A battery disconnect unit including a housing, an electronic relay module installed on a charge/discharge line of a battery within the housing and including electronic switch devices capable of a switching operation of selectively blocking the flow of a current in the charge/discharge line, a heat dissipation cover provided with a structure surrounding at least a portion of the electronic relay module and formed of a material capable of heat exchange with the electronic relay module, and a cooling plate disposed in contact with the heat dissipation cover and provided to allow a refrigerant to flow in the cooling plate.

Improved semiconductor chip package thermo-mechanical cooling assembly are disclosed. An example An apparatus includes: a bolster plate to be coupled to a back plate, the bolster plate and backplate to sandwich a circuit board therebetween; a loading plate including a first fixture, the first fixture to engage a load stud protruding from the bolster plate; and a heat sink base including a second fixture, the second fixture to engage a pin protruding from the loading plate.

A semiconductor package includes: a molded body having opposite first and second sides; at least one semiconductor die encapsulated by the molded body; and a die carrier having opposite first and second sides. The semiconductor die is arranged over the first side of the die carrier. The second side of the die carrier is at least partially exposed from the second side of the molded body, forming at least one exposed portion of the die carrier. The first side of the molded body includes a first portion protruding from a second portion in a vertical direction perpendicular to the first side, forming a planar surface. The second portion extends completely along at least one edge of the first side. A center point of the first portion is in vertical alignment with a center point of the exposed portion.

A spring for use in a semiconductor device is provided, which includes a body having a plurality of slits to allow the body to deflect along a first direction; and one or more legs at one or both ends of the body. The plurality of slits are located in a plurality of planes perpendicular to the first direction and distributed along the first direction. The slits in a particular plane of the plurality of planes are interleaved with the slits in an adjacent plane of the plurality of planes

A cooling package for an integrated circuit, including: package substrate of the integrated circuit having a first package surface, an enclosure and a thermal conductive material filling a gap between the substrate and a circuit die locatable therein and filling a gap between interior sidewalls of the enclosure and sidewall surfaces of the circuit die couplable to the first package surface. A method including: mounting an enclosure to the first package surface, the enclosure surrounding a location on the first package surface the circuit die is couplable thereto and the circuit die is locatable therein, and, filling the enclosure with the thermal conductive material such that the gaps are filled with the thermal conductive material. An integrated circuit cooling package including the substrate, first and second enclosures and first and second thermal conductive materials is also disclosed.

Automated heatsink removal from a Printed Circuit Board Assembly (PCBA) can include detachably affixing a PCBA to a base fixture. Further, automated heatsink removal can include detachably applying a tool which locks on the base fixture while engaging, using a torque mechanism, and a heatsink coupled to a component on the PCBA. The torque mechanism can be activated in response to softening of thermal interface material between the heatsink and the component and an activation temperature for the torque mechanism being met. The activated torque mechanism loosens the heatsink from the component.

A method for mounting a fin system in a power module includes: sintering a fin system to a first base substrate, the fin system comprising a plurality of fins attached to and extending away from a base plate; sintering a first power switch component to the first base substrate; sintering a second power switch component to a second base substrate; and soldering a heat dissipation element to the second base substrate.

A heatsink is provided for a memory and routing module with a lower and upper side, both sides having multiple semiconductor chips attached. The lower side of the module has a connection component attached for connection to a motherboard. The heatsink includes a module receiving region configured to receive a lower side of the module, including a first thermally conductive portion arranged to face the semiconductor chips, an aperture through the lower heatsink component and a thermally conductive peripheral region disposed around the module receiving region. The heatsink includes an upper heatsink component which is configured to connect to the lower heatsink component at the peripheral region to retain the module. The upper heatsink component includes a lower side. The lower side includes a second thermally conductive portion arranged to face the semiconductor chips disposed on an upper side of the module and multiple second heat dissipating elements.

A weight optimized stiffener for use in a semiconductor device is disclosed herein. In one example, the stiffener is made of AlSiC for its weight and thermal properties. An O-ring provides sealing between a top surface of the stiffener and a component of the semiconductor device and adhesive provides sealing between a bottom surface of the stiffener and another component of the semiconductor device. The stiffener provides warpage control for a lidless package while enabling direct liquid cooling of a chip or substrate.

A semiconductor package includes a first rewiring layer; a lower semiconductor chip on the first rewiring layer; an upper semiconductor chip on the lower semiconductor chip; a heat dissipation structure on the upper semiconductor chip; a molding layer on the first rewiring layer so as to contact side surfaces of the lower semiconductor chip, the upper semiconductor chip, and the heat dissipation structure; a second rewiring layer on the heat dissipation structure; and one or more connection structures on the first rewiring layer and positioned adjacent to the side surfaces of the lower semiconductor chip and the upper semiconductor chip and configured to extend through the molding layer and connect the first rewiring layer to the second rewiring layer, wherein the upper semiconductor chip and the heat dissipation structure contact each other.