Abstract: A liquid cooled heat exchanger includes first and second heat exchange chambers that are in thermal communication. The first heat exchange chamber is downstream of the second heat exchanges chamber and receives heat from a heat generating device, such as an electronic circuit. Heat in the first heat exchange chamber can be transferred to the second heat exchange chamber to increase the temperature of a subcooled liquid working fluid in the second heat exchange chamber. This can render a pressure drop across the heat exchanger that is relatively insensitive to a fraction of liquid that is vaporized in the first heat exchange chamber.

Abstract: A thermosiphon device includes an evaporator section, a condenser section and a liquid path configured to deliver liquid that exits the evaporator section directly back to the evaporator inlet. The condenser section has a significantly reduced mass flow rate and lower pressure drop as compared to the evaporator section, which has an increase liquid fraction of working fluid.

Abstract: A thermosiphon device includes an evaporator section, a condenser section and a liquid path configured to deliver liquid that exits the evaporator section directly back to the evaporator inlet. The condenser section has a significantly reduced mass flow rate and lower pressure drop as compared to the evaporator section, which has an increase liquid fraction of working fluid.

Abstract: A heat sink for use in an immersion cooling system that includes a sintered powder structure enclosed in a porous enclosure. The porous enclosure has openings, e.g., formed by a mesh, with a size to help contain sintered powder particles that may be dislodged during operation of the heat sink.

Abstract: A thermosiphon device includes one or more flat multiport tube structures having at least one section that defines a plurality of flow channels and at least one web that extends from the section in a plane of the flat multiport tube structures. The flow channels may function as condensing channels, e.g., in a counterflow device, or as evaporation channels. A multiport tube structure may include two sections that each define a plurality of flow channels and the two sections may be joined by a web that extends between the sections in the plane of the multiport tube structure. The sections may function as condensing channels, as evaporation channels, or one section may function as a set of evaporation channel and the other section may function as a set of condensing channels. Multiport tube sections may alternately function as a vapor supply path or liquid return path.

Abstract: A thermosiphon device including one or more multi-port tubes that form both an evaporator section and a condenser section for the device. The one or more tubes may be flat tubes with multiple, parallel flow channels, and may be bent to form a bend between the evaporator and condenser sections of the tube(s). One or more flow channels of the tube at the bend may provide a vapor flow path or a liquid flow path between the evaporator and condenser sections.

Abstract: A fluid mover includes a chamber with one or more outlet openings, first and/or second fluidic diaphragm(s) having a portion movable in the chamber to cause fluid to move at the outlet opening, and a coil assembly magnetically coupled to the fluidic diaphragm to move the movable portion of the fluidic diaphragm(s) in response to a current in the coil. The coil assembly includes a coil with an opening, and a plug may be positioned in the opening and/or a support may be positioned around a periphery of the coil. The plug and/or the support may have a magnetic permeability greater than one and be arranged so magnetic field lines created by the coil pass through the plug and/or support. The coil, plug and/or support may define a flat surface, e.g., such that a uniform gap is present between the diaphragm(s) and the coil, plug and/or support.

Abstract: A thermosiphon device includes an evaporator section that is formed as a single integrated part including one or more evaporation channels and a liquid return path, and/or includes a condenser section that is formed as a single integrated part including one or more condensing channels and a vapor supply path. A single manifold may include vapor and liquid chambers that are separate from each other and that fluidly connect evaporation channels with the vapor supply path and fluidly connect condensing channels with the liquid return path, respectively. Portions of the evaporator or condenser section that define the liquid return path or vapor supply path, respectively, may be free of any fins or other thermal transfer structure.

Abstract: A thermosiphon device includes one or more flat multiport tube structures having at least one section that defines a plurality of flow channels and at least one web that extends from the section in a plane of the flat multiport tube structures. The flow channels may function as condensing channels, e.g., in a counterflow device, or as evaporation channels. A multiport tube structure may include two sections that each define a plurality of flow channels and the two sections may be joined by a web that extends between the sections in the plane of the multiport tube structure. The sections may function as condensing channels, as evaporation channels, or one section may function as a set of evaporation channel and the other section may function as a set of condensing channels. Multiport tube sections may alternately function as a vapor supply path or liquid return path.

Abstract: A thermosiphon device includes one or more flat multiport tube structures having at least one section that defines a plurality of flow channels and at least one web that extends from the section in a plane of the flat multiport tube structures. The flow channels may function as condensing channels, e.g., in a counterflow device, or as evaporation channels. A multiport tube structure may include two sections that each define a plurality of flow channels and the two sections may be joined by a web that extends between the sections in the plane of the multiport tube structure. The sections may function as condensing channels, as evaporation channels, or one section may function as a set of evaporation channel and the other section may function as a set of condensing channels. Multiport tube sections may alternately function as a vapor supply path or liquid return path.

Abstract: A thermosiphon device includes an evaporator section that is formed as a single integrated part including one or more evaporation channels and a liquid return path, and/or includes a condenser section that is formed as a single integrated part including one or more condensing channels and a vapor supply path. A single manifold may include vapor and liquid chambers that are separate from each other and that fluidly connect evaporation channels with the vapor supply path and fluidly connect condensing channels with the liquid return path, respectively. Portions of the evaporator or condenser section that define the liquid return path or vapor supply path, respectively, may be free of any fins or other thermal transfer structure.

Abstract: An assembly for engaging a heat sink with an electrical component heat source includes a first retaining device with a frame that defines an opening to receive at least a portion of the heat sink and/or the heat source. The frame may be assembled with a heat sink and a retainer element arranged to resiliently bias the heat sink into contact with the heat source, and thereafter the heat sink assembly may be engaged with a heat source. A contact plate of the heat sink may be positioned into the opening of the frame from a top of the frame, i.e., inserted in a top-down direction, and the frame may be arranged for engagement with a tool to mount the fully assembled heat sink, frame and retainer element combination to the heat source.

Abstract: A thermosiphon device including one or more multi-port tubes that form both an evaporator section and a condenser section for the device. The one or more tubes may be flat tubes with multiple, parallel flow channels, and may be bent to form a bend between the evaporator and condenser sections of the tube(s). One or more flow channels of the tube at the bend may provide a vapor flow path or a liquid flow path between the evaporator and condenser sections.

Abstract: A thermosiphon device includes a closed loop evaporator section having one or more evaporation channels that are fed by a liquid return path, and a condenser section with one or more condensing channels. The condenser section may include a vapor supply path that is adjacent one or more condensing channels, e.g., located between two sets of condensing channels. Evaporator and/or condenser sections may be made from a single, flat bent tube, which may be bent about an axis parallel to the plane of the flat tube to form a turnaround and/or twisted about an axis along a length of the tube at the tube ends. A single tube may form both evaporator and condenser sections of a thermosiphon device, and an axially extending wall inside the tube in the evaporator section may separate an evaporator section from a liquid return section.

Abstract: A fluid mover includes a chamber with one or more outlet openings, first and/or second fluidic diaphragm(s) having a portion movable in the chamber to cause fluid to move at the outlet opening, and a coil assembly magnetically coupled to the fluidic diaphragm to move the movable portion of the fluidic diaphragm(s) in response to a current in the coil. The coil assembly includes a coil with an opening, and a plug may be positioned in the opening and/or a support may be positioned around a periphery of the coil. The plug and/or the support may have a magnetic permeability greater than one and be arranged so magnetic field lines created by the coil pass through the plug and/or support. The coil, plug and/or support may define a flat surface, e.g., such that a uniform gap is present between the diaphragm(s) and the coil, plug and/or support.

Abstract: A system and method for deploying a heat harvesting system and for harvesting heat from a geothermal well using one or more heat pipes. A heat exchanger may receive heat from one or more heat pipes for transfer to a heat receiving component. The heat pipes may be thermally coupled to the heat exchanger via a thermal gap material having a relatively low thermal conductivity. A mounting component may engage heat pipes and define a thermal gap between the heat pipes and heat exchanger. A heat spreader, having a relatively high thermal conductivity, may be used to transfer heat from the heat pipes to the thermal gap material and help define a working temperature for the heat pipes. A heat pipe deployment system may include anti-buckling supports and/or a guide to help keep the heat pipes from buckling and to guide the heat pipes into corresponding well bores during deployment.

Abstract: An assembly for cooling heat generating components, such as power electronics, computer processors and other devices. Multiple components may be mounted to a support and cooled by a flow of cooling fluid. A single cooling fluid inlet and outlet may be provided for the support, yet multiple components, including components that have different heat removal requirements may be suitably cooled. One or more manifold elements may provide cooling fluid flow paths that contact a heat transfer surface of a corresponding component to receive heat.

Abstract: A thermal transfer device having a reduced vertical profile. The device includes a condenser with substantially vertical internal cooling fins. An inlet conducts a thermal transfer fluid in a vapor state to the tops of the cooling fins where the vapor condenses and flows down the fins to the bottom of the condenser. The bottom of the condenser is angled towards an outlet for conducting the liquid thermal transfer fluid to a reservoir for holding the fluid. The inlet and the outlet are both positioned at a height above the level of the thermal transfer fluid in liquid state in the reservoir. The device may also include fins on the exterior of the condenser for providing cooling surfaces which do not contact the thermal transfer fluid in either the liquid or vapor states.

Abstract: An assembly for cooling heat generating components, such as power electronics, computer processors and other devices. Multiple components may be mounted to a support and cooled by a flow of cooling fluid. A single cooling fluid inlet and outlet may be provided for the support, yet multiple components, including components that have different heat removal requirements may be suitably cooled. One or more manifold elements may provide cooling fluid flow paths that contact a heat transfer surface of a corresponding component to receive heat.

Abstract: A heat sink assembly includes a base plate having a top surface provided with cooling fins, and a bottom surface with an open channel, the channel having remote regions and a central region with a rectangular cross-section. A heat pipe arrangement including at least two sections is nested in the channel, each section having at least one evaporator section and a condenser section, wherein the evaporator sections are juxtaposed side by side in the central region, and the condenser sections are in respective remote regions. The arrangement is preferably a single S-shaped heat pipe with a pair of hooked ends and a center section which form the evaporator sections, the evaporator sections each having a rectangular profile and an exposed surface which is flush with the bottom surface of the base plate, the condenser sections connecting the evaporator sections and being recessed below the bottom surface.