A packaging structure is provided, including a substrate, a first chip, a second chip, and a conductive unit. The substrate includes a metal carrier, a patterned insulation layer disposed on the metal carrier and partially covering the metal carrier, and a patterned conductive layer disposed on the patterned insulation layer. The first chip is disposed on the metal carrier not covered by the patterned insulation layer. The second chip is disposed on the patterned conductive layer and electrically connected to the first chip by the conductive unit.

A packaging structure is provided, including a substrate, a first chip, a second chip, and a conductive unit. The substrate includes a metal carrier, a patterned insulation layer disposed on the metal carrier and partially covering the metal carrier, and a patterned conductive layer disposed on the patterned insulation layer. The first chip is disposed on the metal carrier not covered by the patterned insulation layer. The second chip is disposed on the patterned conductive layer and electrically connected to the first chip by the conductive unit.

A first heat sink has a first inner surface and a first outer surface, and has a first through hole. A second heat sink has a second inner surface disposed with a clearance left from the first inner surface of the first heat sink, and a second outer surface opposite to the second inner surface, and has a second through hole. A semiconductor element is disposed within a clearance between the first inner surface of the first heat sink and the second inner surface of the second heat sink. A sealing member seals the semiconductor element within the clearance between the first inner surface and the second inner surface. A first hollow tube is made of metal, and connects the first through hole and the second through hole.

A first heat sink has a first inner surface and a first outer surface, and has a first through hole. A second heat sink has a second inner surface disposed with a clearance left from the first inner surface of the first heat sink, and a second outer surface opposite to the second inner surface, and has a second through hole. A semiconductor element is disposed within a clearance between the first inner surface of the first heat sink and the second inner surface of the second heat sink. A sealing member seals the semiconductor element within the clearance between the first inner surface and the second inner surface. A first hollow tube is made of metal, and connects the first through hole and the second through hole.

The present disclosure relates to semiconductor components. The teachings thereof may be embodied in a lead frame for a semiconductor component including: a frame having a recess; an electrically conductive connecting element for establishing an electrical connection to the semiconductor component arranged in the recess; and an insulating element arranged in the recess and mechanically connecting the connecting element to the frame and electrically insulating it from the frame.

A semiconductor module is provided with a conductive member having one end, in a longitudinal direction, joined to an electrode of a semiconductor element that is mounted on an insulating substrate, the other end of the conductive member in the longitudinal direction being joined to a component different from the electrode. The conductive member is made up of a metal sheet, and has a bent portion at the one end and at the other end. The bent portion provided at the one end has a cut in a leading end portion, in the longitudinal direction, and an end joining section at which the cut is not present is joined to the electrode of the semiconductor element. As a result, a semiconductor module can be realized that allows combination of increased current capacity with improved reliability.

A semiconductor module is provided with a conductive member having one end, in a longitudinal direction, joined to an electrode of a semiconductor element that is mounted on an insulating substrate, the other end of the conductive member in the longitudinal direction being joined to a component different from the electrode. The conductive member is made up of a metal sheet, and has a bent portion at the one end and at the other end. The bent portion provided at the one end has a cut in a leading end portion, in the longitudinal direction, and an end joining section at which the cut is not present is joined to the electrode of the semiconductor element. As a result, a semiconductor module can be realized that allows combination of increased current capacity with improved reliability.

[Problem] An object of the present invention is to provide an electronic part mounting heat-dissipating substrate which enables a circuit for which a power semiconductor in which a large current flows is used to reduce the wiring resistances of a large power operation and improve the heat dissipation.

[Means for Solving] The present invention is an electronic part mounting heat-dissipating substrate which comprises lead frames of wiring pattern shapes formed by conductor plate and an insulating member 130 which is provided between the lead frames 110, wherein a plate surface of a part arrangement surface of said conductor plate and a top surface of said insulating member at a side of said part arrangement surface form one continuous surface, the lead frames have different thicknesses, the thick lead frame 110H is used for a large current signal and the thin lead frame 110L is used for a small current signal, a plate surface of a back surface of the part arrangement surface and a top surface of the insulating member at a side of the back surface at the part arrangement surface-side are formed in an identical plane.

An electronic heat-dissipating substrate including: lead frames of wiring pattern shapes on a conductor plate; and an insulating member between the lead frames. A plate surface of the lead frames and a top surface of the insulating member form one continuous surface. The part arrangement surface is on both surfaces of the electronic part mounting heat-dissipating substrate, a reductant circuit which includes at least similar dual-system circuit is formed on the electronic part mounting heat-dissipating substrate, a first-system circuit of the dual-system circuit is formed on a first surface of the electronic part mounting heat-dissipating substrate, a second-system circuit of the dual-system circuit is formed on a second surface of the electronic part mounting heat-dissipating substrate, and the common lead frames used in a portion of a circuit wiring are used to the first surface and the second surface of the electronic part mounting heat-dissipating substrate.

A semiconductor device includes a header, a semiconductor chip fixed to the header constituting a MOSFET, and a sealing body of insulating resin which covers the semiconductor chip, the header and the like, and further includes a drain lead contiguously formed with the header and projects from one side surface of the sealing body, and a source lead and a gate lead which project in parallel from one side surface of the sealing body, and wires which are positioned in the inside of the sealing body and connect electrodes on an upper surface of the semiconductor chip and the source lead and the gate lead, with a gate electrode pad arranged at a position from the gate lead and the source lead farther than a source electrode pad.