Abstract: It is an object to provide a pressure-contact power semiconductor device and a power semiconductor core module which are capable of properly reducing their sizes. Each power semiconductor core module includes the following: a plurality of power semiconductor chips including a plurality of self-turn-off semiconductor elements and a plurality of diodes adjacent to each other in plan view; and a plurality of first springs disposed between an upper metal plate and a conductive cover plate. The plurality of self-turn-off semiconductor elements of each power semiconductor core module are arranged along any one of an L-shaped line, a cross-shaped line, and a T-shaped line in plan view.

Abstract: A power semiconductor device driving circuit has a capacitor whose one end is connected with a first or a second main electrode of a power semiconductor device, a first switch for charging the capacitor and a control electrode of the power semiconductor device with electric charges, and a second switch for discharging electric charges; in the case where when the first switch turns on, the control electrode and the capacitor are charged with electric charges through different resistors, electric charges are discharged from the control electrode and the capacitor through one and the same resistor when the second switch turns on; in the case where when the first switch turns on, the control electrode and the capacitor are charged with electric charges through one and the same resistor, electric charges are discharged from the control electrode and the capacitor through different resistors when the second switch turns on.

Abstract: A power semiconductor module including a positive-side switching device and a positive-side diode device which are mounted on a positive-side conductive pattern, and a negative-side switching device and a negative-side diode device which are mounted on an output-side conductive pattern. When an insulating substrate is viewed in plan view, the positive-side diode device and the negative-side diode device are disposed between the positive-side switching device and the negative-side switching device, and the negative-side diode device is disposed closer to the positive-side switching device than the positive-side diode device is.

Abstract: A power semiconductor module includes: a positive arm and a negative arm that are formed by series connection of self-arc-extinguishing type semiconductor elements and that are connected at a connection point between the self-arc-extinguishing type semiconductor elements; a positive-side DC electrode, a negative-side DC electrode, and an AC electrode that are connected to the positive arm and the negative arm; and a substrate on which a wiring pattern is formed, the wiring pattern connecting the self-arc-extinguishing type semiconductor elements of the positive arm and the negative arm to the positive-side DC electrode, the negative-side DC electrode and the AC electrode. The positive-side DC electrode, the negative-side DC electrode, and the AC electrode are insulated from one another and arranged such that one of the electrodes faces each of the other two electrodes.

Abstract: A power semiconductor module includes: a positive arm and a negative arm that are formed by series connection of self-arc-extinguishing type semiconductor elements, the positive arm and the negative arm being connected at a series connection point between the self-arc-extinguishing type semiconductor elements; a positive-side electrode, a negative-side electrode, and an AC electrode connected to the positive arm and the negative arm; and a substrate on which a plurality of wiring patterns are formed, the wiring patterns connecting the self-arc-extinguishing type semiconductor elements of the positive arm and the negative arm to the positive-side electrode, the negative-side electrode, and the AC electrode. Respective directions of current flowing in adjacent wiring patterns are identical to each other, and one of the adjacent wiring patterns is arranged in mirror symmetry with the other of the adjacent wiring patterns.

Abstract: A short-circuit protection circuit for a self-arc-extinguishing type semiconductor element includes a first protection circuit and a second protection circuit. The first protection circuit is configured to reduce a voltage between a control electrode and a first main electrode of the self-arc-extinguishing type semiconductor element when detecting overcurrent flowing between the first main electrode and a second main electrode. The second protection circuit is configured to: detect current flowing in an interconnection adapted to supply the drive voltage; determine, based on the detected current, whether the first protection circuit is in an operating state; and change the drive voltage to turn off the self-arc-extinguishing type semiconductor element when the first protection circuit is in the operating state.

Abstract: A power semiconductor device driving circuit has a capacitor whose one end is connected with a first or a second main electrode of a power semiconductor device, a first switch for charging the capacitor and a control electrode of the power semiconductor device with electric charges, and a second switch for discharging electric charges; in the case where when the first switch turns on, the control electrode and the capacitor are charged with electric charges through different resistors, electric charges are discharged from the control electrode and the capacitor through one and the same resistor when the second switch turns on; in the case where when the first switch turns on, the control electrode and the capacitor are charged with electric charges through one and the same resistor, electric charges are discharged from the control electrode and the capacitor through different resistors when the second switch turns on.

Abstract: A power semiconductor module includes: a positive arm and a negative arm that are formed by series connection of self-arc-extinguishing type semiconductor elements and that are connected at a connection point between the self-arc-extinguishing type semiconductor elements; a positive-side DC electrode, a negative-side DC electrode, and an AC electrode that are connected to the positive arm and the negative arm; and a substrate on which a wiring pattern is formed, the wiring pattern connecting the self-arc-extinguishing type semiconductor elements of the positive arm and the negative arm to the positive-side DC electrode, the negative-side DC electrode and the AC electrode. The positive-side DC electrode, the negative-side DC electrode, and the AC electrode are insulated from one another and arranged such that one of the electrodes faces each of the other two electrodes.

Abstract: A power semiconductor module includes: a positive arm and a negative arm that are formed by series connection of self-arc-extinguishing type semiconductor elements, the positive arm and the negative arm being connected at a series connection point between the self-arc-extinguishing type semiconductor elements; a positive-side electrode, a negative-side electrode, and an AC electrode connected to the positive arm and the negative arm; and a substrate on which a plurality of wiring patterns are formed, the wiring patterns connecting the self-arc-extinguishing type semiconductor elements of the positive arm and the negative arm to the positive-side electrode, the negative-side electrode, and the AC electrode. Respective directions of current flowing in adjacent wiring patterns are identical to each other, and one of the adjacent wiring patterns is arranged in mirror symmetry with the other of the adjacent wiring patterns.

Abstract: A power semiconductor module includes a base plate as a metallic heat dissipating body, a first insulating layer on the base plate, and a first wiring pattern on the first insulating layer. On a predetermined region that is a part of the first wiring pattern, a second wiring pattern for a second layer is laminated via only a second insulating layer made of resin, thereby forming a pattern laminated region. A power semiconductor element is mounted in a region other than the pattern laminated region on the first wiring pattern. The base plate, the first insulating layer, the first wiring pattern, the second insulating layer, the second wiring pattern, and the power semiconductor element are integrally sealed with a transfer mold resin, thus obtaining the power semiconductor module.

Abstract: A power semiconductor module includes a base plate as a metallic heat dissipating body, a first insulating layer on the base plate, and a first wiring pattern on the first insulating layer. On a predetermined region that is a part of the first wiring pattern, a second wiring pattern for a second layer is laminated via only a second insulating layer made of resin, thereby forming a pattern laminated region. A power semiconductor element is mounted in a region other than the pattern laminated region on the first wiring pattern. The base plate, the first insulating layer, the first wiring pattern, the second insulating layer, the second wiring pattern, and the power semiconductor element are integrally sealed with a transfer mold resin, thus obtaining the power semiconductor module.