Abstract: An apparatus for cooling an electrical heat source is disclosed. A heat exchanger has two principal sub-assemblies. A closed-loop fluid flow is provided through a second sub-assembly, disposed next to a heat source. An open-loop fluid flow is provided though a first sub-assembly in communication with a second sub-assembly. Each of the first and second sub-assemblies has a rotational element. The fluid flow entering the first sub-assembly rotates the first rotational element, and magnetic communication between the rotational elements causes movement of the second rotational element, thereby achieving fluid movement within the second sub-assembly. Operationally, the closed-loop sub-assembly removes heat from the heat source and transfers it to the open-loop sub-assembly for subsequent heat transfer in a downstream fluid flow.

Abstract: In association with a liquid flow through a heat exchanger situated to remove heat from electronic devices, a coolant flow control apparatus is provided. The coolant flow control apparatus comprises a first input channel for carrying liquid coolant to a first input of the heat exchanger; a flow control device positioned along a flow path that includes the first input channel, the flow control device, in response to a temperature of coolant proximate to the flow control device, is operable to enable or to prevent coolant flow along the first input channel into the heat exchanger; a second input channel for continuously carrying liquid coolant to a second input of the heat exchanger, during both times when the flow control device is enabling and is preventing the coolant flow along the first input channel into the heat exchanger; and an output channel for carrying coolant away from the heat exchanger.

Abstract: An apparatus for cooling an electrical heat source is disclosed. A heat exchanger has two principal sub-assemblies. A closed-loop fluid flow is provided through a second sub-assembly, disposed next to a heat source. An open-loop fluid flow is provided though a first sub-assembly in communication with a second sub-assembly. Each of the first and second sub-assemblies has a rotational element. The fluid flow entering the first sub-assembly rotates the first rotational element, and magnetic communication between the rotational elements causes movement of the second rotational element, thereby achieving fluid movement within the second sub-assembly. Operationally, the closed-loop sub-assembly removes heat from the heat source and transfers it to the open-loop sub-assembly for subsequent heat transfer in a downstream fluid flow.

Abstract: A method and system for cooling an electrical heat source is disclosed. A heat exchanger has two principal sub-assemblies. A closed-loop fluid flow is provided through a second sub-assembly, disposed next to a heat source. An open-loop fluid flow is provided though a first sub-assembly in communication with a second sub-assembly. Each of the first and second sub-assemblies has a rotational element. The fluid flow entering the first sub-assembly rotates the first rotational element, and magnetic communication between the rotational elements causes movement of the second rotational element, thereby achieving fluid movement within the second sub-assembly. Operationally, the closed-loop sub-assembly removes heat from the heat source and transfers it to the open-loop sub-assembly for subsequent heat transfer in a downstream fluid flow.

Abstract: In association with a liquid flow through a heat exchanger situated to remove heat from electronic devices, a coolant flow control apparatus is provided. The coolant flow control apparatus comprises a first input channel for carrying liquid coolant to a first input of the heat exchanger; a flow control device positioned along a flow path that includes the first input channel, the flow control device, in response to a temperature of coolant proximate to the flow control device, is operable to enable or to prevent coolant flow along the first input channel into the heat exchanger; a second input channel for continuously carrying liquid coolant to a second input of the heat exchanger, during both times when the flow control device is enabling and is preventing the coolant flow along the first input channel into the heat exchanger; and an output channel for carrying coolant away from the heat exchanger.

Abstract: An embodiment of the invention is directed to coolant flow control apparatus, in association with a liquid flow through heat exchanger situated to cool one or more electronic or other device. The apparatus comprises a first input channel for carrying liquid coolant to a first input of the heat exchanger, and further comprises a flow control device positioned along a flow path that includes the first input channel. The flow control device is provided with a gating element supported for selected movement across the flow path, in order to selectively vary the amount of coolant moving through the flow path. The apparatus further include an actuator located in the flow control device that comprises a metal component which is directly tied to the gating element, wherein the metal component changes its shape in response to specified changes in coolant temperature, and a given change in the shape of the metal component acts to selectively move the gating element with respect to the flow path.

Abstract: An embodiment is directed to an IC mounting assembly that comprises an IC device having a first planar surface, wherein multiple electrically conductive first terminals are located at the first surface. The assembly further comprises an IC device mounting platform having a second planar surface in closely spaced relationship with the first surface, wherein multiple electrically conductive second terminals are located at the second surface, each second terminal corresponding to one of the first terminals. A solder element extends between each first terminal and its corresponding second terminal, and a constraining element is fixably joined to the second surface, wherein the constraining element has a CTE which is selectively less than the CTE of the mounting platform at the second surface. The constraining element is provided with a number of holes or apertures, and each hole is traversed by a solder element that extends between a first terminal and its corresponding second terminal.

Abstract: A thermal flow material-free thermally conductive interface between a mounted integrated circuit device and a heat sink that comprises a mounted integrated circuit device, a heat sink vertically disposed over the device, a vertically compressible thermally conductive member unattachably disposed between the device and the heat sink, and an unattached frame member horizontally enclosing the compressible member.

Abstract: A method and system for cooling an electrical heat source is disclosed. A heat exchanger has two principal sub-assemblies. A closed-loop fluid flow is provided through a second sub-assembly, disposed next to a heat source. An open-loop fluid flow is provided though a first sub-assembly in communication with a second sub-assembly. Each of the first and second sub-assemblies has a rotational element. The fluid flow entering the first sub-assembly rotates the first rotational element, and magnetic communication between the rotational elements causes movement of the second rotational element, thereby achieving fluid movement within the second sub-assembly. Operationally, the closed-loop sub-assembly removes heat from the heat source and transfers it to the open-loop sub-assembly for subsequent heat transfer in a downstream fluid flow.

Abstract: An embodiment of the invention comprises a method for constructing a heat exchanger for cooling one or more semiconductor components. The method comprises the step of providing first and second planar sheets of specified thermally conductive metal foil, wherein each of the sheets has and exterior side and an interior side. The method further comprises forming one or more thermal contact nodes (TCNs) in the first sheet, wherein each TCN extends outward from the exterior side of the first sheet, and comprises a planar contact member and one or more side sections, the side sections respectively including resilient components that enable the contact member of the TCN to move toward and away from the exterior side of the first sheet, and the side sections and contact member of a TCN collectively forming a coolant chamber.