A power converting device such that an overcurrent is interrupted and damage to a power semiconductor element can be prevented is obtained. The power converting device includes a power semiconductor element, a wiring member connected to an electrode of the power semiconductor element, a bus bar that supplies power to the power semiconductor element, and a frame that houses the power semiconductor element, wherein the bus bar has a connection terminal connected to the wiring member, and a fuse portion is provided in the connection terminal.

A power converting device such that an overcurrent is interrupted and damage to a power semiconductor element can be prevented is obtained. The power converting device includes a power semiconductor element, a wiring member connected to an electrode of the power semiconductor element, a bus bar that supplies power to the power semiconductor element, and a frame that houses the power semiconductor element, wherein the bus bar has a connection terminal connected to the wiring member, and a fuse portion is provided in the connection terminal.

A power converting device such that an overcurrent is interrupted and damage to a power semiconductor element can be prevented is obtained. The power converting device includes a power semiconductor element, a wiring member connected to an electrode of the power semiconductor element, a bus bar that supplies power to the power semiconductor element, and a frame that houses the power semiconductor element, wherein the bus bar has a connection terminal connected to the wiring member, and a fuse portion is provided in the connection terminal.

A power converting device such that an overcurrent is interrupted and damage to a power semiconductor element can be prevented is obtained. The power converting device includes a power semiconductor element, a wiring member connected to an electrode of the power semiconductor element, a bus bar that supplies power to the power semiconductor element, and a frame that houses the power semiconductor element, wherein the bus bar has a connection terminal connected to the wiring member, and a fuse portion is provided in the connection terminal.

A power module of a square flat pin-free packaging structure for suppressing the power module from being excessively high in local temperature. The power module includes an insulating resin, a driving chip, a plurality of power chips, and a plurality of metal electrode contacts. The driving chip, the power chips, and the metal electrode contacts are electrically connected through a metal lead according to a predetermined circuit. A plurality of metal heat dissipating disks used for heat dissipation of the power chips and a driving chip lead frame are disposed at the bottom of the insulating resin. A plurality of metal power chip lead frames are disposed on the metal heat dissipating disks, the power chips are disposed on the power chip lead frames, and the drain electrodes of the power chips are electrically connected to the metal heat dissipating disks.

A power module of a square flat pin-free packaging structure for suppressing the power module from being excessively high in local temperature. The power module includes an insulating resin, a driving chip, a plurality of power chips, and a plurality of metal electrode contacts. The driving chip, the power chips, and the metal electrode contacts are electrically connected through a metal lead according to a predetermined circuit. A plurality of metal heat dissipating disks used for heat dissipation of the power chips and a driving chip lead frame are disposed at the bottom of the insulating resin. A plurality of metal power chip lead frames are disposed on the metal heat dissipating disks, the power chips are disposed on the power chip lead frames, and the drain electrodes of the power chips are electrically connected to the metal heat dissipating disks.

A power module of a square flat pin-free packaging structure for suppressing the power module from being excessively high in local temperature. The power module includes an insulating resin, a driving chip, a plurality of power chips, and a plurality of metal electrode contacts. The driving chip, the power chips, and the metal electrode contacts are electrically connected through a metal lead according to a predetermined circuit. A plurality of metal heat dissipating disks used for heat dissipation of the power chips and a driving chip lead frame are disposed at the bottom of the insulating resin. A plurality of metal power chip lead frames are disposed on the metal heat dissipating disks, the power chips are disposed on the power chip lead frames, and the drain electrodes of the power chips are electrically connected to the metal heat dissipating disks.

A power module of a square flat pin-free packaging structure for suppressing the power module from being excessively high in local temperature. The power module includes an insulating resin, a driving chip, a plurality of power chips, and a plurality of metal electrode contacts. The driving chip, the power chips, and the metal electrode contacts are electrically connected through a metal lead according to a predetermined circuit. A plurality of metal heat dissipating disks used for heat dissipation of the power chips and a driving chip lead frame are disposed at the bottom of the insulating resin. A plurality of metal power chip lead frames are disposed on the metal heat dissipating disks, the power chips are disposed on the power chip lead frames, and the drain electrodes of the power chips are electrically connected to the metal heat dissipating disks.

A method of manufacturing a packaged semiconductor device includes patterning and plating silver nanoparticles in bonding areas of a lead frame, forming a hydrophilic group while oxidizing the silver nanoparticles, forming wire bonds on the silver nanoparticles, and encapsulating the wire bonds and the silver nanoparticles.