulating substrate, a wiring terminal including a connection portion electrically connected to the semiconductor chip, a surrounding frame surrounding the semiconductor chip and the connection portion, an embedded material provided in the surrounding frame covering the semiconductor chip and the connection portion, and a pressing unit provided on a surface of the embedded material.

Abstract: An aspect of the present embodiment, there is provided a semiconductor device, including an insulating substrate, at least one semiconductor chip provided above the insulating substrate, a wiring terminal including a connection portion electrically connected to the semiconductor chip, a surrounding frame surrounding the semiconductor chip and the connection portion, an embedded material provided in the surrounding frame covering the semiconductor chip and the connection portion, and a pressing unit provided on a surface of the embedded material.

Abstract: A semiconductor device includes a first semiconductor chip, a buffer body, and a terminal lead. The first semiconductor chip includes a first electrode and a second electrode provided on a side opposite to the first electrode. The first semiconductor chip is configured to allow a current to flow between the first electrode and the second electrode. The buffer body includes a lower metal foil, a ceramic piece, and an upper metal foil. The lower metal foil is electrically connected to the second electrode. The ceramic piece is provided on the second electrode with the lower metal foil interposed. The upper metal foil is provided on a side of the ceramic piece opposite to the lower metal foil to be electrically connected to the lower metal foil. The terminal lead has one end provided on the upper metal foil and electrically connected to the upper metal foil.

Abstract: According to one embodiment, a power module includes a metal base, a ceramic substrate, a semiconductor chip, a nut holder housing a nut, an electrode terminal and a casing. The ceramic substrate is connected to an upper surface of the metal base via a lower electrode. The semiconductor chip is located on a first major surface of the ceramic substrate. The electrode terminal includes a bent portion surrounding a nut holder. The electrode terminal includes a first connecting portion extending perpendicularly to the bent portion from one end of the bent portion, and being located on the first major surface via an upper electrode, and electrically connected to the semiconductor chip. A casing is bonded to the metal base to enclose the semiconductor chip and the electrode terminal. An upper end portion of the bent portion of the electrode terminal is exposed to outside of the casing through the opening.

Abstract: A semiconductor device includes a first semiconductor chip, a buffer body, and a terminal lead. The first semiconductor chip includes a first electrode and a second electrode provided on a side opposite to the first electrode. The first semiconductor chip is configured to allow a current to flow between the first electrode and the second electrode. The buffer body includes a lower metal foil, a ceramic piece, and an upper metal foil. The lower metal foil is electrically connected to the second electrode. The ceramic piece is provided on the second electrode with the lower metal foil interposed. The upper metal foil is provided on a side of the ceramic piece opposite to the lower metal foil to be electrically connected to the lower metal foil. The terminal lead has one end provided on the upper metal foil and electrically connected to the upper metal foil.

Abstract: According to one embodiment, a power module includes a metal base, a ceramic substrate, a semiconductor chip, a nut holder housing a nut, an electrode terminal and a casing. The ceramic substrate is connected to an upper surface of the metal base via a lower electrode. The semiconductor chip is located on a first major surface of the ceramic substrate. The electrode terminal includes a bent portion surrounding a nut holder. The electrode terminal includes a first connecting portion extending perpendicularly to the bent portion from one end of the bent portion, and being located on the first major surface via an upper electrode, and electrically connected to the semiconductor chip. A casing is bonded to the metal base to enclose the semiconductor chip and the electrode terminal. An upper end portion of the bent portion of the electrode terminal is exposed to outside of the casing through the opening.

Abstract: An insulating substrate (1) has insulative ceramic layers (2, 3) laid one upon another, an intermediate layer (4) made of a material that is different from a material of the ceramic layers and arranged between adjacent ones of the ceramic layers to join the adjacent ceramic layers to each other, a first conductive layer (5) joined to the top surface of a top one of the ceramic layers, and a second conductive layer (6) joined to the bottom surface of a bottom one of the ceramic layers. Even if any one of the ceramic layers has strength lower than design strength and causes a breakage due to, for example, thermal stress, the remaining ceramic layers are sound to secure a specified breakdown voltage for the insulating substrate.

Abstract: An insulating substrate (1) has insulative ceramic layers (2, 3) laid one upon another, an intermediate layer (4) made of a material that is different from a material of the ceramic layers and arranged between adjacent ones of the ceramic layers to join the adjacent ceramic layers to each other, a first conductive layer (5) joined to the top surface of a top one of the ceramic layers, and a second conductive layer (6) joined to the bottom surface of a bottom one of the ceramic layers. Even if any one of the ceramic layers has strength lower than design strength and causes a breakage due to, for example, thermal stress, the remaining ceramic layers are sound to secure a specified breakdown voltage for the insulating substrate.

Abstract: An insulating substrate (1) has insulative ceramic layers (2, 3) laid one upon another, an intermediate layer (4) made of a material that is different from a material of the ceramic layers and arranged between adjacent ones of the ceramic layers to join the adjacent ceramic layers to each other, a first conductive layer (5) joined to the top surface of a top one of the ceramic layers, and a second conductive layer (6) joined to the bottom surface of a bottom one of the ceramic layers. Even if any one of the ceramic layers has strength lower than design strength and causes a breakage due to, for example, thermal stress, the remaining ceramic layers are sound to secure a specified breakdown voltage for the insulating substrate.

Abstract: An insulating substrate (1) has insulative ceramic layers (2, 3) laid one upon another, an intermediate layer (4) made of a material that is different from a material of the ceramic layers and arranged between adjacent ones of the ceramic layers to join the adjacent ceramic layers to each other, a first conductive layer (5) joined to the top surface of a top one of the ceramic layers, and a second conductive layer (6) joined to the bottom surface of a bottom one of the ceramic layers. Even if any one of the ceramic layers has strength lower than design strength and causes a breakage due to, for example, thermal stress, the remaining ceramic layers are sound to secure a specified breakdown voltage for the insulating substrate.