An apparatus for grounding a heatsink utilizing an EMC spring press-fit pin includes a printed circuit board, a logic chip, a heatsink, and a grounding member, where the grounding member includes an integrated spring and a first terminal pin at a first end of the grounding member. The logic chip is electrically coupled to the printed circuit board and the heatsink is disposed on a top surface of the logic chip. The first terminal pin at the first end of the grounding member is disposed in a plated-through hole of the printed circuit, where the grounding member is configured to electrically couple the heatsink to the printed circuit board.

This application discloses a board, an electronic device, and a manufacturing method, and pertains to the field of bare die package technologies. The board includes a PCB assembly, a bare die, a reinforcing frame, a heat sink, and fasteners. Both the bare die and the reinforcing frame are located on a surface of the PCB assembly, the bare die is located in the reinforcing frame, and the reinforcing frame is fixedly connected to the PCB assembly by using the fastener. The heat sink is located on a surface of the bare die that is away from the PCB assembly, and the heat sink is fixedly connected to the reinforcing frame by using the fastener.

A chip module includes a circuit board (2), a slot (21) disposed on a surface of one side of the circuit board (2), a lidless packaged chip (5), a heat radiator (4), and a substrate fixing assembly (6). The lidless packaged chip (5) includes a substrate (51) and a die (52) packaged on the substrate (51). The slot (21) is electrically connected to the circuit board (2), the lidless packaged chip (5) has a connecting part on one side of the substrate (51) facing away from the die (52), and the connecting part is inserted into the slot (21). The heat radiator (4) is press-fitted on one side of the die (52) facing away from the circuit board (2). The substrate fixing assembly (6) is press-fitted at a periphery of one side of the substrate (51) facing away from the circuit board (2) and avoids the die (52).

The present disclosure is related to a power module. The power module includes first fasteners and power devices. The power devices are adjacently disposed and locked by the first fasteners. Each of the power devices packages a power electronic therein. Each of the power devices includes a first extending portion. The first extending portion extends from a side of the power device. The first extending portion includes at least one first curved opening for receiving the first fastener. The first curved openings are adjacently disposed to form a first inserting hole. The first fastener passes through the first inserting hole.

Provided is a semiconductor module including semiconductor devices and a cooling apparatus, wherein the semiconductor device has semiconductor chips and a circuit board with the semiconductor chips implemented thereon; the cooling apparatus has a top plate, a side wall, a bottom plate, a coolant flow portion, an inlet, an outlet and a plurality of fins; the top plate and the bottom plate have three through holes that are through holes for inserting fastening members that fasten the semiconductor module to an external apparatus, penetrating the top plate and the bottom plate in one direction respectively; and a geometric center of gravity of a aperture of at least one of the inlet and the outlet may also be positioned inside a virtual triangle with the three through holes being vertexes in planar view.

A disclosed apparatus may include (1) a heat-emitting component, (2) a heatsink that includes a designated area thermally coupled to the heat-emitting component, (3) a plurality of springs that apply forces that support the thermal coupling between the designated area of the heatsink and the heat-emitting component, and (4) a pressure plate that concentrates the forces applied by the springs toward the designated area of the heatsink. Various other apparatuses, systems, and methods are also disclosed.

A method includes forming a reconstructed wafer, which includes placing a plurality of device dies over a carrier, encapsulating the plurality of device dies in an encapsulant, and forming a redistribution structure over the plurality of device dies and the encapsulant. The redistribution structure includes a plurality of dielectric layers and a plurality of redistribution lines in the plurality of dielectric layers. The method further includes performing a trimming process on the reconstructed wafer. The trimming process forms a round edge for the reconstructed wafer. A sawing process is performed on the reconstructed wafer, so that the reconstructed wafer includes straight edges.

A semiconductor device according to the present disclosure includes an electrically conductive first electrode block, an electrically conductive submount, an insulating layer, a semiconductor element, an electrically conductive bump, and an electrically conductive second electrode block. The submount is provided in a first region of the upper surface of the first electrode block, and electrically connected to the first electrode block. The semiconductor element is provided on the submount, and has a first electrode electrically connected to the submount. The bump is provided on the upper surface of a second electrode, opposite the first electrode, of the semiconductor element, and electrically connected to the second electrode. A third region of the lower surface of the second electrode block is electrically connected to the bump via an electrically conductive metal layer. An electrically conductive metal sheet is provided between the metal layer and the bump.

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 heat sink includes a heat sink base, a first fin, and a second fin. The spacing between the base and the first fin and the second fin, restively, may be adjusted by rotating a threaded rod. The threaded rod includes a first threaded knurl that is engaged with the first fin and a second threaded knurl that is engaged with the second fin. The thread pitch of the first threaded knurl and the second threaded knurl may differ. For example, the pitch of the first threaded knurl may be smaller than the pitch of the second threaded knurl if the first fin is located nearest the heat sink base relative to the second fin. The spacing of the heat sink fins may be adjusted based upon the current operating conditions of the electronic device to maintain an optimal temperature of a heat generating device during device operation.