A package structure includes first/second/third package components, a thermal interface material (TIM) structure overlying the first package component opposite to the second package component, and a heat dissipating component disposed on the third package component and thermally coupled to the first package component through the TIM structure. The first package component includes semiconductor dies and an insulating encapsulation encapsulating the semiconductor dies, the second package component is interposed between the first and third package components, and the semiconductor dies are electrically coupled to the third package component via the second package component. The TIM structure includes a dielectric dam and thermally conductive members including a conductive material, disposed within areas confined by the dielectric dam, and overlying the semiconductor dies. A manufacturing method of a package structure is also provided.

Provided is a power semiconductor module that can secure insulating properties. A semiconductor element is mounted on a resin-insulated base plate including a circuit pattern, a resin insulating layer, and a base plate. A case enclosing the resin-insulated base plate is bonded to the resin insulating layer with an adhesive. The resin insulating layer and the case are bonded together with a region enclosed by the resin insulating layer and a tapered portion of the case formed closer to the resin insulating layer being filled with the adhesive made of a material identical to that of the sealing resin. Air bubbles in the adhesive appear in the tapered portion opposite to the resin insulating layer.

A semiconductor device package is disclosed. The package according to one example includes a base having a main surface made of a metal, a dielectric side wall having a bottom surface facing the main surface, a joining material containing silver (Ag) and joining the main surface of the base and the bottom surface of the side wall to each other, a lead made of a metal joined to an upper surface of the side wall on a side opposite to the bottom surface, and a conductive layer not containing silver (Ag). The conductive layer is provided between the bottom surface and the upper surface of the side wall at a position overlapping the lead when viewed from a normal direction of the main surface. The conductive layer is electrically connected to the joining material, extends along the bottom surface, and is exposed from a lateral surface of the side wall.

A semiconductor module includes a semiconductor element, a substrate on which the semiconductor module is mounted, a heat radiating plate on which the substrate is mounted, a resin case, and a first main current electrode and a second main current electrode, in which in the first main current electrode and the second main current electrode, one end of each thereof is joined to a circuit pattern on the substrate, an other end of each thereof is extended through and incorporated in a side wall of the resin case so as to project outward of the resin case, and each thereof has at least a portion of overlap at which a part thereof overlaps in parallel with each other with a gap therebetween, and each thereof has a slope portion provided between an external projection portion and an internal projection portion.

A semiconductor device includes a substrate, a resin case, and a wiring member having an exposed portion adjacent to a first fixing portion fixed in a wall surface of the resin case and exposed to outside, and a second fixing portion fixed in the wall surface of the resin case at a position different from the first fixing portion with respect to a portion extending from the first fixing portion into the resin case, in which the wiring member is bonded to a surface of the semiconductor element by solder in the resin case, and has a plate shape having a length, a thickness, and a width, in which the wiring member has the thickness being uniform and is flat in the resin case, and the width of the second fixing portion is narrower than the width of the exposed portion.

A semiconductor device includes a substrate, a resin case, and a wiring member having an exposed portion adjacent to a first fixing portion fixed in a wall surface of the resin case and exposed to outside, and a second fixing portion fixed in the wall surface of the resin case at a position different from the first fixing portion with respect to a portion extending from the first fixing portion into the resin case, in which the wiring member is bonded to a surface of the semiconductor element by solder in the resin case, and has a plate shape having a length, a thickness, and a width, in which the wiring member has the thickness being uniform and is flat in the resin case, and the width of the second fixing portion is narrower than the width of the exposed portion.

A semiconductor device includes: a conductive base substrate; a semiconductor chip mounted on the base substrate and having a signal pad; a frame configured to surround the semiconductor chip, to be mounted on the base substrate, and to include a step having an inner first upper surface and an outer second upper surface higher than the first upper surface in a plan view, wherein a first conductor pattern provided on the first upper surface is electrically connected to the base substrate; a capacitive component mounted on the first conductor pattern; a signal terminal mounted on the second upper surface of the frame; a first bonding wire configured to electrically connect the signal pad and an upper surface of the capacitive component; and a second bonding wire configured to electrically connect the upper surface of the capacitive component and the signal terminal.

A semiconductor device has a substrate and a first semiconductor die disposed over the substrate. A first metal frame is disposed over the substrate around the first semiconductor die. A first metal lid is disposed over the first metal frame. A flap of the first metal lid includes an elastic characteristic to latch onto the first metal frame. An edge of the flap can have a castellated edge. A recess in the first metal frame and a protrusion on the first metal lid can be used to latch the first metal lid onto the first metal frame. A second metal frame and second metal lid can be disposed over an opposite surface of the substrate from the first metal frame.

A semiconductor die package and a method of forming the same are provided. The semiconductor die package includes a package substrate and a semiconductor device disposed over the package substrate. A ring structure is disposed over the package substrate and laterally surrounds the semiconductor device. The ring structure includes a lower ring portion arranged around the periphery of the package substrate. Multiple notches are formed along the outer periphery of the lower ring portion. The ring structure also includes an upper ring portion integrally formed on the lower ring portion. The upper ring portion laterally extends toward the semiconductor device, so that the inner periphery of the upper ring portion is closer to the semiconductor device than the inner periphery of the lower ring portion. An adhesive layer is interposed between the lower ring portion and the package substrate.

A package structure includes a first semiconductor die, a first insulating encapsulation, a thermal coupling structure, and a heat dissipating component thermally coupled to the first semiconductor die through the thermal coupling structure. The first semiconductor die includes an active side, a rear side, and a sidewall connected to the active side and the rear side. The first insulating encapsulation extends along the sidewall of the first semiconductor die and includes a first side substantially leveled with the active side, a second side opposite to the first side, and topographic features at the second side. The thermal coupling structure includes a metallic layer overlying and the rear side of the first semiconductor die and the topographic features of the first insulating encapsulation. A manufacturing method of a package structure is also provided.