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A winged heat sink includes one or more arms that transport heat from a pedestal that is thermally coupled to an integrated circuit to convective fins. For example, the one or more arms may include one or more heat pipes. Moreover, the arms extend the vertical position of the winged heat sink away f

A winged heat sink includes one or more arms that transport heat from a pedestal that is thermally coupled to an integrated circuit to convective fins. For example, the one or more arms may include one or more heat pipes. Moreover, the arms extend the vertical position of the winged heat sink away from a plane of the pedestal so that the convective fins extend downward back toward a circuit board on which the integrated circuit is mounted. These downward facing fins may match the topologies of components on the underlying circuit board.

대표청구항 ▼

1. A heat sink, comprising: a first pedestal configured to thermally couple to a first integrated circuit mounted on a circuit board;a first arm thermally coupled to the first pedestal, wherein the first arm is a first heat pipe, wherein the first arm extends a vertical position of the a first heat

1. A heat sink, comprising: a first pedestal configured to thermally couple to a first integrated circuit mounted on a circuit board;a first arm thermally coupled to the first pedestal, wherein the first arm is a first heat pipe, wherein the first arm extends a vertical position of the a first heat sink from a plane defined by a top surface of the first pedestal to a second vertical position, the second vertical position is further away from the circuit board than the top surface of the first pedestal, wherein the first heat pipe has a wall-and-wick structure, wherein the first heat pipe comprises first convective fins thermally coupled to the first arm, wherein the first convective fins extend downward from the first arm back toward the circuit board, wherein the first convective fins are variable-length fins, and wherein the first convective fins form scallops to clear a second heat pipe and to optimize cooling efficiency of the first convective fins;a second pedestal configured to thermally couple to a second integrated circuit mounted on the circuit board;a third arm thermally coupled to the second pedestal, wherein the third arm is the second heat pipe, wherein the third arm extends a vertical position of a second heat sink from a plane defined by a top surface of the second pedestal to a third vertical position, the third vertical position is between the plane defined by the top surface of the first pedestal and the second vertical position, wherein the second heat pipe has a wall-and-wick structure, wherein the second heat pipe comprises second convective fins thermally coupled to the third arm, wherein the second convective fins extend upward from the third arm away from the circuit board, wherein the second convective fins are variable-length fins, and wherein the second convective fins form scallops to clear the first heat pipe and to optimize cooling efficiency of the second convective fins, andwherein the first convective fins are interleaved with the second convective fins. 2. The heat sink of claim 1, wherein the first heat sink further includes a second arm, thermally coupled to the first pedestal, on an opposite side of the first integrated circuit from the first arm; wherein the second arm extends the vertical position of the first heat sink; and wherein the second arm is thermally coupled to the first convective fins. 3. The heat sink of claim 1, wherein the first heat sink further includes additional fins thermally coupled to the first arm; and wherein the additional fins extend upward away from the circuit board. 4. The heat sink of claim 1, wherein the first heat sink further includes additional fins thermally coupled to the first arm; and wherein the additional fins extend parallel to the plane of the first pedestal. 5. The heat sink of claim 1, wherein, during operation, the first heat sink is configured to transport heat from the first integrated circuit to the first convective fins. 6. The heat sink of claim 1, wherein the first heat sink further includes multiple arms arranged adjacent to each other, wherein the multiple arms include the first arm; and wherein, during operation, the first heat sink is configured to transport heat from the first integrated circuit in two dimensions to the first convective fins. 7. The heat sink of claim 1, wherein the first heat sink further includes a heat-sink base thermally coupled to at least a portion of the first arm; and wherein the heat-sink base is configured to spread heat over the first arm. 8. A system, comprising: a first integrated circuit mounted on a circuit board; anda first heat sink, wherein the first heat sink includes:a first pedestal thermally coupled to the first integrated circuit;a first arm thermally coupled to the first pedestal, wherein the first arm is a first heat pipe, wherein the first arm extends a vertical position of the first heat sink from a plane defined by a top surface of the first pedestal to a second vertical position, the second vertical position is further away from the circuit board than the top surface of the first pedestal, wherein the first heat pipe has a wall-and-wick structure, wherein the first heat pipe comprises first convective fins thermally coupled to the first arm, wherein the first convective fins extend downward from the first arm back toward the circuit board, wherein the first convective fins are variable-length fins, and wherein the first convective fins form scallops to clear a second heat pipe and to optimize cooling efficiency of the first convective fins;a second pedestal configured to thermally couple to a second integrated circuit mounted on the circuit board;a third arm thermally coupled to the second pedestal, wherein the third arm is the second heat pipe, wherein the third arm extends a vertical position of a second heat sink from a plane defined by a top surface of the second pedestal to a third vertical position, the third vertical position is between the plane defined by the top surface of the first pedestal and the second vertical position, wherein the second heat pipe has a wall-and-wick structure, wherein the second heat pipe comprises second convective fins thermally coupled to the third arm, wherein the second convective fins extend upward from the third arm away from the circuit board, wherein the second convective fins are variable-length fins, wherein the second convective fins form scallops to clear the first heat pipe and to optimize cooling efficiency of the second convective fins, and wherein the first convective fins are interleaved with the second convective fins. 9. The system of claim 8, wherein the system further includes a component in the components, the component having a height mounted on the circuit board proximate to the first integrated circuit; and wherein the second vertical position clears the height. 10. The system of claim 9, wherein the first convective fins have different lengths to accommodate the height of the component. 11. The system of claim 8, wherein the first heat sink further includes a second arm, thermally coupled to the first pedestal, on an opposite side of the first integrated circuit from the first arm; wherein the second arm extends the vertical position of the first heat sink; and wherein the second arm is thermally coupled to the first convective fins. 12. The system of claim 8, wherein the first heat sink further includes additional fins thermally coupled to the first arm; and wherein the additional fins extend upward away from the circuit board. 13. The system of claim 8, wherein the first heat sink further includes additional fins thermally coupled to the first arm; and wherein the additional fins extend parallel to the plane of the first pedestal. 14. The system of claim 8, wherein, during operation, the first heat sink is configured to transport heat from the first integrated circuit to the first convective fins. 15. The system of claim 8, wherein the first heat sink further includes multiple arms arranged adjacent to each other, wherein the multiple arms include the first arm; and wherein, during operation, the first heat sink is configured to transport heat from the first integrated circuit in two dimensions to the first convective fins. 16. The system of claim 8, wherein the first heat sink further includes a heat-sink base thermally coupled to at least a portion of the first arm; and wherein the heat-sink base is configured to spread heat over the first arm. 17. A method for cooling a first integrated circuit using a first heat sink, wherein the method comprises: transporting heat from the first integrated circuit to first convective fins using a first arm in the first heat sink, wherein the first arm is a first heat pipe, wherein the first arm extends a vertical position of the first heat sink from a plane defined by a top surface of the first integrated circuit to a second vertical position, the second vertical position is further away from the circuit board than the top surface of the first integrated circuit, the circuit board coupled to the integrated circuit, wherein the heat pipe has a wall-and-wick structure, wherein the first heat pipe comprises first convective fins thermally coupled to the first arm, wherein the first convective fins extend downward from the first arm back toward the circuit board, wherein the first convective fins are variable-length fins, and wherein the first convective fins form scallops to clear a second heat pipe and to optimize cooling efficiency of the first convective fins;providing a second integrated circuit coupled to the circuit board;providing a third arm thermally coupled to the second integrated circuit, wherein the third arm is the second heat pipe, wherein the third arm extends a vertical position of a second heat sink from the plane defined by a top surface of a second integrated circuit to a third vertical position, the third vertical position is between the plane defined by the top surface of the first integrated circuit and the second vertical position, wherein the second heat pipe has a wall-and-wick structure, wherein the second heat pipe comprises second convective fins thermally coupled to the third arm, wherein the second convective fins extend upward from the third arm away from the circuit board, wherein the second convective fins are variable-length fins, wherein the second convective fins form scallops to clear the first heat pipe and to optimize cooling efficiency of the second convective fins, andwherein the first convective fins are interleaved with the second convective fins. 18. The method of claim 17, wherein, during the transport, the method further comprises spreading the heat over the first heat sink using a heat-sink base in the first heat sink. 19. The method of claim 17, wherein the method further comprises: transporting the heat from the first integrated circuit to additional convective fins using the first arm, where the additional convective fins extend upward away from the first integrated circuit; and convectively cooling the additional convective fins. 20. The method of claim 17, wherein the method further comprises: transporting the heat from the first integrated circuit to additional convective fins using the first arm, where the additional convective fins extend parallel to the plane defined by the top surface of the first integrated circuit; andconvectively cooling the additional convective fins.