초록 ▼

A thermal management for EMI shielded circuit packs having one or more high-power components, i.e. heat sources. More particularly, a heat transfer device or assembly for EMI shielded circuit packs is provided whereby multiple components (e.g., high-power components) are cooled by individual heat si

A thermal management for EMI shielded circuit packs having one or more high-power components, i.e. heat sources. More particularly, a heat transfer device or assembly for EMI shielded circuit packs is provided whereby multiple components (e.g., high-power components) are cooled by individual heat sinks (i.e., each component has its own individual heat sink) which protrude into an external airflow through individual openings in the lid of the EMI shield. Mechanically-compliant, electrically-conductive gaskets are used to seal the base plates of the individual heat sinks against the lid of the EMI shield enclosure. As such, in accordance with the various embodiments, the conductive gaskets establish a compliance layer which accommodates any variation in the heights of the individual components, thereby, allowing optimum thermal contact between the components and their respective heat sinks without compromising the EMI shielding.

대표청구항 ▼

We claim: 1. A heat transfer device, said heat transfer device comprising: a plurality of heat sources; an EMI shield enclosure having a lid; a heat-dissipating structure that is a heat sink to a particular one heat source of the plurality of heat sources; and a gasket disposed between, and in cont

We claim: 1. A heat transfer device, said heat transfer device comprising: a plurality of heat sources; an EMI shield enclosure having a lid; a heat-dissipating structure that is a heat sink to a particular one heat source of the plurality of heat sources; and a gasket disposed between, and in contact with, said heat-dissipating structure and a select area of the EMI shield enclosure; and wherein said gasket is mechanically-compliant and electrically-conductive; and wherein part of the heat sink protrudes through the lid via an opening in the lid. 2. The heat transfer device of claim 1, wherein said select area of said EMI shield is a portion of said lid and said gasket is integral with said EMI shield enclosure. 3. The heat transfer device of claim 1, wherein said plurality of heat sources are mounted on a printed circuit board, and said EMI shield enclosure provides an enclosure to said printed circuit board. 4. The heat transfer device of claim 1, wherein said heat sink has a plurality of heat-transfer fins, said plurality of heat-transfer fins extending through said lid of said EMI shield enclosure. 5. The heat transfer device of claim 1, wherein said particular one heat source is an integrated circuit. 6. A heat transfer device comprising: a heat-dissipating structure thermally connected to a particular one heat source of a plurality of heat sources, and a gasket disposed between, and in contact with, said heat-dissipating structure and a select area of an EMI shield enclosure; and wherein said gasket is mechanically-compliant, electrically-conductive and integral with said EMI shield enclosure; and wherein the heat transfer device comprises: a plurality of heat-dissipating structures, each one of said heat-dissipating structures being in thermal contact with a different one of said heat sources; a plurality of gaskets such that each gasket is disposed between, and in contact with, a different one of said heat sources and a particular area of said EMI shield enclosure; and wherein said gaskets are mechanically-compliant, electrically-conductive, integral with said EMI shield enclosure and compensate for any height variations between said mounted heat sources in said EMI shield enclosure. 7. The heat transfer device of claim 6, wherein said gaskets are of a uniform size and said heat-dissipating structures are of a variable size. 8. The heat transfer device of claim 6, wherein said thermal contact between at least one of said heat-dissipating structures and its associated said different one of said heat sources includes a thermal grease layer. 9. The heat transfer device of claim 1, wherein said EMI shield enclosure and said heat sink are formed from aluminum, and said gasket is formed from a nickel-graphite-filled silicone elastomer. 10. The heat transfer device of claim 6, wherein said plurality of gaskets form a compliant layer, within said EMI shield enclosure, which is external of a thermal path associated with said plurality of heat sources. 11. The heat transfer device of claim 6, wherein each heat-dissipating structure of said plurality of heat-dissipating structures has a plurality of heat-transfer fins which extend through said EMI shield enclosure and are exposed to an airflow external to said EMI shield enclosure. 12. A circuit packet assembly comprising: a printed circuit board (PCB); a plurality of integrated circuits mounted on said PCB; an EMI shield, said EMI shield providing an enclosure to said PCB; a plurality of heat sinks, each one of said heat sinks being associated with, and thermally connectable to, a different one integrated circuit of said plurality of integrated circuits; a plurality of gaskets, each one of said gaskets being disposed between, and in contact with, a particular one heat sink of said plurality of heat sinks and said EMI shield; and wherein said gaskets are mechanically-compliant, electrically-conductive, form part of said EMI shield and compensate for any height variations between said mounted integrated circuits within said EMI enclosure. 13. The circuit pack assembly of claim 12, wherein at least one of said heat sinks has a plurality of heat-transfer fins, said plurality of heat-transfer fins extending through a select area of said EMI shield. 14. The circuit pack assembly of claim 13, wherein said gaskets are of a uniform size and said heat sinks are of a variable size. 15. The circuit pack assembly of claim 14, wherein said thermal connection between at least one of said heat sinks and its associated said different one integrated circuit includes a thermal grease layer. 16. A heat transfer method for use with an EMI shield, the method comprising the steps of: thermally connecting a first heat-dissipating structure to a first heat source, and thermally connecting a second heat-dissipating structure to a second heat source, said first and said second heat-dissipating structures each having at least one heat-transfer fin; and disposing a first gasket between, and in contact with, said first heat-dissipating structure and a first select area of said EMI shield such that said heat-transfer fin of said first-heat dissipating structure extends through said first select area of said EMI shield; and disposing a second gasket between, and in contact with, said second heat-dissipating structure and a second select area of said EMI shield such that said heat-transfer fin of said second heat-dissipating structure extends through said second select area of said EMI shield; and wherein said first and said second gaskets are mechanically-compliant, electrically-conductive, integral with said EMI shield and compensate for any height variations between said first heat source and said second heat source within said EMI shield. 17. The heat transfer method of claim 16 further comprising: providing an airflow, external to said EMI shield, which is exposed to said extended heat-transfer fin of said first heat-dissipating structure and said extended heat-transfer fin of said second heat-dissipating structure. 18. The heat transfer method of claim 16, wherein said second heat-dissipating structure is thermally connected to both said second heat source and at least a third heat source. 19. The heat transfer method of claim 16, wherein said thermally connecting operation further comprises: applying a thermal grease layer between said first heat source and said first heat-dissipating structure.