Abstract: An airflow sensor for a heat sink has a first portion having a first electrical point of contact, a second portion have a second electrical point of contact, and a deformable portion made of an electroactive material electrically coupled to the first and second portions. The deformable portion has first electrical properties measured between the first and second electrical points of contact when there is no airflow and the deformable portion is in a first position, and has second electrical properties different than the first electrical properties when a source of airflow blows air against the deformable portion, thereby causing the deformable portion to extend to a second position farther away from the source of airflow than the first position. The airflow sensor can be incorporated into a heat sink for an electronic component.

Abstract: A heat sink structure includes a heat sink; a threaded heat sink base pocket within the heat sink; a module lid, where the module lid thermally interfaces with a die; a threaded exterior portion of the module lid; and a thread engagement between the threaded heat sink base pocket and the threaded exterior portion of the module lid, where the thread engagement mechanically couples the heat sink to the module lid.

Abstract: A method affixes a heat sink to a module lid. A module lid is mounted to a substrate by use of a lid adhesive. The module lid has a threaded exterior portion. The module lid is thermally interfaced to a die by use of a thermal interface material. The heat sink is then screwed onto a module lid, where the heat sink includes a threaded heat sink base pocket that mates with the threaded exterior portion of the module lid, and wherein the heat sink is screwed down onto the module lid until 1) a solid mechanical and thermal contact is established between the heat sink and the module lid, and 2) an airflow from an air moving device flows unobstructed across vanes on the heat sink.

Abstract: A heat sink structure includes a heat sink; a threaded heat sink base pocket within the heat sink; a module lid, where the module lid thermally interfaces with a die; a threaded exterior portion of the module lid; and a thread engagement between the threaded heat sink base pocket and the threaded exterior portion of the module lid, where the thread engagement mechanically couples the heat sink to the module lid.

Abstract: A cooling system that includes two or more fans that each have a chassis. The chassis includes a first face, a second face, and a sidewall. The fans then can be attached to each other by attaching a sidewall of a first fan chassis to a sidewall of a second fan chassis. An adjustable vane is attached perpendicularly and approximately equidistant between the fans, with an angular control element that is attached to the first fan chassis. The vane can be oriented such that the vane divides the airflow distributed to the fans. The vane then can be adjusted radially by the angular control element, which is attached to the fan chassis. If an impeller of a fan chassis fails the vane can be adjusted radially using an angular control element to distribute more airflow to the failed fan superimposing the non-failed fan chassis.

Abstract: An airflow sensor for a heat sink has a substantially flat base portion and a deformable upper portion electrically coupled to the base portion that contacts a conductive strip. As airflow increases, the deformable upper portion deforms and moves away from the source of airflow, which moves the point of contact between the deformable upper portion and the conductive strip farther away from the source of the airflow. The difference in the point of contact is measured, and is used to characterize the airflow sensor for different airflows. Data from the airflow sensor can then be logged during system operation. When needed, the data from the airflow sensor can be read from the log and converted to airflow using the airflow sensor characterization data. In this manner the airflow through a heat sink may be dynamically measured, allowing analysis and correlation between system events and airflow through the heat sink.

Abstract: A heat pipe includes a reservoir of liquid that is connected to a horizontal portion of the heat pipe via a capillary connection. The heat pipe includes a temperature sensor in proximity to a heat interface in the horizontal portion and a controller that controls a heater for the reservoir. As power into the heat pipe increases, the controller turns on the heater, causing the temperature of the liquid in the reservoir to rise. Liquid then passes from the reservoir through the capillary connection into the horizontal portion, thereby dynamically increasing the amount of liquid in the heat pipe, which increases performance of the heat pipe at higher power levels. When the heater is off, as the heat pipe cools, the liquid condenses and flows back through the capillary connection into the reservoir. The result is a heat pipe that provides demand-based charging of the liquid based on power level.

Abstract: A heat pipe includes one or more reservoirs of liquid that are closed at lower temperatures and open at higher temperatures. The opening of the reservoirs at higher temperatures caused by higher power levels dynamically increases the amount of liquid in the heat pipe, which increases performance of the heat pipe at higher power levels. As the heat pipe cools, the liquid condenses and flows back into the reservoirs. As the heat pipe continues to cool, the reservoirs close. The result is a heat pipe that is more efficient at lower power levels and still maintains high efficiency at higher power levels due to the demand-based charging of the liquid based on temperature.

Abstract: A heat pipe includes one or more reservoirs of liquid that are closed at lower temperatures and open at higher temperatures. The opening of the reservoirs at higher temperatures caused by higher power levels dynamically increases the amount of liquid in the heat pipe, which increases performance of the heat pipe at higher power levels. As the heat pipe cools, the liquid condenses and flows back into the reservoirs. As the heat pipe continues to cool, the reservoirs close. The result is a heat pipe that is more efficient at lower power levels and still maintains high efficiency at higher power levels due to the demand-based charging of the liquid based on temperature.

Abstract: A heat pipe includes a reservoir of liquid that is connected to a horizontal portion of the heat pipe via a capillary connection. The heat pipe includes a temperature sensor in proximity to a heat interface in the horizontal portion and a controller that controls a heater for the reservoir. As power into the heat pipe increases, the controller turns on the heater, causing the temperature of the liquid in the reservoir to rise. Liquid then passes from the reservoir through the capillary connection into the horizontal portion, thereby dynamically increasing the amount of liquid in the heat pipe, which increases performance of the heat pipe at higher power levels. When the heater is off, as the heat pipe cools, the liquid condenses and flows back through the capillary connection into the reservoir. The result is a heat pipe that provides demand-based charging of the liquid based on power level.

Abstract: A method includes rotating a first elongated, inlet-side member of an air valve toward an open configuration when a fan blade is rotating and rotating the first inlet-side member to toward a closed configuration when the fan blade is not rotating. The air valve includes a frame and a sheet of thin material. The frame may have an outlet-side member configured to be mounted on a fan housing and the inlet-side member rotatably coupled to the outlet-side member. The material may have top and bottom edges, and a plurality of folds perpendicular to the top and bottom side edges that divide the sheet into a plurality of sections. The material may be attached to the outlet-side member and the inlet-side member, and configurable between folded and expanded positions.

Abstract: An air valve includes a frame and a sheet of thin material. The frame may have an outlet-side member configured mounted on a fan housing and an inlet-side member rotatably coupled to the outlet-side member. The material may have top and bottom edges, and a plurality of folds perpendicular to the top and bottom side edges that divide the sheet into a plurality of sections. The material may be attached to the outlet-side member and the inlet-side member, and configurable between folded and expanded positions. An attraction between a magnetic component on the inlet-side member and a magnetic component on a rotating fan blade may cause the inlet-side member to rotate, moving the material into the folded configuration. When the fan blade is not rotating, a spring attached at a pivot point may cause the inlet-side member to rotate in an opposite direction, moving the material into the expanded position.

Abstract: A cooling system that includes two or more fans that each have a chassis. The chassis includes a first face, a second face, and a sidewall. The fans then can be attached to each other by attaching a sidewall of a first fan chassis to a sidewall of a second fan chassis. An adjustable vane is attached perpendicularly and approximately equidistant between the fans, with an angular control element that is attached to the first fan chassis. The vane can be oriented such that the vane divides the airflow distributed to the fans. The vane then can be adjusted radially by the angular control element, which is attached to the fan chassis. If an impeller of a fan chassis fails the vane can be adjusted radially using an angular control element to distribute more airflow to the failed fan superimposing the non-failed fan chassis.

Abstract: A cooling system that includes two or more fans that each have a chassis. The chassis includes a first face, a second face, and a sidewall. The fans then can be attached to each other by attaching a sidewall of a first fan chassis to a sidewall of a second fan chassis. An adjustable vane is attached perpendicularly and approximately equidistant between the fans, with an angular control element that is attached to the first fan chassis. The vane can be oriented such that the vane divides the airflow distributed to the fans. The vane then can be adjusted radially by the angular control element, which is attached to the fan chassis. If an impeller of a fan chassis fails the vane can be adjusted radially using an angular control element to distribute more airflow to the failed fan superimposing the non-failed fan chassis.

Abstract: A cooling system that includes two or more fans that each have a chassis. The chassis includes a first face, a second face, and a sidewall. The fans then can be attached to each other by attaching a sidewall of a first fan chassis to a sidewall of a second fan chassis. An adjustable vane is attached perpendicularly and approximately equidistant between the fans, with an angular control element that is attached to the first fan chassis. The vane can be oriented such that the vane divides the airflow distributed to the fans. The vane then can be adjusted radially by the angular control element, which is attached to the fan chassis. If an impeller of a fan chassis fails the vane can be adjusted radially using an angular control element to distribute more airflow to the failed fan superimposing the non-failed fan chassis.

Abstract: A method includes rotating a first elongated, inlet-side member of an air valve toward an open configuration when a fan blade is rotating and rotating the first inlet-side member to toward a closed configuration when the fan blade is not rotating. The air valve includes a frame and a sheet of thin material. The frame may have an outlet-side member configured to be mounted on a fan housing and the inlet-side member rotatably coupled to the outlet-side member. The material may have top and bottom edges, and a plurality of folds perpendicular to the top and bottom side edges that divide the sheet into a plurality of sections. The material may be attached to the outlet-side member and the inlet-side member, and configurable between folded and expanded positions.

Abstract: An air valve includes a frame and a sheet of thin material. The frame may have an outlet-side member configured mounted on a fan housing and an inlet-side member rotatably coupled to the outlet-side member. The material may have top and bottom edges, and a plurality of folds perpendicular to the top and bottom side edges that divide the sheet into a plurality of sections. The material may be attached to the outlet-side member and the inlet-side member, and configurable between folded and expanded positions. An attraction between a magnetic component on the inlet-side member and a magnetic component on a rotating fan blade may cause the inlet-side member to rotate, moving the material into the folded configuration. When the fan blade is not rotating, a spring attached at a pivot point may cause the inlet-side member to rotate in an opposite direction, moving the material into the expanded position.

Abstract: Disclosed is a dynamic air moving system comprising a rail system disposed in an electronic enclosure, at least one fan housing moveably disposed on the rail system, the fan being actuatable along the rail system, a pivotable fan disposed in each of the at least one fan housings, at least one blade included with the fan, the at least one blade being rotatable about at least one blade axes, a fan controller chip controlling actuation of at least one fan housing, individual rotation of at least one blade, and rotation of the fan, a chip thermal sensor disposed on at least one chip located in the electronic enclosure, the thermal sensor being linked to the fan controller chip, and a drive thermal sensor disposed on at least one disk drive associated with the electronic enclosure, the drive thermal sensor being linked to the fan controller chip.

Abstract: Disclosed is a dynamic air moving system comprising a rail system disposed in an electronic enclosure, at least one fan housing moveably disposed on the rail system, the fan being actuatable along the rail system, a pivotable fan disposed in each of the at least one fan housings, at least one blade included with the fan, the at least one blade being rotatable about at least one blade axes, a fan controller chip controlling actuation of at least one fan housing, individual rotation of at least one blade, and rotation of the fan, a chip thermal sensor disposed on at least one chip located in the electronic enclosure, the thermal sensor being linked to the fan controller chip, and a drive thermal sensor disposed on at least one disk drive associated with the electronic enclosure, the drive thermal sensor being linked to the fan controller chip.