An object is to provide a technology for enabling reduction in the time and cost taken to manufacture a die to be used for molding a case that surrounds semiconductor elements. A semiconductor device includes a base plate, a cooling plate, an insulating substrate, a semiconductor element, a case, a lead frame formed integrally with the case and including a terminal formed on one end portion of the lead frame and protruding outward, and a sealant. The case includes a pair of first case components arranged to face each other, and a pair of second case components arranged to face each other and crossing the pair of first case components. Joining end portions of the first case components to end portions of the pair of second case components forms the case.

A semiconductor device in which a semiconductor element mounted on a laminate substrate and an electrically conductive connection member are sealed with a sealing material, includes: a primer layer in an interface between the sealing material and sealed members including the laminate substrate, the semiconductor element, and the electrically conductive connection member, in which the sealing material includes a first sealing layer which is provided in contact with the primer layer; and a second sealing layer which covers the first sealing layer, the semiconductor device satisfies α.sub.p≥α.sub.1>α.sub.2 in which α.sub.p, α.sub.1, and α.sub.2 represent coefficients of linear thermal expansion of the primer layer, the first sealing layer, and the second sealing layer, respectively, α.sub.c≥15×10.sup.−6/° C. in which α.sub.c represents a composite coefficient of linear thermal expansion of the sealing layers, and E.sub.c≥5 GPa or more in which E.sub.c represents a composite Young's modulus of the sealing layers.

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 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.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, a mounting layer, switching elements, a moisture-resistant layer and a sealing resin. The substrate has a front surface facing in a thickness direction. The mounting layer is electrically conductive and disposed on the front surface. Each switching element includes an element front surface facing in the same direction in which the front surface faces along the thickness direction, a back surface facing in the opposite direction of the element front surface, and a side surface connected to the element front surface and the back surface. The switching elements are electrically bonded to the mounting layer with their back surfaces facing the front surface. The moisture-resistant layer covers at least one side surface. The sealing resin covers the switching elements and the moisture-resistant layer. The moisture-resistant layer is held in contact with the mounting layer and the side surface so as to be spanned between the mounting layer and the side surface in the thickness direction.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, a mounting layer, switching elements, a moisture-resistant layer and a sealing resin. The substrate has a front surface facing in a thickness direction. The mounting layer is electrically conductive and disposed on the front surface. Each switching element includes an element front surface facing in the same direction in which the front surface faces along the thickness direction, a back surface facing in the opposite direction of the element front surface, and a side surface connected to the element front surface and the back surface. The switching elements are electrically bonded to the mounting layer with their back surfaces facing the front surface. The moisture-resistant layer covers at least one side surface. The sealing resin covers the switching elements and the moisture-resistant layer. The moisture-resistant layer is held in contact with the mounting layer and the side surface so as to be spanned between the mounting layer and the side surface in the thickness direction.

A semiconductor device includes a semiconductor element, a heat sink on which the semiconductor element is mounted, and a case made of resin, the case being mounted on the heat sink and containing the semiconductor element. A fastening hole is formed passing through the case and the heat sink. The case includes a surface pressure absorbing member on a portion including the fastening hole in plan view, the surface pressure absorbing member having a plate shape and being higher in rigidity than the resin.

A semiconductor device includes a semiconductor element, a heat sink on which the semiconductor element is mounted, and a case made of resin, the case being mounted on the heat sink and containing the semiconductor element. A fastening hole is formed passing through the case and the heat sink. The case includes a surface pressure absorbing member on a portion including the fastening hole in plan view, the surface pressure absorbing member having a plate shape and being higher in rigidity than the resin.

There is provided an electric-power conversion apparatus in which smoke emission, a burnout, and short-circuiting can be suppressed even when a fuse portion is melted by an excessive current and in which it is made possible that heat generated in the fuse portion is less likely to be transferred to the electric power semiconductor device. The electric-power conversion apparatus includes a fuse portion formed in an electrode wiring member, a fuse resin member that covers the fuse portion, and a sealing resin member that seals an electric power semiconductor device and the fuse portion in a case. Along a current-flowing direction, the fuse portion includes an upstream-side first step portion whose cross-sectional area is smaller than that of the portion at the upstream side thereof, a second step portion whose cross-sectional area is smaller than that of the upstream-side first step portion, and a downstream-side first step portion whose cross-sectional area is larger than that of the second step portion but is smaller than that of the portion at the downstream side thereof.

A semiconductor device module may include a leadframe spacer that provides the functions of both a leadframe and a spacer, while enabling a double-sided cooling configuration. Such a leadframe spacer may include a leadframe surface that provides a die attach pad (DAP) that is shared by at least two semiconductor devices. The leadframe spacer may include at least one downset, where the semiconductor devices may be attached within a recess defined by the at least one downset. A first substrate may be connected to a first side of the leadframe. A second substrate may be connected to downset surfaces of the at least one downset, and positioned for further connection to the semiconductor devices in a double-sided assembly.