A semiconductor device according to the disclosure includes a first semiconductor chip, a second semiconductor chip, a first metal plate provided on an upper surface of the first semiconductor chip, a second metal plate provided on an upper surface of the second semiconductor chip and a sealing resin covering the first semiconductor chip, the second semiconductor chip, the first metal plate and the second metal plate, wherein a groove is formed in the sealing resin, the groove extending downwards from an upper surface of the sealing resin, the first metal plate includes, at an end facing the second metal plate, a first exposed portion exposed from a side face of the sealing resin forming the groove, and the second metal plate includes, at an end facing the first metal plate, a second exposed portion exposed from a side face of the sealing resin forming the groove.

A chip package structure, comprises a first chip having a plurality of first chip joints at a lower side thereof; a circuit board below the first chip; an upper side of the circuit board being arranged with a plurality of circuit board joints; in packaging, the first chip joints being combined with the circuit board joints of the circuit board so that the first chip is combined to the circuit board by a way of ACF combination or convex joint combination; and wherein in the ACF combination, ACFs are used as welding points to be combined to the pads at another end so that the chip is combined to the circuit board; and wherein in the convex pad combination, a convex pad is combined with a flat pad by chemically methods or physical methods; and these pads are arranged on the circuit board and the first chip.

A semiconductor package includes a die pad having a die attach surface, a rear surface opposite the die attach surface, and an outer edge side extending between the die attach surface and the rear surface, the outer edge side having a step-shaped profile, wherein an upper section of the die pad laterally overhangs past a lower section of the die pad, a semiconductor die mounted on the die attach surface and having a first electrical terminal on an upper surface of the semiconductor die, and a first conductive clip that directly electrically contacts the first electrical terminal and wraps around the outer edge side of the die pad such that a section of the first conductive clip is at least partially within an area that is directly below the upper section of the die pad and directly laterally adjacent to the lower section.

An electronic module has a sealing part 90; a rear surface-exposed conductor 10, 20, 30 having a rear surface-exposed part 12, 22, 32 whose rear surface is exposed; a rear surface-unexposed conductor 40, 50 whose rear surface is not exposed; an electronic element 15, 25, which is provided in the sealing part 90 and provided on a front surface of the rear surface-exposed conductor 40, 50; a first connector 60 for electrically connecting the electronic element 15, 25 with the rear surface-exposed conductor 10, 20, 30; and a second connector 70 for electrically connecting the electronic element 15, 25 with the rear surface-unexposed conductor 40, 50. A thickness T1 of the first connector 60 is thicker than a thickness T2 of the second connector 70.

A method for manufacturing a semiconductor device includes: fixing a semiconductor chip to a first part of a leadframe; bonding one connector member to a first terminal of the semiconductor chip, a second terminal of the semiconductor chip, a second part of the leadframe, and a third part of the leadframe; forming a sealing member; and separating a first conductive part of the connector member and a second conductive part of the connector member by removing at least a section of the portion of the connector member exposed outside the sealing member, the first conductive part being bonded to the first terminal and the second part, the second conductive part being bonded to the second terminal and the third part.

The disclosure relates to a lead frame assembly for a semiconductor device, the lead frame assembly including: a die attach structure and clip frame structure. The clip frame structure includes: a die connection portion configured to contact to one or more contact terminals on a top side of the semiconductor die; one or more electrical leads extending from the die connection portion at a first end, and a lead supporting member extending from a second end of the one or more leads; and a plurality of clip support members arranged orthogonally to the one or more electrical leads. The plurality of support members and the lead supporting member are configured to contact the die attach structure. The present disclosure also relates a die attach structure and clip frame structure for a semiconductor device, a semiconductor device including the same and a method of manufacturing the semiconductor device.

A power semiconductor package includes a power semiconductor chip, an electrical connector arranged at a first side of the power semiconductor chip and having a first surface that is coupled to a power electrode of the power semiconductor chip, an encapsulation body at least partially encapsulating the power semiconductor chip and the electrical connector, and an electrical insulation layer arranged at a second surface of the electrical connector opposite the first surface, wherein parts of the encapsulation body and the electrical insulation layer form a coplanar surface of the power semiconductor package.

A method of manufacturing a semiconductor package includes attaching semiconductor dies to an array of leadframes and positioning a clip array in alignment with the array of leadframes within a mold cavity, the clip array including clips that electrically connect to at least some of the semiconductor dies and a siderail along a perimeter of the clip array. The siderail forms a set of reliefs extending from an outer edge of the siderail to an inner edge of the siderail, the inner edge being adjacent to the array of leadframes. The method also includes injecting a mold compound into the mold cavity through a flow path including the set of reliefs of the siderail to form a mold block at least partially covering the semiconductor dies.

A chip package structure, comprises a first chip having a plurality of first chip joints at a lower side thereof; a circuit board below the first chip; an upper side of the circuit board being arranged with a plurality of circuit board joints; in packaging, the first chip joints being combined with the circuit board joints of the circuit board so that the first chip is combined to the circuit board by a way of ACF combination or convex joint combination; and wherein in the ACF combination, ACFs are used as welding points to be combined to the pads at another end so that the chip is combined to the circuit board; and wherein in the convex pad combination, a convex pad is combined with a flat pad by chemically methods or physical methods; and these pads are arranged on the circuit board and the first chip.

A packaged semiconductor device has a die attach pad and leads disposed proximate to the die attach pad. Each lead has a lead bottom surface and a lead end surface. A semiconductor device attached adjacent to a top surface of the die attach pad, and a conductive clip is attached to the semiconductor device and at least one of the leads. The conductive clip comprises a first tie bar extending from a first side surface of the conductive clip. A package body encapsulates the semiconductor device, the conductive clip, portions of the leads, at least a portion of the first tie bar, and at least a portion of the die attach pad. Each lead end surface is exposed in a side surface of the package body, and an end surface of the first tie bar is exposed in a first side surface of the package body. A conductive layer is disposed on each lead end surface but is not disposed on the end surface of the first tie bar.