A redundant heat sink module can include a first independent coolant pathway and a second independent coolant pathway. The first independent coolant pathway can include a first inlet chamber, a first outlet chamber, and a first plurality of orifices extending from the first inlet chamber to the firs
A redundant heat sink module can include a first independent coolant pathway and a second independent coolant pathway. The first independent coolant pathway can include a first inlet chamber, a first outlet chamber, and a first plurality of orifices extending from the first inlet chamber to the first outlet chamber and providing a first plurality of impinging jet streams of coolant against a first region of a surface to be cooled when pressurized coolant is provided to the first inlet chamber. The second independent coolant pathway can include a second inlet chamber, a second outlet chamber, and a second plurality of orifices extending from the second inlet chamber to the second outlet chamber and providing a second plurality of impinging jet streams of coolant against a second region of the surface to be cooled when pressurized coolant is provided to the second inlet chamber.
대표청구항▼
1. A redundant heat sink module for transferring heat away from a surface to be cooled, the redundant heat sink module comprising: a first independent coolant pathway formed within the redundant heat sink module, the first independent coolant pathway comprising: a first inlet chamber; a first outlet
1. A redundant heat sink module for transferring heat away from a surface to be cooled, the redundant heat sink module comprising: a first independent coolant pathway formed within the redundant heat sink module, the first independent coolant pathway comprising: a first inlet chamber; a first outlet chamber; and a first plurality of orifices extending from the first inlet chamber to the first outlet chamber, the first plurality of orifices configured to provide a first plurality of impinging jet streams of coolant against a first region of a surface to be cooled when the redundant heat sink module is mounted on the surface to be cooled and when pressurized coolant is provided to the first inlet chamber; anda second independent coolant pathway formed within the redundant heat sink module, the second independent coolant pathway comprising: a second inlet chamber; a second outlet chamber; and a second plurality of orifices extending from the second inlet chamber to the second outlet chamber, the second plurality of orifices configured to provide a second plurality of impinging jet streams of coolant against a second region of the surface to be cooled when the redundant heat sink module is mounted on the surface to be cooled and when pressurized coolant is provided to the second inlet chamber, wherein the second outlet chamber circumscribes the first outlet chamber. 2. The redundant heat sink module of claim 1, wherein the first plurality of orifices have an average jet height of about 0.01-0.75, 0.05-0.5, 0.05-0.25, 0.020-0.25, 0.03-0.125, or 0.04-0.08 in. 3. The redundant heat sink module of claim 1, wherein the first plurality of orifices have an average diameter of about 0.001-0.020, 0.001-0.2, 0.001-0.150, 0.001-0.120, 0.001-0.005, 0.020-0.045, 0.030-0.050 in, or 0.040 in. 4. The redundant heat sink module of claim 1, wherein the first coolant pathway comprises a hydrofoil located upstream of the first inlet chamber, the hydrofoil comprising a curved surface. 5. The redundant heat sink module of claim 1, wherein the first outlet chamber is adjacent to the second outlet chamber. 6. The redundant heat sink module of claim 1, wherein the first inlet chamber decreases in cross-sectional area in a direction of flow, and wherein the first outlet chamber increases in cross-sectional area in the direction of flow. 7. The redundant heat sink module of claim 1, further comprising a flow-guiding lip proximate an exit of the first outlet chamber, the flow-guiding lip comprising a surface having an angle of less than about 45 degrees with respect to a bottom plane of the redundant heat sink module. 8. The redundant heat sink module of claim 1, wherein the first plurality of orifices have an average diameter of D and an average length of L, and wherein L divided by D is greater than or equal to one or about 1-10, 1-8, 1-6, 1-4, or 1-3. 9. A redundant apparatus for cooling a heat source, the redundant apparatus comprising: a thermally conductive base member configured to be placed in thermal communication with the heat source, the thermally conductive base member comprising a surface to be cooled;a redundant heat sink module mounted on the thermally conductive base member, the redundant heat sink module comprising:a first independent coolant pathway formed within the redundant heat sink module, the first independent coolant pathway comprising: a first inlet chamber; a first outlet chamber; and a first plurality of orifices configured to provide a first plurality of impinging jet streams of coolant against a first region of the surface to be cooled when pressurized coolant is provided to the first inlet chamber; anda second independent coolant pathway formed within the redundant heat sink module, the second independent coolant pathway comprising: a second inlet chamber; a second outlet chamber; and a second plurality of orifices configured to provide a second plurality of impinging jet streams of coolant against a second region of the surface to be cooled when pressurized coolant is provided to the second outlet chamber; andone or more sealing members disposed between a bottom surface of the redundant heat sink module and a surface of the thermally conductive base member to provide a first liquid-tight seal around a perimeter of the first outlet chamber and a second liquid-tight seal around a perimeter of the second outlet chamber, wherein the second region of the surface to be cooled circumscribes the first region of the surface to be cooled. 10. The apparatus of claim 9, wherein the thermally conductive base member is a metallic base plate. 11. The apparatus of claim 9, wherein the thermally conductive base member is a heat pipe comprising a sealed vapor cavity. 12. A redundant heat sink module for cooling a heat providing surface, the heat sink module comprising: a first independent coolant pathway, comprising: a first inlet chamber formed within the redundant heat sink module; a first outlet chamber formed within the redundant heat sink module, the first outlet chamber having a first open portion, the first open portion configured to be enclosed by the heat providing surface when the redundant heat sink module is sealed against the heat providing surface; and a first plurality of orifices extending from the first inlet chamber to the first outlet chamber;a second independent coolant pathway, comprising: a second inlet chamber formed within the redundant heat sink module; a second outlet chamber formed within the redundant heat sink module, the second outlet chamber having a second open portion, the second open portion configured to be enclosed by the heat providing surface when the redundant heat sink module is sealed against the heat providing surface; and a second plurality of orifices extending from the second inlet chamber to the second outlet chamber; anda plurality of anti-pooling orifices extending from the first inlet chamber to a rear wall of the first outlet chamber, the plurality of anti-pooling orifices configured to deliver a plurality of anti-pooling jet streams of coolant to a rear portion of the first outlet chamber when pressurized coolant is provided to the first inlet chamber. 13. The redundant heat sink module of claim 12, wherein the first plurality of orifices are arranged at an angle of about 20-80, 30-60, 40-50, or 45 degrees with respect to a bottom plane of the redundant heat sink module. 14. The redundant heat sink module of claim 12, wherein the first plurality of orifices are arranged in an array, the array being organized into staggered columns and staggered rows such that a given orifice in a given column and a given row does not have a corresponding orifice in a neighboring row in the given column or a corresponding orifice in a neighboring column in the given row. 15. The redundant heat sink module of claim 12, further comprising one or more boiling-inducing members extending into the first outlet chamber toward the heat providing surface, wherein a flow clearance between end portions of the boiling-inducing members and a bottom plane of the redundant heat sink module is about 0.001-0.0125, 0.001-0.05, 0.001-0.02, 0.001-0.01, or 0.005-0.010 in. 16. The redundant heat sink module of claim 12, wherein the first independent coolant pathway further comprises an upwardly angled inlet port fluidly connected to the first inlet chamber, wherein the upwardly angled inlet port has a central axis that defines an angle of about 10-80, 20-70, 30-60, or 40-50 degrees with respect to a bottom plane of the redundant heat sink module. 17. The redundant heat sink module of claim 12, wherein the first inlet chamber has a volume of about 0.01-0.02, 0.01-0.05, 0.04-0.08, 0.07-0.15, 0.1-0.2, 0.15-0.25, 0.2-0.4, 0.3-0.5 in3.
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