Abstract: The invention provides a heat sink assembly having a positionable heat sink permitting the heat sink to be mounted to a substrate in more than one configuration. Various features are described for permitting multiple degrees of freedom in the arrangement of the heat sink assembly. Such features permit the heat sink assembly to be adapted to different environments. The heat sink assembly also has features such as a vane for directing air flow relative to the heat sink. Features for varying and maintaining pressure between the heat sink and a component to be cooled are also included.

Abstract: A thermo-electro sub-assembly comprises a gas supply, a first duct, a first heatsink adjacent a first device, a second duct, and a second heat sink adjacent a second device. The gas supply may be realized as a fan, a blower, or a compressed gas source. The first duct provides a passageway for delivering pressurized gas from the gas supply to the first heat sink. The duct may include a plurality of vanes for reducing the turbulence and air boundary separation within the duct. The first heatsink is in thermal communication with a first heat-producing device such as a microprocessor. In a preferred embodiment the heatsink comprises an axial shaped folded fin heatsink. The second duct is used to provide a pathway for the air leaving the first heatsink and delivers the air to the second heatsink. The second duct may also include a plurality of vanes for reducing turbulence and boundary flow separation within the second duct.

Abstract: The invention provides a heat sink assembly having a positionable heat sink permitting the heat sink to be mounted to a substrate in more than one configuration. Various features are described for permitting multiple degrees of freedom in the arrangement of the heat sink assembly. Such features permit the heat sink assembly to be adapted to different environments. The heat sink assembly also has features such as a vane for directing air flow relative to the heat sink. Features for varying and maintaining pressure between the heat sink and a component to be cooled are also included.

Abstract: A heat removal system comprising a gas supply, a duct, and a heatsink is presented. The gas supply may be realized as a fan, a blower, or a compressed gas source and is located remotely from the heatsink. The duct provides a passageway for delivering high velocity gas from the gas supply to the first heat sink. The duct includes a plurality of vanes for reducing the turbulence and air boundary separation within the duct. The heatsink is in thermal communication with a heat-producing device such as a microprocessor.

Abstract: The present invention comprises a heatsink adjacent a first device wherein a gas supply can be located to provide gas in any direction with respect to the heatsink. The gas supply may be realized as a fan, a blower, or a compressed gas source. The gas supply may be provided in any direction or in multiple directions. The heatsink is in thermal communication with a first heat-producing device such as a microprocessor. In a preferred embodiment the heatsink comprises a radial shaped folded fin heatsink arranged for axial flow.

Abstract: A heat removal system comprising a gas supply, a duct, and a heatsink is presented. The gas supply may be realized as a fan, a blower, or a compressed gas source and is located remotely from the heatsink. The duct provides a passageway for delivering high velocity gas from the gas supply to the first heat sink. The duct includes a plurality of vanes for reducing the turbulence and air boundary separation within the duct. The heatsink is in thermal communication with a heat-producing device such as a microprocessor.

Abstract: A thermo-electro sub-assembly comprises a gas supply, a first duct, a first heatsink adjacent a first device, a second duct, and a second heat sink adjacent a second device. The gas supply may be realized as a fan, a blower, or a compressed gas source. The first duct provides a passageway for delivering pressurized gas from the gas supply to the first heat sink. The duct may include a plurality of vanes for reducing the turbulence and air boundary separation within the duct. The first heatsink is in thermal communication with a first heat-producing device such as a microprocessor. In a preferred embodiment the heatsink comprises an axial shaped folded fin heatsink. The second duct is used to provide a pathway for the air leaving the first heatsink and delivers the air to the second heatsink. The second duct may also include a plurality of vanes for reducing turbulence and boundary flow separation within the second duct.