A jig for manufacturing a semiconductor package includes a bottom piece and an upper piece. The bottom piece includes a base, a support plate, and at least one elastic connector. The support plate is located in a central region of the base. The at least one elastic connector is interposed between the support plate and the base. The upper piece includes a cap and outer flanges. The cap overlays the support plate when the upper piece is disposed on the bottom piece. The outer flanges are disposed at edges of the cap, connected with the cap. The outer flanges contact the base of the bottom piece when the upper piece is disposed on the bottom piece. The cap includes an opening which is a through hole. When the upper piece is disposed on the bottom piece, a vertical projection of the opening falls entirely on the support plate.

A solid-state storage device includes a housing, a wiring board and a semiconductor package unit. The housing is formed with a heat-dissipating recess thereon. The wiring board is fixed in the housing. One side of the semiconductor package unit is mounted on the wiring board, and the other side of the semiconductor package unit is embedded in the heat-dissipating recess. A top surface and lateral surfaces surrounding the top surface of the semiconductor package unit are all thermally connected to the housing in the heat-dissipating recess.

A processing unit disposed within a compute unit, where the compute unit includes a printed circuit board (PCB) that includes an integrated circuit; a first thermal management device, that includes a first vapor chamber thermally conductively coupled to a first side of the integrated circuit; and a first heatsink thermally conductively coupled to the first vapor chamber; and a second thermal management device, that includes a second vapor chamber; and a second heatsink thermally conductively coupled to the second vapor chamber, where the second thermal management device is thermally conductively coupled to the first thermal management device; where the PCB is interposed between the first thermal management device and the second thermal management device.

A circuit carrier arrangement includes: a cooling plate (1) which has spacer and fastening elements (3) for connection to a printed circuit board (2) in a spaced-apart manner; a printed circuit board (2) which has bores (4) for receiving spring element sleeves (9); at least one power semiconductor component (10) which is connected by a soldered connection to the printed circuit board (2) and fastening elements (3) in the state in which it is fitted with the cooling plate (1) by means of plug-in connections (11) of spring-action configuration; and at least one spring element (5) having at least two spring element sleeves (9) between which a web (6) that is connected to the spring element sleeves (9) extends, and supporting elements (7) arranged on either side of said web and at least one spring plate (8) being arranged on said web.

Some examples described herein provide for a heterogeneous integration module (HIM) that includes a thermal management apparatus. In an example, an apparatus (e.g., a HIM) includes a wiring substrate, a first component, a second component, and a thermal management apparatus. The first component and the second component are communicatively coupled together via the wiring substrate. The thermal management apparatus is in thermal communication with the first component and the second component. The thermal management apparatus has a first thermal energy flow path for dissipating thermal energy generated by the first component and has a second thermal energy flow path for dissipating thermal energy generated by the second component. The first thermal energy flow path has a lower thermal resistivity than the second thermal energy flow path.

The disclosure describes a lid allowing for a thermal interface material with fluidity, like a liquid metal, in a lidded flip chip package, including: a lid, a sealing ring for forming a sealed gap between a flip chip and the lid, a storage tunnel in the lid for accepting or releasing a liquid from or to the sealed gap, a connecting hole connecting the sealed gap with the storage tunnel, an injection hole with a plug, wherein a plug structure is formed at an outer end of the storage tunnel for opening or closing it, a slippery skin is arranged on an inner surface of the storage tunnel for a better flow of a liquid metal in it, the sealed gap is completely filled with a liquid metal, and a portion of the storage tunnel is filled with the same liquid metal and its remaining portion is filled with a gas.

The disclosure describes a lidded flip chip package allowing for a thermal interface material (TIM) with fluidity, like a liquid metal, including: a lid, a sealing ring for forming a sealed gap between a flip chip and the lid, a storage tunnel as a reservoir for accepting or releasing a liquid metal from or to the sealed gap, and an injection tunnel for filling a liquid metal into the sealed gap, wherein a self-sealing plug structure is integrated with the storage tunnel and the injection tunnel, the sealed gap is completely filled with a liquid metal, and a portion of the storage tunnel is filled with the same liquid metal and its remaining portion is filled with a gas. The disclosure also describes a method for filling a liquid metal into the lidded flip chip package based on the self-sealing plug structure.

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.

A threaded cooling apparatus includes a head having a heat exchanger and a shaft having a threaded section configured to mechanically fasten the head to a structure. The heat exchanger is configured to exchange heat with a coolant flowing through the head. The shaft also includes first and second cooling channels. The first cooling channel is configured to deliver the coolant to the heat exchanger, and the second cooling channel is configured to exhaust the coolant from the heat exchanger. The apparatus may also include a first seal between the head and the structure that is configured to reduce or prevent coolant loss. The apparatus may further include a second seal that is configured to reduce or prevent coolant flow between the first and second cooling channels that bypasses the heat exchanger.

Provided are an electric control component, an air conditioner having the same, and an assembly method for the electric control component. The electric control component includes a circuit board, a chip, a radiator and a fixing member. The chip is disposed on the circuit board. The radiator is disposed at a side of the chip away from the circuit board. The fixing member is configured to rigidly connect the radiator to the circuit board. At least one of the circuit board and the radiator has an engagement portion adapted to be engaged with a pre-tightening device for clamping the radiator and the circuit board.