An object of the present invention is to provide a semiconductor device in which the effect of dimensional tolerance can be reduced, and a method for manufacturing the same. The semiconductor device according to the present invention includes: a plurality of cooling plates each having a coolant passage inside; spacers disposed to stack the cooling plates with spaces; at least one semiconductor package disposed on at least one principal surface of at least one of the cooling plates; and a spring plate disposed between adjacent ones of the cooling plates, the spring plate biasing the at least one semiconductor package toward the cooling plates.

A top side frame stiffener structure for a printed circuit board (PCB) stack. The structure is placed between a cooling component and a backing plate, in an area surrounding a substrate package. The structure does not cause the overall height of the PCB stack to increase.

A cooler includes a base on the upper surface of which semiconductor elements are mounted; a housing which is superimposed on the rear surface side of the base and between which and the base a refrigerant flow path is formed; screws which are disposed in the outer peripheral portion of an overlap region between the base and the housing and which fasten and fix the base to the housing; O-rings which seal the outer peripheral portion of the refrigerant flow path; and joining members which are disposed in a joining surface portion of the housing, which is inside the outer peripheral portion of the refrigerant flow path and makes contact with the base, and which bite into the base and housing in an unpenetrated state. The joining strength between the housing and the base is reinforced by the joining members whose joint interfaces are not exposed to the outside.

A power semiconductor module has a substrate and an insulation layer and a metal layer arranged on the insulation layer, forming conductor tracks, comprising power semiconductor components arranged on the metal layer and conductively contacted with the metal layer. A pressure device arranged above the substrate in the normal direction of the insulation layer and having a pressure body and pressure elements running toward the substrate. The pressure elements each being connected to the pressure body to move resiliently in the normal direction via a spring element. The pressure body exerting a pressure onto the pressure elements in the direction toward the substrate via the spring elements, the pressure elements being arranged in such a way that, owing to the pressure exerted by the pressure body, they press onto power semiconductor component surrounding regions, surrounding the power semiconductor components, of the substrate.

An exemplary base includes a heat absorber and clips attached to the heat absorber. The heat absorber includes a top surface and a bottom surface. A pair of receiving grooves is defined in opposite lateral sides of the heat absorber, respectively. Each receiving groove is located above a level of the bottom surface and below a level of the top surface. Each clip includes a positioning beam. The positioning beam is received in a corresponding one of the receiving grooves with a portion of the heat absorber adjacent to the positioning beam deformed and fixed in the positioning beam thereby fixing the positioning beam in the receiving groove. A heat dissipating module having the base is also provided.

A power semiconductor module includes: a substrate with a metallization layer attached to a dielectric insulation layer and a semiconductor body mounted to the metallization layer; a housing at least partly enclosing the substrate and having sidewalls and a cover that at least partly covers an opening formed by the sidewalls and has a flexible portion; and a press-on pin having arranged on the substrate or semiconductor body. A first end of the press-on pin faces the substrate or semiconductor body and extends towards the cover such that a second end of the press-on pin contacts the flexible portion of the cover. The substrate in an area vertically below the press-on pin has a first spring constant k.sub.1 in a vertical direction that is perpendicular to a top surface of the substrate. The flexible portion of the cover has a second spring constant k.sub.2, where 0.5*k.sub.1≤k.sub.2≤5*k.sub.1.

A heat sink apparatus that utilizes a pivot couple and support with anchor-spring mounts to enable exertion of a uniform amount of force over the mounting surface of the apparatus that is thermally/physically coupled to a heat load. The apparatus can include a heat sink base that has a bottom side defining the mounting surface, and a top side to which a support is pivotally coupled by a pivot couple. The apparatus can include a first and second anchor that each have a first end connected to an anchor point and a second end coupled to a load surface on the support by a spring. The load surfaces can be symmetrically disposed on opposite sides of the pivot couple, which is centrally located relative to the mounting surface so that the force imparted by spring loads of the springs is evenly distributed over the mounting surface.

Micro devices having enhanced through printed circuit board (PCB) heat transfer are provided. In one example, a micro device is provided that includes a PCB, a thermal management device, a chip package, a bracket, and a plurality of extra-package heat conductors. The chip package has a first side facing the thermal management device and a second side mounted to a first side of the PCB. The bracket is disposed on a second side of the PCB that faces away from the chip package. The plurality of extra-package heat conductors are disposed laterally outward of the chip package and provide at least a portion of a thermally conductive heat transfer path between the bracket and the thermal management device through the PCB.

A system includes a retainer assembly to align each of a group of cooling devices with a corresponding electrical component of a group of electrical components that are mounted to a circuit board, where the retainer assembly includes a group of apertures, such that each of the cooling devices protrudes through a corresponding aperture when the retainer assembly is installed on the circuit board, and where the retainer assembly includes a group of retaining springs, each of which is associated with a corresponding aperture, that applies a respective force, of a group of forces, to a corresponding one of the cooling devices when the retainer assembly is installed on the circuit board. The system also includes a set of fasteners to mount the retainer assembly to the circuit board, such that the cooling devices dissipate heat that is generated by the electrical components.

An electronic component which comprises an electrically conductive carrier, an electronic chip on the carrier, an encapsulant encapsulating at least part of at least one of the carrier and the electronic chip, and a functional structure covering a surface portion of the encapsulant, wherein at least part of the covered surface portion of the encapsulant is spatially selectively roughened.