One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

The disclosure describes a lidded flip chip package, including a lid with a tray structure, wherein a tray is formed at an upper side of the lid, a heat spreader is mounted in the tray through a sealing ring so as to form a sealed gap between the tray and the heat spreader, another sealing ring is mounted at a lower side of the top piece of the lid so as to form another sealed gap between a flip chip and the lid, through-holes are formed through the tray so as to connect the first sealed gap with the second sealed gap, and a thermal interface material having fluidity is completely filled in the first sealed gap and at least partially filled in the second sealed gap. A lidded flip chip package including a lid with a two-step tray is one preferred embodiment of the present disclosure.

Chip packages and methods for fabricating the same are provided which utilize a first heat spreader interfaced with a first integrated circuit (IC) die and a second heat spreader separately interfaced with a second IC die. The separate heat spreaders allow the force applied to the first IC die to be controlled independent of the force applied to the second IC die.

A base of a connector defines an accommodation portion for accommodating a card-type device. The base has holding portions with surfaces directed to the accommodation portion. The holding portions hold held portions of terminals 40. Heat conductive members are provided on the surfaces of the holding portions. The heat conductive members are sandwiched between the card-type device and the holding portions when the card-type device is connected to the connector 10. In this way, heat conductive paths, which include the conductive members, are formed between the card-type device and held portions of the terminals 40.

A semiconductor device includes a power module unit, a fin base, and a plurality of radiator fins. The power module unit and the fin base are integrated together, with a recess-projection portion formed on the power module unit being fitted to a recess-projection portion formed on the fin base. The plurality of radiator fins are integrally fitted on a heat radiation diffusion portion of the fin base.

An electromagnetic wave absorption sheet is arranged to contact an upper surface and side surfaces of an electronic component mounted on a wiring board, a heat conduction plate is arranged to contact the electromagnetic wave absorption sheet, a heat transfer sheet is arranged to contact the heat conduction plate, and a heat dissipation member is arranged to contact the heat transfer sheet. Heat conductive particles contained in the heat transfer sheet contact a flat surface portion of the heat conduction plate. The electromagnetic wave absorption sheet, the heat conduction plate, and the heat transfer sheet are interposed between the heat dissipation member and the electronic component, as a heat conduction member for conducting heat generated in the electronic component and the like to the heat dissipation member.

A semiconductor device includes a vapor chamber lid for high power applications such as chip-on-wafer-on-substrate (CoWoS) applications using high performance processors (e.g., graphics processing unit (GPU)) and methods of manufacturing the same. The vapor chamber lid provides a thermal solution which enhances the thermal performance of a package with multiple chips. The vapor chamber lid improves hot spot dissipation in high performance chips, for example, at the three-dimensional (3D-IC) packaging level.

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.

One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

A heat sink includes a threaded rod. The threaded rod includes a first portion and a second portion. The first portion may engage with a first heat sink fin and a second portion may engage with a second heat sink fin. The first portion includes a first external thread of a first diameter. The second portion includes a second external thread also of the first diameter and of different pitch than the first external thread. For example, the pitch of a first knurl of the threaded rod may be smaller than the pitch of a second threaded knurl of the threaded rod. 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.