| Entries |
| Document | Title | Date |
|---|
| 20130044433 | HEAT-DISSIPATING DEVICE FOR ELECTRONIC APPARATUS - A heat-dissipating device for an electronic apparatus can include: a thermal base coupled to a first electronic component in such a manner that enables heat-transfer therebetween so that heat generated by the first electronic component mounted on a substrate is absorbed thereby; and a vibrating capillary-shaped heat-pipe loop comprising a first heat-absorption portion coupled with the thermal base in such a manner that enables heat-transfer therebetween and a heat-dissipating portion configured to dissipate heat absorbed by the first heat-absorption portion, the heat-pipe loop having working fluid injected thereinto. The heat-pipe loop can be radially disposed with a central area thereof hollowed out, and an assembly area of a coupling member can be exposed in the central area so that the coupling member for coupling the thermal base to the substrate is coupled through the central area. | 02-21-2013 |
| 20130044432 | LOOP HEAT PIPE, AND ELECTRONIC APPARATUS INCLUDING LOOP HEAT PIPE - There is provided a loop heat pipe which includes an evaporator that internally includes at least one wick built, a condenser, a liquid pipe and a vapor pipe that connect the evaporator and the condenser to each other, and a heat dispersion cavity that is formed inside the evaporator, and disperses a vapor, wherein the wick includes, a first wick that is porous, a second wick that is porous, the second wick being inserted into the first wick from the liquid pipe side and including a pore size larger than the first wick, and a vapor channel that is defined between the first wick and the second wick. The vapor channel is connected at an end on the liquid pipe side to the heat dispersion cavity. | 02-21-2013 |
| 20090109623 | HEAT-RADIATING MODULE WITH COMPOSITE PHASE-CHANGE HEAT-RADIATING EFFICIENCY - The present invention provides a heat-radiating module with composite phase-change heat-radiating efficiency. The cooling pad of the heat-radiating module is fitted with a heating portion and radiating portion. The first and second chambers are placed at intervals into the cooling pad. The first and second phase-change materials are separately placed in two chambers. The reaction temperatures of two phase-change materials differ from each other. The phase-change material of higher reaction temperature assists in heat-absorbing and preventing overheating. There is a heat peak when the cooling pad reaches the preset high-temperature state. When the temperature of the cooling pad declines below a preset temperature, the phase-change material of lower reaction temperature will release the stored latent heat, enabling the cooling pad to maintain an operating temperature and improve the heat-radiating efficiency in a variety of equipment. | 04-30-2009 |
| 20090195984 | COOLING DEVICE - A cooling device for dissipating heat generated by an electronic element includes a fixing seat, a cooling body, and a vapor chamber. The fixing seat is arranged an opening. The cooling body includes a bottom plate attached onto the fixing seat and a plurality of cooling fins that are interspaced to each other and are attached to the bottom plate, in which a fixing hole is arranged at one side of the bottom plate, and an accommodating space is configured at the cooling fins in corresponding to the fixing hole. The vapor chamber is accommodated in the opening of the fixing seat, and one side of the vapor chamber contacts a bottom part of the cooling body, while another side contacts the electronic element. | 08-06-2009 |
| 20090122488 | APPARATUS FOR FACILITATING COOLING OF AN ELECTRONICS RACK THROUGH THE USE OF AN AIR-TO-LIQUID HEAT EXCHANGER - An apparatus for facilitating cooling of an electronics rack is provided. The apparatus includes an air-to-liquid heat exchanger and system coolant inlet and outlet plenums mounted to a door of an electronics rack. The inlet and outlet plenums are in fluid communication with the heat exchanger and respectively include a coolant inlet and coolant outlet in the top portions thereof. System coolant supply and return hoses are disposed above the electronics rack and respectively couple in fluid communication the inlet plenum to a system coolant supply header and the outlet plenum to a system coolant return header. The hoses are each flexible, partially looped and of sufficient length to allow for opening and closing of the door. Stress-relief structures are coupled to at least one end of the hoses to relieve stress on the ends of the hoses during opening or closing of the door. | 05-14-2009 |
| 20100118493 | MOTOR DRIVE WITH HEAT PIPE AIR COOLING - An air cooled switching unit for a motor drive includes a plurality electrical switches and a plurality of heat pipe assemblies. Each heat pipe assembly includes a thermally and electrically conductive evaporator, a condenser, and at least one heat pipe extending between the evaporator and condenser. Each of the switches is abutted with an evaporator of at least one of the heat pipe assemblies for conduction of both electrical power and heat between the switch and the evaporator. Each heat pipe assembly further includes an electrically conductive base abutted with the evaporator, and the air cooled switching unit further includes a plurality of power lugs each connected to a base of a respective one of the heat pipe assemblies for input or output of electrical power to the base and the evaporator plate abutted with the base. Each heat pipe assembly includes at least one evaporator defined by a metallic plate. The condenser of each heat pipe assembly includes a plurality of parallel spaced-apart cooling fins. The at least one heat pipe of each heat pipe assembly includes a sealed pipe containing a phase-change material for transferring heat from said evaporator to said condenser. The at least one heat pipe includes a first end located in the metallic plate and a second end in contact with and extending through the cooling fins of the condenser. A temperature feedback system derives air flow velocity through the condenser. | 05-13-2010 |
| 20100073880 | HEAT DISSIPATION DEVICE - A heat dissipation device includes two heat pipes, three extruded heat sinks and a heat conducting plate. Each heat pipe has a substantially G-shaped configuration and includes a heat absorbing section and first and second heat dissipating sections. The first and second heat dissipating sections extend along opposite directions, wherein the second heat dissipating section is located above the first heat dissipating section. Each heat sink includes a main body and a plurality of fins extending from the main body. The main body of each heat sink has a same profile with that of each heat pipe. Each heat pipe is sandwiched between the main bodies of two adjacent heat sinks. The heat conducting plate is attached to the main bodies of the heat sinks and the heat absorbing sections of the heat pipes. | 03-25-2010 |
| 20130077247 | VALVE CONTROLLED, NODE-LEVEL VAPOR CONDENSATION FOR TWO-PHASE HEAT SINK(S) - A cooling apparatus and method are provided for cooling one or more electronic components of an electronic subsystem of an electronics rack. The cooling apparatus includes a heat sink, which is configured to couple to an electronic component, and which includes a coolant-carrying channel for coolant to flow therethrough. The coolant provides two-phase cooling to the electronic component, and is discharged from the heat sink as coolant exhaust which comprises coolant vapor to be condensed. The cooling apparatus further includes a node-level condensation module, associated with the electronic subsystem, and coupled in fluid communication with the heat sink to receive the coolant exhaust from the heat sink. The condensation module is liquid-cooled, and facilitates condensing of the coolant vapor in the coolant exhaust. A controller automatically controls the liquid-cooling of the heat sink and/or the liquid-cooling of the node-level condensation module. | 03-28-2013 |
| 20130077245 | COOLING MODULE FOR COOLING ELECTRONIC COMPONENTS - A cooling module including a condenser, a power module including the cooling module and a method for cooling electric and/or electronic components are provided. The condenser of the cooling module includes at least one panel for cooling electric and/or electronic components. Two sheets of the panel are attached to one another by a process involving roll-bonding such that a conduit is formed between the two sheets. The conduit extends in a direction of a plane formed by the sheets. Cooling may be provided by evaporating coolant in the conduit at an evaporation section of the panel and by condensing the coolant at a condensing section of the panel. A heat load may be transferred from a heat source to a heat receiving unit. The heat receiving unit is adapted to transfer the heat load to the panel which transfers the heat load to an ambient environment by a thermal carrier. | 03-28-2013 |
| 20130077246 | HEAT SINK STRUCTURE WITH A VAPOR-PERMEABLE MEMBRANE FOR TWO-PHASE COOLING - A heat sink, and cooled electronic structure and cooled electronics apparatus utilizing the heat sink are provided. The heat sink is fabricated of a thermally conductive structure which includes one or more coolant-carrying channels coupled to facilitate the flow of coolant through the coolant-carrying channel(s). The heat sink further includes a membrane associated with the coolant-carrying channel(s). The membrane includes at least one vapor-permeable region, which overlies a portion of the coolant-carrying channel(s) and facilitates removal of vapor from the coolant-carrying channel(s), and at least one orifice coupled to inject coolant onto at least one surface of the coolant-carrying channel(s) intermediate opposite ends of the channel(s). | 03-28-2013 |
| 20130039012 | HEAT DISSIPATION DEVICE - The present invention relates to a heat dissipation device, including at least one semiconductor device, at least one first substrate and a cooling substance. The first substrate has a first surface, a second surface and at least one hole, wherein the semiconductor device is located on the first surface of the first substrate, and the hole is opened at the second surface of the first substrate and corresponds to the semiconductor device. The cooling substance is used for flowing in the hole and taking away heat from the semiconductor device, wherein the cooling substance is in contact with the first substrate. Thereby, the temperature of the semiconductor device can be reduced efficiently. | 02-14-2013 |
| 20130039011 | HEAT-DISSIPATING MODULE - A heat-dissipating module applied to a circuit board having an electronic element is disclosed. The heat-dissipating module includes a plurality of connecting portions, a contacting portion and a folded portion. The heat-dissipating module is connected to the circuit board by the connecting portions, and a first surface of the contacting portion contacts the electronic element. The folded portion is connected to the contacting portion. The heat-dissipating module is suitable for a thin and light electronic device and has firm structure. | 02-14-2013 |
| 20090154104 | Cooling Device and Electronic Apparatus Using the Same - It is an object to provide a cooling device for optimally cooling a semiconductor device on a CPU blade which is detachable with respect to an electronic apparatus using the cooling device with compact structure for reducing power consumption. A cooling device for cooling a semiconductor device disposed on an electronic circuit substrate in a casing of an electronic apparatus, comprising a first cooling unit comprising a first heat absorbing portion and a first heat releasing portion, and a second cooling unit comprising a second heat absorbing portion and a second heat releasing portion, wherein the first heat absorbing portion is disposed in contact with the semiconductor device, the second heat absorbing portion is detachably disposed in contact with the first heat releasing portion, a phase-change refrigerant is contained in the first cooling unit, and the second heat releasing portion is disposed outside the casing. | 06-18-2009 |
| 20090154103 | HEAT DISSIPATION DEVICE - A heat dissipation device includes a base, a first heat sink located on the base, a second heat sink located on the first heat sink, and a heat pipe contacting with the base and the first and second heat sink. The first heat sink includes a heat spreader and a plurality of fins extending from the heat spreader. The second heat sink includes a heat spreader and a plurality of fins extending from the heat spreader. The heat pipe includes an evaporating portion, first and second condensing portions parallel to the evaporating portion and first and second connecting portions interconnecting corresponding first and second condensing portion and the evaporating portion. The evaporating portion and the first condensing portion are located between the base and the heat spreader of the first heat sink. The second condensing portion is located on the heat spreader of the second heat sink. | 06-18-2009 |
| 20090154102 | HEAT DISSIPATION DEVICE - A heat dissipation device includes a spreader, a heat sink comprising a base plate and a plurality of outer fins extending upwardly from a top surface of the base plate, a heat pipe thermally connecting the heat sink and the spreader together, a plurality of fasteners each including a fixture having a head at a top thereof, a spring encircling the fixture and a gasket wired on the fixtures. The fixtures extend through the base plate of the heat sink and the spreader, the gaskets are respectively compressed between the heads and the base plate, edge of the base plate of the heat sink is joined with the housing of the computer, and cooperates with the housing to form a hermetic encapsulation which encloses the heat-generating electronic component. | 06-18-2009 |
| 20130027884 | VALVE CONTROLLED, NODE-LEVEL VAPOR CONDENSATION FOR TWO-PHASE HEAT SINK(S) - A cooling apparatus and method are provided for cooling one or more electronic components of an electronic subsystem of an electronics rack. The cooling apparatus includes a heat sink, which is configured to couple to an electronic component, and which includes a coolant-carrying channel for coolant to flow therethrough. The coolant provides two-phase cooling to the electronic component, and is discharged from the heat sink as coolant exhaust which comprises coolant vapor to be condensed. The cooling apparatus further includes a node-level condensation module, associated with the electronic subsystem, and coupled in fluid communication with the heat sink to receive the coolant exhaust from the heat sink. The condensation module is liquid-cooled, and facilitates condensing of the coolant vapor in the coolant exhaust. A controller automatically controls the liquid-cooling of the heat sink and/or the liquid-cooling of the node-level condensation module. | 01-31-2013 |
| 20130027883 | FLOW BOILING HEAT SINK STRUCTURE WITH VAPOR VENTING AND CONDENSING - A heat sink, and cooled electronic structure and cooled electronic apparatus utilizing the heat sink, are provided. The heat sink is fabricated of a thermally conductive structure which includes one or more coolant-carrying channels and one or more vapor-condensing channels. A membrane is disposed between the coolant-carrying channel(s) and the vapor-condensing channel(s). The membrane includes at least one vapor-permeable region, at least a portion of which overlies a portion of the coolant-carrying channel(s) and facilitates removal of vapor from the coolant-carrying channel(s) to the vapor-condensing channel(s). The heat sink further includes one or more coolant inlets coupled to provide a first liquid coolant flow to the coolant-carrying channel(s), and a second liquid coolant flow to condense vapor within the vapor-condensing channel(s). | 01-31-2013 |
| 20130083485 | HEAT DISSIPATION APPARATUS FOR MEDIUM-VOLTAGE DRIVE - A heat dissipation apparatus is suitable for dissipating heat from heat-generating elements in a medium-voltage drive. The heat dissipation apparatus comprises: a heat-dissipating substrate, wherein the heat-generating elements are placed on at least one of a first surface and a second surface of the heat-dissipating substrate; at least one heat pipe group each of which includes a plurality of heat pipes, each heat pipe having an evaporation section and a condensation section, wherein the evaporation section is buried in an inner layer of the heat-dissipating substrate for absorbing heat from the heat-generating elements; and a plurality of fins arranged to be intersected with each heat pipe and connected to the condensation sections of the heat pipes, so as to transfer the heat released from the condensation sections to air. The contact portions between the heat pipe group and the fins are arranged in triangle staggered arrangements. | 04-04-2013 |
| 20130070420 | FLOW BOILING HEAT SINK WITH VAPOR VENTING AND CONDENSING - A method is provided for facilitating extraction of heat from a heat-generating electronic component. The method includes providing a heat sink, the heat sink including a thermally conductive structure which has one or more coolant-carrying channels and one or more vapor-condensing channels. A membrane is disposed between the coolant-carrying channel(s) and the vapor-condensing channel(s). The membrane includes at least one vapor-permeable region, at least a portion of which overlies a portion of the coolant-carrying channel(s) and facilitates removal of vapor from the coolant-carrying channel(s) to the vapor-condensing channel(s). The heat sink further includes one or more coolant inlets coupled to provide a first liquid coolant flow to the coolant-carrying channel(s), and a second liquid coolant flow to condense vapor within the vapor-condensing channel(s). | 03-21-2013 |
| 20130070419 | ELECTRONIC DEVICE WITH HEAT DISSIPATING MODULE - An electronic device includes a circuit board and a heat dissipating module. The circuit board includes a body and a first heat generating part located on the body. The body defines a through hole close to the first heat generating part. The heat dissipating module includes a heat pipe, a first heat dissipating piece attached to the heat pipe and a resilient piece. The resilient piece includes a securing portion secured to the first heat dissipating piece and a resilient arm. The resilient arm is engaged in the through hole to secure the first heat dissipating piece to the body. The first heat dissipating piece abuts the first heat generating part, and the resilient arm is elastically deformable to disengage from the through hole. | 03-21-2013 |
| 20130070418 | HEAT DISSIPATION MODULE - An electronic device includes printed circuit board having an electronic component and a heat dissipation module mounted the printed circuit board. The heat dissipation module includes a base with a heat absorbing plate and two elastic pieces extending from the heat absorbing plate. The heat absorbing plate thermally engages on the electronic component. The elastic pieces are fixed on the printed circuit board. The base is made of one of copper-nickel-silicon alloy, beryllium copper, a titanium copper or phosphor bronze. | 03-21-2013 |
| 20100002394 | FASTENING DEVICE FOR THERMAL MODULE - A thermal module includes a heat sink ( | 01-07-2010 |
| 20130088836 | HEAT DISSIPATION STRUCTURE FOR ELECTRONIC DEVICE - A heat dissipation structure in which an IC chip that generates heat is mounted on a substrate and a heat dissipation sheet is interposed between a cover member and the IC chip to dissipate heat, wherein chip-pressing parts ( | 04-11-2013 |
| 20120218711 | COOLING SYSTEM FOR ELECTRONIC EQUIPMENT - In a cooling system for an electronic device of the present invention, server rooms in which a plurality of servers are placed, an evaporator which is provided close to each of the servers, and cools exhaust air from the server by vaporizing a refrigerant with heat generating from the server, a cooling tower which is provided at a place higher than the evaporator, cools the refrigerant by outside air and water sprinkling, and condenses the vaporized refrigerant, and a circulation line in which the refrigerant naturally circulates between the evaporator and the cooling tower. According to the cooling system, an electronic device which is required to perform a precise operation with a heat generation amount from itself being large, such as a computer and a server, can be efficiently cooled at low running cost. | 08-30-2012 |
| 20100097766 | FIXING DEVICE FOR HEAT SINK - A fixing device fastens a heat sink having a base on one of motherboards with different specifications. Each motherboard with a corresponding specification defines a plurality of extending holes therethrough. The fixing device comprises a plurality of slats each having an end thereof pivotally connecting to the base of the heat sink and the other end thereof defining an elongated slot for corresponding to one of the extending holes of the one of the motherboards, a back plate defining a plurality of mounting holes corresponding to the extending holes of the motherboards, and a plurality of fixing units extending through the slots of the slats, the extending holes of the one of the motherboards and corresponding mounting holes of the back plate to mount the heat sink on the one of the motherboards. | 04-22-2010 |
| 20130058042 | Laminated heat sinks - An apparatus includes a heat sink with a complex 3D structure. The heat sink includes a stack of metal layers. The metal layers are mechanically connected together and being separated by physical interface regions. The stack has array of channels for carrying fluid through the stack. Each channel of the array has a lateral surface formed by portions of more than one of the metal layers. | 03-07-2013 |
| 20130063897 | Modular High-Power Drive Stack Cooled with Vaporizable Dielectric Fluid - A high power drive stack system is provided which includes a cabinet having a vaporizable dielectric fluid cooling system and a plurality of receivers for accepting a plurality of modules containing power electronics. The modules are removably attachable to the receivers by at least two non-latching, dry-break connectors. Each of the at least two connectors providing both a fluid connection and an electrical connection between the cabinet and the module. | 03-14-2013 |
| 20130063896 | HEATSINK APPARATUS AND ELECTRONIC DEVICE HAVING SAME - A heatsink apparatus performs cooling by circulating a working fluid and causing a phase change between a liquid phase and a gas phase. The heatsink apparatus includes a box-shaped heat receiver, provided with a heat-generating body on an external wall, to transfer heat to an internal wall. The heatsink apparatus includes an inlet pipe supplying the working fluid to the heat receiver, an outlet pipe discharging vapor, into which the working fluid supplied to the heat receiver is evaporated by heat, and a heat dissipater dissipating heat of the vapor passing through the outlet pipe. An opening portion of the inlet pipe is opposite to and near the internal wall so as cause the working fluid near the internal wall to flow. | 03-14-2013 |
| 20090009969 | HEAT-DISSIPATING CASING STRUCTURE - A heat-dissipating casing structure includes a base seat, a heat-dissipating module, and a casing. The heat-dissipating module is disposed on the base seat. The heat-dissipating module has a first heat-conducting block and a heat pipe, and one side of the heat pipe connects to the first heat-conducting block. The casing has an installed portion, and the casing is slidably assembled on the base seat for connecting the other side of the heat pipe with the casing via the installed portion. When the casing is slidably assembled on the base seat, the heat pipe is connected with the casing via the installed portion. Hence, the heat-dissipating module is assembled and replaced easily and rapidly. Moreover, the heat from a heat-generating element on the base seat is transmitted to the casing through the heat pipe for increasing heat-dissipating efficiency. | 01-08-2009 |
| 20080266802 | Phase change cooled electrical connections for power electronic devices - A technique is disclosed for cooling connections points in power electronic circuits, such as points at which wire bonding connections are made. A phase change heat spreader is thermally coupled at or near the connection point and a continuous phase change takes place in the heat spreader to extract heat from the connection point during operation. The heat spreader may extend over a area larger than the connection point to enhance cooling and to dissipate heat over a larger area. Small, specifically directed applications are possible in which specific points are cooled together or individually. | 10-30-2008 |
| 20110279978 | COOLING DEVICE - A cooling device of the present invention includes: a substrate having a first surface which supports an electronic component and a second surface on an opposite side to the first surface; a container which can form a space between itself and the second surface of the substrate; and an evaporation section which is thermally connected to the electronic component supported on the substrate, which is arranged in the space so that at least a portion thereof is in contact with a liquid within the space, and which changes a phase of at least a portion of the liquid to gas on a basis of heat generated by the electronic component. | 11-17-2011 |
| 20110149517 | Aircraft Electronics Cooling Apparatus For An Aircraft Having A Liquid Cooling System - The invention relates to an improved aircraft electronics cooling system for an aircraft having a liquid cooling system ( | 06-23-2011 |
| 20110286184 | THERMAL PACKAGING OF A MOTOR CONTROLLER FOR AN AUXILIARY POWER UNIT - A starter motor controller for an auxiliary power unit transfers thermal energy from low thermal capacity electric components to high thermal capacity electric components to control temperature without active cooling systems. | 11-24-2011 |
| 20130021752 | TWO-PHASE, WATER-BASED IMMERSION-COOLING APPARATUS WITH PASSIVE DEIONIZATION - Cooling apparatuses, cooled electronic modules and methods of fabrication are provided for fluid immersion-cooling of an electronic component(s). The cooled electronic module includes a substrate supporting the electronic component(s), and the cooling apparatus couples to the substrate, and includes a housing at least partially surrounding and forming a compartment about the electronic component(s). Additionally, the cooling apparatus includes a fluid and a deionization structure disposed within the compartment. The electronic component is at least partially immersed within the fluid, and the fluid is a water-based fluid. The deionization structure includes deionizing material, which ensures deionization of the fluid within the compartment. The deionization structure facilitates boiling heat transfer from the electronic component(s) to a condenser structure disposed in the compartment. Transferred heat is subsequently conducted to, for example, a liquid-cooled cold plate or an air-cooled heat sink coupled to the housing for cooling the condenser structure. | 01-24-2013 |
| 20090034194 | MINIATURIZED LIQUID COOLING DEVICE - A miniaturized liquid cooling device ( | 02-05-2009 |
| 20100033933 | HEAT SPREADER, ELECTRONIC APPARATUS, AND HEAT SPREADER MANUFACTURING METHOD - According to an embodiment, there is provided a heat spreader including an evaporation portion, a first condenser portion, a working fluid, and a first flow path. The evaporation portion is arranged in a first position. The first condenser portion is arranged in a second position, the second position being the first position. The working fluid evaporates from a liquid phase to a gas phase in the evaporation portion, and condenses from the gas phase to the liquid phase in the first condenser portion. The first flow path is made of a nanomaterial, has hydrophobicity on a surface, and causes the working fluid condensed to the liquid phase in the first condenser portion to flow to the evaporation portion. | 02-11-2010 |
| 20110170264 | Semiconductor Module Socket Apparatus - A semiconductor module socket apparatus including a socket main body in which a socket groove corresponding to a semiconductor module is formed; a socket pin mounted in the socket groove of the socket main body so as to be electrically connected to a module pin of the semiconductor module; and a heat radiating member mounted in the socket main body so as to externally radiate heat that is generated in the semiconductor module and then is delivered from the socket groove and the socket pin. According to the semiconductor module socket apparatus, it is possible to prevent the heat generated in the semiconductor module from being delivered to the main board, to increase the heat radiation efficiency, to significantly save an installation space, to reduce the installation costs, and to realize no-noise and no-vibration of the semiconductor module socket apparatus. | 07-14-2011 |
| 20100079952 | HEAT-DISSIPATING MODULE AND ELECTRONIC DEVICE HAVING THE SAME - An electronic device having a heat-dissipating module includes a housing and an electronic component (e.g., a central processing unit) disposed within the housing. The heat-dissipating module is used for dissipating heat of the electronic component, and includes a two-phase flow heat-dissipating loop and a thermoelectric cooling component. The two-phase flow heat-dissipating loop can be a loop heat pipe (LHP) or a capillary pumped loop (CPL). The thermoelectric cooling component includes a cooling portion and a heat-generating portion respectively to cool or heat necessary portions of the two-phase flow heat-dissipating loop, or directly cool the electronic component through the cooling portion, thereby increasing the heat-dissipation effect of the two-phase flow heat-dissipating loop. | 04-01-2010 |
| 20090310307 | INTEGRATED HEAT-DISSIPATING DEVICE FOR PORTABLE ELECTRONIC PRODUCT - An integrated heat-dissipating device for a portable electronic product includes a heat-conducting base, a heat-dissipating plate, a first heat-dissipating module and a second heat-dissipating module. The heat-dissipating plate is adhered onto the heat-conducting base. The coefficient of heat conductivity of the heat-dissipating plate is larger than that of the heat-conducting base. The first heat-dissipating module includes a first heat pipe. One section of the first heat pipe is connected to the heat-conducting base, and the other section thereof extends in a direction away from the heat-conducting base. The second heat-dissipating module includes a second heat pipe, an adapting block and a third heat pipe. One section of the second heat pipe is connected to the heat-conducting base, and the other section thereof is connected to the adapting block. One section of the third heat pipe is connected to the adapting block, and the other section thereof extends in a direction away from the adapting block. With a multiple-directional heat-dissipating path, a great amount of heat generated by a heat-generating source can be dissipated to the outside quickly. | 12-17-2009 |
| 20110013364 | MODULAR HIGH-POWER DRIVE STACK COOLED WITH VAPORIZABLE DIELECTRIC FLUID - A high power drive stack system is provided which includes a cabinet ( | 01-20-2011 |
| 20100079953 | Electronic Appartus - According to one embodiment, an electronic apparatus includes a connector electrically connecting a sub-board to a main board, a heat producing component mounted on the sub-board, a heat pipe opposed to the heat producing component, a pressing member, and fixing members. The pressing member includes a main part opposed to the heat pipe, and a plurality of fixing parts extending from the main part and being located closer to the connector than the main part is. The plurality of fixing members fix the fixing parts of the pressing member to the sub-board, and fix the sub-board to support members at positions that are closer to the connector than the main part is. | 04-01-2010 |
| 20090273904 | HEAT-DISSIPATION MODULE AND ELECTRONIC APPARATUS HAVING THE SAME - An electronic apparatus including a circuit board having multiple heat generating elements and a heat-dissipation module is provided. The heat-dissipation module includes a heat-dissipation plate and a heat pipe set. The heat-dissipation plate having a first surface and a second surface is disposed on the circuit board and having multiple contacting portions and at least one heat pipe protecting portion connecting the contacting portions. The contacting portions are used for receiving heat from the heat generating elements. A heat pipe accommodating groove passing through the heat pipe protecting portion is set on the first surface. The heat pipe set is disposed in the heat pipe accommodating groove of the heat-dissipation plate. | 11-05-2009 |
| 20090284924 | THERMAL TRANSFER TECHNIQUE USING HEAT PIPES WITH INTEGRAL RACK RAILS - A thermal transfer apparatus for cooling a heat-producing electronic component includes an evaporator disposed over the heat-producing electronic component and thermally coupled to the heat-producing electronic component, a plurality of heat pipes carrying a working fluid therein disposed over the evaporator and thermally coupled to the evaporator, a cold plate thermally coupled to a first end of the plurality of heat pipes, and a condenser thermally coupled to a second end of the plurality of heat pipes. The heat pipes extend over the evaporator such that the first end and the second end of the heat pipes couple to the cold plate and condenser at a location not over the heat-producing electronic component. The cold plate and the condenser are supplied with a coolant from outside the thermal transfer apparatus. | 11-19-2009 |
| 20090284923 | IGBT PACKAGING AND COOLING USING PCM AND LIQUID - A power control system may use power semiconductor devices such as insulated gate bipolar transistors (IGBT's) in a switching unit to provide motor control. The IGBT's may be cooled with a system that is configured and sized to provide proper cooling at steady-state operating conditions of the switching unit. The IGBT's may be placed in thermal communication with a compartment that may contain phase change material (PCM). When and if the switching unit is operated under transient high load conditions, excess heat may be absorbed by melting of the PCM. When steady state operating conditions are restored the PCM may solidify and release its latent heat to a coolant. The PCM may thus act as a thermal buffer for the cooling system and thus may provide that the cooling system may be minimally sized. | 11-19-2009 |
| 20090284926 | TWO-PHASE COOLING CIRCUIT - The disclosure relates to a two-phase cooling circuit. The cooling circuit can include an evaporator and a condenser. The evaporator and condenser can be connected by a feeder line and a first return line. A phase separator is arranged at an inlet side of the condenser. The phase separator can be connected with the evaporator by a second return line. | 11-19-2009 |
| 20090284925 | EVAPORATOR FOR A COOLING CIRCUIT - An evaporator is disclosed for a cooling circuit. The evaporator includes a housing having at least one wall for contacting a heat emitting device. A channel, the cross section of which is small enough to allow convection boiling, and a separation volume are located in the evaporator. The separation volume is located at a vapor exiting port of the channel. The evaporator can include a liquid reservoir. | 11-19-2009 |
| 20100277868 | INSULATED METAL SUBSTRATES INCORPORATING ADVANCED COOLING - A power module includes one or more semiconductor power devices bonded to an insulated metal substrate (IMS). A plurality of cooling fluid channels is integrated into the IMS. | 11-04-2010 |
| 20090002947 | Evaporative cooling system for electronic components - An apparatus for cooling a number of electronic components comprises an enclosure within which the components are positioned, an arrangement for circulating a cooling fluid to the components so that the cooling fluid can evaporate on or proximate the components and thereby absorb the heat generated by the components, a mechanism for condensing the evaporated cooling fluid, and a reservoir which is in fluid communication with the circulating means and within which the condensed cooling fluid collects. | 01-01-2009 |
| 20120170221 | COMPLIANT VAPOR CHAMBER CHIP PACKAGING - An arrangement for improving the cooling efficiency of semiconductor chips. One embodiment is to construct a vapor chamber with one compliant surface for improving the efficiency of transferring heat from a semiconductor chip to the vapor chamber, and another embodiment is to construct a vapor chamber with the chip substrate such that the chips are embedded inside the vapor chamber. One surface of the vapor chamber has a flexible structure to enable the surface of the vapor chamber to be compliant with the surface of a chip or a heat sink device. | 07-05-2012 |
| 20080291630 | METHOD AND APPARATUS FOR COOLING COMPUTER MEMORY - A method and apparatus for cooling chips on a computer memory module. The apparatus includes a primary and secondary heat spreaders, at least a first heatpipe coupled to the primary heat spreader and having a remote portion spaced apart from the primary heat spreader and thermally contacting the secondary heat spreader, and a coolant within the first heatpipe and the primary heat spreader so as to absorb heat from the primary heat spreader and conduct the heat to the secondary heat spreader. The primary heat spreader has at least two panels configured to engage the memory module therebetween, with facing contact surfaces of the panels adapted for thermal contact with the module chips. The secondary heat spreader is configured to increase surface dissipation of heat from the first heatpipe into the environment. The coolant has a boiling point at or below a maximum preselected operating temperature of the module chips. | 11-27-2008 |
| 20080310111 | TRANSPIRATION COOLING FOR PASSIVE COOLED ULTRA MOBILE PERSONAL COMPUTER - In some embodiments, transpiration cooling for passive cooled ultra mobile personal computer is presented. In this regard, an apparatus is introduced having a plurality of integrated circuit device(s), a power source to power the integrated circuit device(s), a chassis to house the integrated circuit device(s) and the power supply, and a skin to cover the chassis, the skin comprising a waterproof layer configured to prevent water from contacting the integrated circuit device(s) and a water absorbent layer configured to absorb water. Other embodiments are also disclosed and claimed. | 12-18-2008 |
| 20080266800 | HEAT SINK WITH SURFACE-FORMED VAPOR CHAMBER BASE - A heat sink comprises a vapor chamber base formed in a three-dimensional arrangement that mirrors topology of underlying structures on a substrate upon which the heat sink can be mounted, and at least one fin coupled to the vapor chamber base. | 10-30-2008 |
| 20090310308 | Integrated Replaceable Energy Storage and Coolant Module - There is disclosed a self-contained electronic apparatus containing at least some power-dissipating components which may require cooling. The self-contained electronic apparatus may also include a removable and replaceable energy storage module. The removable and replaceable energy storage module may include a power element to provide electrical energy for the self-contained electronic apparatus and a cooling element to cool at least a portion of the power dissipating components. | 12-17-2009 |
| 20080266803 | Phase change cooled electrical bus structure - A technique for cooling electrical bus structures is disclosed, in which a phase change heat spreader is thermally coupled to the bus. A continuous phase change cycle occurs within the heat spreader to draw heat from the bus during operation. The heat spreader may be planar, and extend over an area greater then the surface area of the bus to enhance cooling and to render the overall assembly more isothermal. The heat spreader may be placed near bus joints and circuits to remove heat caused by increased resistance at such locations. | 10-30-2008 |
| 20080266801 | Phase change cooled power electronic module - A power electronic module is cooled by a phase change heat spreader or cooling device. The module may include switched or unswitched devices, such as power transistors, diodes, and so forth, forming circuits such as rectifiers, inverters, converters, or the like, or portions of such circuits. Heat is transferred to the heat spreader in which a continuous phase change cycle takes place to cool the circuit components. The heat spreader may extend over an area sufficient to reduce the temperature of the components, and ultimately will render portions of the overall structure more isothermal. | 10-30-2008 |
| 20090161316 | HEAT DISSIPATION DEVICE WITH FAN HOLDER - A heat dissipation device includes a heat sink assembly, a fan holder and a fan mounted in the fan holder. The heat sink assembly includes a heat spreader for contacting with a heat-generating electronic component, and two fin assemblies thermally connecting with the heat spreader and sandwiching the fan therebetween. Each fin assembly defines cutouts at opposite ends thereof. The fan holder includes a top plate and a pair of vertical, downward-extending baffle walls. A pair of clamping arms extends from each baffle wall and inserted into the cutouts of the fin assemblies. Screws extend through the top plate to engage in holes defined in the fin assemblies and communicating with the cutouts. A vaulted operating plate is formed by the top plate for a user to grip to conveniently transport the heat dissipation device. | 06-25-2009 |
| 20090129022 | Micro-chimney and thermosiphon die-level cooling - A method and arrangement for dissipating heat from a localized area within a semiconductor die is presented. A semiconductor die is constructed and arranged to have at least one conduit portion therein. At least a portion of the conduit portion is proximate to the localized area. The conduit portion is at least partially filled with a heat-dissipating material. The conduit portion absorbs heat from the localized area and dissipates at least a portion of the heat away from the localized area. As such, thermal stress on the die is reduced, and total heat from the die is more readily dissipated. | 05-21-2009 |
| 20080316707 | HEAT DISSIPATION DEVICE WITH HEAT PIPES - A heat dissipation device includes a base ( | 12-25-2008 |
| 20120069522 | THERMAL MODULE AND ELECTRONIC DEVICE INCORPORATING THE SAME - An electronic device includes a circuit board and a thermal module mounted thereon. The circuit board has a heat-generating chip and an electromagnetic interference (EMI) source mounted thereon. The thermal module includes a shielding cover and a heat conducting member. The shielding cover is heat-conductive and electrically-conductive material, and defines a cavity therein. The shielding cover encloses the EMI source in the cavity for EMI shielding. The heat conducting member has one end thermally connecting with the shielding cover and another end thermally connecting with the heat-generating chip for transferring heat from the heat-generating chip to the shielding cover. | 03-22-2012 |
| 20100149755 | Loop Heat Pipe and Electronic Device - According to one embodiment, a loop heat pipe including a fluid circulating channel containing fluid, includes: an evaporating portion configured to vaporize the fluid by heat from a heat generating component; a condensing portion configured to liquefy the vaporized fluid; a first fluid channel connecting the evaporating portion and the condensing portion, the vaporized fluid flowing through the first fluid channel; a second fluid channel connecting the evaporating portion and the condensing portion, the fluid liquefied by the condensing portion flowing through the second fluid channel; a liquid accumulating portion formed on an inner wall of the second fluid channel, and provided between the evaporating portion and the condensing portion, the liquid accumulating portion being configured to accumulate the liquid liquefied by the condensing portion; and a wick provided between the evaporating portion and a position where the liquid accumulating portion is formed. | 06-17-2010 |
| 20110141692 | CONDUCTION COOLED CIRCUIT BOARD ASSEMBLY - A conduction cooled circuit board assembly may include a frame and at least one circuit board attached to the frame, having at least one area to be cooled. The assembly may also include at least one rail attached to the frame, and at least one heat pipe having a first end and a second end, the first end disposed near the area and the second end in contact with the rail so as to transfer heat from the area to the rail. | 06-16-2011 |
| 20090213545 | CONTROL DEVICE, IN PARTICULAR IN THE FORM OF AN ELECTRIC SWITCH FOR ELECTRIC HANDTOOLS - A control device, in particular an electrical switch for use for an electrical tool such as a rechargeable-battery and/or plug-powered electrical tool having an electric motor. The switch has a housing for holding at least one heat-generating component such as a power transistor, a MOSFET, a triac or the like, which is arranged in particular in an electrical circuit arrangement which, for example, is used for open-loop and/or closed-loop control of the electric motor by appropriate open-loop and/or closed-loop control of the electrical load current flowing through the component to the electric motor. A means for thermal conduction is connected on the one hand to the housing of the electrical switch, and/or to the heat-generating component, in particular to the power semiconductor which is located in the housing, and on the other hand to a cooled area which is associated with the switch. | 08-27-2009 |
| 20090219695 | Electronic Device, Loop Heat Pipe and Cooling Device - According to one embodiment, an electronic device includes a heat generating part housed inside a cabinet and a loop heat pipe housed inside the cabinet, which includes an internal flow path having a loop shape in which a working fluid is sealed. The loop heat pipe further includes a heat receiving unit, a heat radiating unit, a vapor flow path which allows a gasified portion of the working fluid to flow from the heat receiving unit towards the heat radiating unit, a liquid returning flow path which allows a liquefied portion of the working fluid to flow from the heat radiating unit towards the heat receiving unit, and a wick provided at a position adjacent to the vapor flow path inside the liquid returning flow path. The wick also serves as a partition portion which partitions the vapor flow path and the liquid returning flow path from each other. | 09-03-2009 |
| 20090244846 | Electronic Device, Cooling Device and Loop Heat Pipe - According to one embodiment, an electronic device includes a housing, a heat generating part contained in the housing, and a loop heat pipe contained in the housing. The loop heat pipe includes a heat receiving portion, a heat radiating portion, a vapor flow path and a liquid return flow path. The heat receiving portion includes a first region connected to the liquid return flow path and provided with a wick, and a second region formed to be hollow, connected to the vapor flow path. The heat receiving portion is thermally connected to the heat generating part at a position across the first region and the second region. | 10-01-2009 |
| 20090257193 | Heat dissipating device - A heat dissipating device is designed with calm, efficient, and space economy performance includes a housing ( | 10-15-2009 |
| 20100157533 | HEAT-TRANSPORTING DEVICE, ELECTRONIC APPARATUS, AND METHOD OF PRODUCING A HEAT-TRANSPORTING DEVICE - A heat-transporting device includes a working fluid, a vessel, a vapor-phase flow path, and a liquid-phase flow path. The working fluid transports heat using a phase change. The vessel seals in the working fluid. The vapor-phase flow path causes the working fluid in a vapor phase to circulate inside the vessel. The liquid-phase flow path includes a laminated body and causes the working fluid in a liquid phase to circulate inside the vessel, the laminated body including a first mesh member and a second mesh member and being formed such that the first mesh member and the second mesh member are laminated while weaving directions thereof differ relatively. | 06-24-2010 |
| 20100157534 | HEAT-TRANSPORTING DEVICE AND ELECTRONIC APPARATUS - A heat-transporting device includes a working fluid, a vessel, a vapor-phase flow path, and a liquid-phase flow path. The working fluid transports heat using a phase change. The vessel seals in the working fluid. The vapor-phase flow path includes a first mesh member and causes the working fluid in a vapor phase to circulate inside the vessel, the first mesh member including a through-hole larger than a mesh thereof. The liquid-phase flow path causes the working fluid in a liquid phase to circulate inside the vessel. | 06-24-2010 |
| 20100157535 | HEAT-TRANSPORTING DEVICE AND ELECTRONIC APPARATUS - A heat-transporting device includes a working fluid, a vessel, a vapor-phase flow path, a liquid-phase flow path, and an intermediate layer. The working fluid transports heat using a phase change. The vessel seals in the working fluid. The vapor-phase flow path causes the working fluid in a vapor phase to circulate inside the vessel. The liquid-phase flow path includes a first mesh member having a first mesh number and causes the working fluid in a liquid phase to circulate inside the vessel. The intermediate layer includes a second mesh member and is interposed between the liquid-phase flow path and the vapor-phase flow path, the second mesh member being laminated on the first mesh member and having a second mesh number smaller than the first mesh number. | 06-24-2010 |
| 20100002395 | ELECTRONIC HOUSING WITH ELECTRONIC BOARDS COMPRISING HEAT PIPES - The field of the invention is that of the discharge of heat from electronic cards in operation and more specifically from electronic devices comprising at least one heat pipe. The electronic package according to the invention comprises at least a mechanical structure comprising at least one housing, an electronic card, and means for mechanically attaching the electronic card in the housing of the structure, the electronic card comprising at least one electronic component and a device of high thermal conductivity joined to the electronic card and comprising two ends, the first end being in thermal contact with the electronic component and the second end of the device of high thermal conductivity being mechanically arranged so as to ensure good thermal contact with the walls of the housing of the structure. | 01-07-2010 |
| 20100259897 | HEAT DISSIPATION DEVICE - A heat dissipation device dissipates heat generated by a heat-generating electronic element mounted on a top surface printed circuit board. The printed circuit board defines a plurality of first through holes. The heat dissipation device comprises a heat spreader located at a top side of the printed circuit board. The heat spreader defines a plurality of second through holes corresponding to the first through holes, respectively. A first heat sink is located over the heat spreader, and a plurality of second heat sinks is located at a bottom side of the printed circuit board. A plurality of heat pipes extending through the second through holes of the heat spreader and the first through holes of the printed circuit board to thermally connect the first and second heat sinks to the heat spreader. | 10-14-2010 |
| 20100188818 | HEAT DISSIPATING DEVICE AND METHOD OF MANUFACTURING THE SAME - A heat dissipating device includes a flat evaporator, a vapor pipe, a liquid pipe, and a condenser. The flat evaporator consists of a bottom plate, a porous material, and a top lid. The porous material is located on the bottom plate and provided with vapor flow passages. The vapor pipe and liquid pipe are communicably connected at respective one end to a vapor port and a liquid port on the evaporator, and at the other end to two sides of the condenser. The evaporator has simple structure and low manufacturing cost, and can fully effectively bear on an electronic chip to enable reduced room needed for installing the evaporator and reduced thermal resistance during heat dissipation. The heat dissipating device can be used to dissipate heat produced by computer chips, and to cool LED illuminating devices, chips for communication devices, high-power heat-producing elements in military, medical, aerial, and aerospace apparatuses. | 07-29-2010 |
| 20100254088 | HEAT TRANSPORT DEVICE, ELECTRONIC APPARATUS, AND HEAT TRANSPORT DEVICE MANUFACTURING METHOD - According to an embodiment of the present invention, there is provided a heat transport device including a working fluid, an evaporation portion, a condenser portion, a flow path portion, and an area. The working fluid includes pure water and an organic compound bearing a hydroxyl group. The evaporation portion causes the working fluid to evaporate from a liquid phase to a vapor phase. The condenser portion communicates with the evaporation portion, and causes the working fluid to condense from the vapor phase to the liquid phase. The flow path portion causes the working fluid condensed in the condenser portion to the liquid phase to flow to the evaporation portion. The area is made of a carbon material and provided on at least one of the evaporation portion, the condenser portion, and the flow path portion. | 10-07-2010 |
| 20110103018 | INTEGRATED ANTENNA STRUCTURE WITH AN EMBEDDED COOLING CHANNEL - According to one embodiment of the disclosure, an integrated antenna structure comprises a plurality of radiating elements, cooling channels embedded directly within each of the plurality of radiating elements, a fluid inlet, and a fluid outlet. Each of the plurality of radiating elements receive or transmit electromagnetic energy. The cooling channels are formed by an internal surface of the radiating elements. The fluid inlet and the fluid outlet are in communication with each of the cooling channels. Each of the cooling channels provides a heat exchanging function by receiving at least a portion of a fluid coolant from the fluid inlet, transferring a least a portion of the thermal energy from the respective radiating element to the received portion of the fluid coolant, and dispensing of at least a portion of the received fluid coolant out of the cooling channel to the fluid outlet. | 05-05-2011 |
| 20090040725 | HEAT DISSIPATION DEVICE - A heat dissipation device includes a first heat dissipation unit attached to a top surface of the electronic component of an add-on card and defining a channel therein, a heat pipe, and a second heat dissipation unit. The second heat dissipation unit includes a first portion located at a lateral side of the add-on card, a second portion extending from the first portion to a bottom side of the add-on card, and a joint portion formed between the first portion and the second portion and located at the lateral side of the add-on card. The heat pipe includes an evaporating portion received in the channel of the first heat dissipation unit, and a condensing portion extended through the second heat dissipation unit at the joint portion. | 02-12-2009 |
| 20090073657 | Electronic package whereby an electronic assembly is packaged within an enclosure that is designed to act as a heat pipe - An electronic component or assembly that is assembled within a case that is designed to operate as a liquid phase to gas phase heat pipe where the electronic component or assembly is introduced into a liquid or partially liquid partially gaseous environment; whereby said liquid evaporates into a gas absorbing heat energy and transferring it to and through the component's or assembly's case. The case will be engineered out of materials that do not contaminate the liquid and electronics with ions and will be engineered to include a plurality of chambers/towers that extend in various directions providing enhanced heat pipe functionality in any physical orientation. | 03-19-2009 |
| 20090323285 | HEAT TRANSPORT DEVICE AND ELECTRONIC APPARATUS - A heat transport device includes an airtight container, a working fluid contained in the airtight container, and a plurality of plate-like members including a first plate-like member and a second plate-like member adjacent to the first plate-like member, the plate-like members each having a first hole having a first opening area and a second hole having a second opening area smaller than the first opening area, the plate-like members being layered in the airtight container so that the first hole of the first plate-like member and the first hole of the second plate-like member are communicated with each other, to retain the working fluid in a liquid phase by applying a capillary force to the working fluid, and so that an opening of the second hole is located within an opening of the first hole, to transfer the working fluid vaporized into a gas phase in the layered direction. | 12-31-2009 |
| 20080291629 | Liquid-cooled portable computer - Embodiments of a computer system are described. This computer system includes a power source that is coupled to a heat pipe, where the power source includes an integrated circuit. This heat pipe may contain a liquid coolant that has a density greater than a first pre-determined value at room temperature. A pump is coupled to the heat pipe is configured to circulate the liquid coolant through the heat pipe. Furthermore, a heat exchanger coupled to the heat pipe is configured to transfer heat from the heat pipe to an environment external to the computer system. | 11-27-2008 |
| 20100296249 | MICRO PASSAGE COLD PLATE DEVICE FOR A LIQUID COOLING RADIATOR - A micro passage cold plate device for a liquid cooling radiator includes a upper cover and a lower plate. The upper cover has a working medium inlet at a side thereof and a working medium outlet at another side thereof. The inlet and outlet are trumpet-shaped such that the working medium expansively enters the cold plate gradually and leaves the cold plate with a reduced way gradually. Hence, the cold plate provides an even distribution of temperature, a lower thermal resistance and a better heat dissipation performance such that the stability of the two-state flow of the working medium is enhanced for heat dissipation device in the field of electronic field. | 11-25-2010 |
| 20110122584 | ELECTRONIC APPARATUS - According to one embodiment, an electronic apparatus includes a housing, a first heating element in the housing, a heat sink in the housing, a first pressing member, a first heat pipe, and a second heat pipe. The first heat pipe has a plate shape, includes a first portion facing the first heating element and a second portion being outside the first heating element. The first heat pipe is configured to be bent by the first pressing member. The second heat pipe is connected to the second portion of the first heat pipe and the heat sink. | 05-26-2011 |
| 20100315781 | ANTI-GRAVITY THERMOSYPHON HEAT EXCHANGER AND A POWER MODULE - A thermosyphon heat exchanger according to the disclosure includes a set of linear conduit elements and a heat exchange plate mounted in a heat receiving region on the conduit elements. The longitudinal axes of the conduit elements extend in a first direction in a plane defined by the flat side of the heat exchange plate. The conduit elements project above the heat receiving region in the first direction on a first side and an opposing second side such that the extension of the conduit elements on each side of the heat exchange region is suitable for constituting a condensing region for condensing a refrigerant vaporized in the heat receiving region if the first direction is arranged vertically. | 12-16-2010 |
| 20110110042 | ELECTRONIC DEVICE ASSEMBLY WITH HEAT DISSIPATION DEVICE - An exemplary electronic device assembly includes a printed circuit board with an electronic component thereon, and a heat dissipation device. The heat dissipation device includes a heat sink mounted on the printed circuit board and a heat pipe pivotably engaged with the heat sink. The heat sink includes a main body defining a transverse channel therethrough and an injection aperture at a top of the main body to communicate the channel and an exterior of the main body. The heat pipe is pivotably engaging in the channel of the main body. A gap is defined between the heat pipe and the heat sink. Heat conductive grease is injected into the channel and filled in the gap between the heat pipe and the heat sink to thermally connect the heat sink with the heat pipe. | 05-12-2011 |
| 20090086434 | Recirculating Gas Rack Cooling Architecture - Cabinet for housing and cooling electronic components with internally circulating air that is cooled at each of a plurality of equipment shelves. | 04-02-2009 |
| 20090016022 | SEMICONDUCTOR MODULE - A semiconductor module includes a base plate, a circuit substrate coupled to a side face of the base plate, a first semiconductor package mounted on the circuit substrate and a radiation channel portion inside the base plate. The radiation channel portion includes at least one heat pipe containing a working fluid. The at least one heat pipe containing the working fluid is configured to transfer heat generated by the first semiconductor package. Thus, the radiation channel portion may provide an efficient and reliable semiconductor module having improved heat transfer and radiation performance. | 01-15-2009 |
| 20090034195 | HEAT-DISSIPATING MODULE - A heat-dissipating module dissipating heat generated by a heat-generating element includes a plurality of fins, a fan generating an air current and a heat pipe. Each fin has a first edge facing the fan and a second edge facing the fan. The first edges are located on a first surface. The second edges are located on a second surface not coinciding with the first surface. The air current passing through the first and second surfaces passes by the fins. A first end of the heat pipe is thermally coupled to the heat-generating element. A second end of the heat pipe is thermally coupled to the fins. | 02-05-2009 |
| 20110249403 | ELECTRONIC APPARATUS - According to one embodiment, an electronic apparatus includes a housing, a circuit board in the housing, a first back plate on the circuit board, a second back plate on the circuit board, and a connecting portion connecting the first back plate with the second back plate. | 10-13-2011 |
| 20100128436 | METHOD AND APPARATUS FOR COOLING ELECTRONICS - Embodiments of the present disclosure provide for methods and devices for improving the heat dissipating properties of a heatsink to provide increased cooling for electronic equipment, such as power converters. In one embodiment, a heatsink includes at least one fluid cooled portion and at least one heat pipe disposed adjacent to the fluid cooled portion. The heat pipe improves the conduction of heat away from heat sources. | 05-27-2010 |
| 20110075370 | PRESSING MEMBER, PRESSING STRUCTURE FOR HEAT RECEIVING BLOCK OF SUBSTRATE, AND ELECTRONIC DEVICE - According to one embodiment, a pressing member includes: a band-like pressing portion placed on a heat receiving block arranged on an element mounted on a substrate, the pressing portion configured to press the heat receiving block against the element; a first arm, one end of the first arm being connected to one longitudinal end of the pressing portion, other end of the first arm being connected to the substrate; and a second arm, one end of the second arm being connected to other longitudinal end of the pressing portion, other end of the second arm being connected to the substrate, wherein the first arm and the second arm are connected to the pressing portion in a bent shape as seen in a planar view from above a surface of the substrate. | 03-31-2011 |
| 20100238630 | HEAT DISSIPATION DEVICE - A heat dissipation device includes a heat sink and a pair of heat pipes fixed to the heat sink. The heat sink includes a rectangular post, four branches extending outwardly from four corners of the post, respectively, and a plurality of fins extending between the branches. Each heat pipe includes an evaporating section attached to a bottom of the post, a condensing section parallel to the evaporation section and attached to a top of the post, and an adiabatic section interconnecting the evaporating section and the condensing section. A block is secured to bottoms of the condensing sections of the heat pipes. | 09-23-2010 |
| 20110075369 | ELECTRONIC DEVICE - An electronic device including a heat generation element, a heat dissipation plate, and a heat pipe is provided. The heat dissipation plate includes a top surface, a bottom surface, a pair of longitudinal side surfaces, and a pair of lateral side surfaces including a third side surface and a fourth side surface. The longitudinal side surfaces include first and second side surfaces. The lateral side surfaces include third and fourth side surfaces. The first, second, third and fourth side surfaces are connected to both the top surface and the bottom surface. The heat pipe is disposed in contact with the heat dissipation plate, and the heat pipe and the heat generation element are disposed on the bottom surface of the heat dissipation plate. The heat pipe is disposed on the heat dissipation plate and extension of the heat pipe is not beyond the first, second, third and fourth side surfaces. | 03-31-2011 |
| 20110075371 | ELECTRONIC DEVICE - According to one embodiment, an electronic device includes a housing, a circuit board, a thermally radiative section, a first heat generator, a second heat generator, a first heat receiving block, a second heat receiving block, at least one heat pipe including a first end and a second end, a second heat pipe including a third end, a fourth end, and an intermediate portion, and a cutout section provided on the first heat receiving block. The second heat generator is mounted on the circuit board at a position farther from the thermally radiative section than the first heat generator is. The first heat receiving block is provided with a cutout section and is thermally connected to the first heat generator. The second heat receiving block is thermally connected to the second heat generator. The intermediate portion of the second heat pipe passes through the cutout section. | 03-31-2011 |
| 20110069454 | LIQUID-COOLED ELECTRONICS APPARATUS AND METHODS OF FABRICATION - Liquid-cooled electronics apparatuses and methods are provided. The cooled electronics apparatuses include a liquid-cooled cold rail and an electronics subassembly. The liquid-cooled cold rail has a thermally conductive structure and a coolant-carrying channel extending within and cooling the thermally conductive structure. The electronics subassembly includes an electronics card(s) and one or more thermal transfer plates. The electronics card(s) includes electronic devices to be cooled, and the one or more thermal transfer plates are each rigidly affixed to one or more electronic devices of the electronics card(s). Each thermal transfer plate is thermally conductive and couples the electronics subassembly to the liquid-cooled cold rail to thermally interface the one or more electronic devices to the liquid-cooled cold rail to facilitate cooling of the electronic devices. In one embodiment, the electronics subassembly includes multiple interleaved electronics cards and thermal transfer plates. | 03-24-2011 |
| 20100296251 | HEAT DISSIPATION DEVICE - A heat dissipation device is provided for dissipating heat generated by a plurality of electronic components mounted on a printed circuit board and having different heights. The heat dissipation device includes a connecting member and a first base mounted on the connecting member and located at above one of the electronic components. A number of joining members extend through the printed circuit board and engage with the first base to assemble the first base on the one of the electronic components on the printed circuit board. A distance between the first base and the one of the electronic components is adjustable by adjusting the joining members to make the first base intimately contact with the one of the electronic components. | 11-25-2010 |
| 20080205003 | Redundant Cooling Systems And Methods - Redundant cooling systems and methods are disclosed. In an exemplary embodiment, a method for redundant cooling system of computer systems and other electronics may comprise thermally connecting a cooling fluid to one or more heat-generating components to absorb heat from the heat-generating components during operation. The method may also comprise thermally connecting the cooling fluid to a primary coolant and a secondary coolant. The method may also comprise exchanging heat between the cooling fluid and the primary coolant or the secondary coolant to remove heat from the cooling fluid even if one of the cooling sources is unavailable. | 08-28-2008 |
| 20100296250 | HEAT DISSIPATION DEVICE FOR COMMUNICATION CHASSIS - A heat dissipation device for communication chassis, which includes an enclosure and at least one second heat pipe assembly. The enclosure includes at least one first copper heat absorption component, at least one first heat pipe assembly and multiple radiating fins disposed on an outer surface of the enclosure. The first heat pipe assembly is connected with the first copper heat absorption component and a section not in contact therewith so as to transfer heat absorbed by the first copper heat absorption component to the section to dissipate the heat. The second heat pipe assembly penetrates through the radiating fins of the enclosure for quickly and uniformly distributing the heat to all the radiating fins. Therefore, the heat conduction efficiency is greatly enhanced to provide better heat dissipation effect for the communication chassis. | 11-25-2010 |
| 20110096502 | PRINTED CIRCUIT BOARD ASSEMBLY - A printed circuit board assembly includes a heat sink, a back board, and a securing member. The heat sink is configured to be mounted on a heat generating element of a printed circuit board. The heat sink is configured to dissipate heat generated by the heat generating element. The heat sink and the back board are configured to be placed on opposite sides of the printed circuit board. The heat sink includes a first connecting heat pipe. The back board includes a second connecting heat pipe. The second connecting heat pipe contacts the first connecting heat pipe. The securing member thermally contacts the first connecting heat pipe and the second connecting heat pipe. | 04-28-2011 |
| 20110216505 | Aircraft Electronics Cooling Apparatus For An Aircraft Having A Liquid Cooling System - The invention relates to an improved aircraft electronics cooling system for an aircraft having a liquid cooling system ( | 09-08-2011 |
| 20120307452 | PORTABLE ELECTRONIC DEVICE WITH HEAT PIPE - An exemplary portable electronic device includes a printed circuit board, a heat generating electronic component mounted on the printed circuit board, a shell housing the printed circuit board, the heat generating electronic component and a heat pipe therein. The heat pipe includes an evaporating side and a condensing side. The evaporating side thermally contacts the heat generating electronic component, and the condensing side thermally contacts the shell. | 12-06-2012 |
| 20100302734 | HEATSINK AND METHOD OF FABRICATING SAME - A heatsink assembly for cooling a heated device includes a ceramic substrate having a plurality of cooling fluid channels integrated therein. The ceramic substrate includes a topside surface and a bottomside surface. A layer of electrically conducting material is bonded or brazed to only one of the topside and bottomside surfaces of the ceramic substrate. The electrically conducting material and the ceramic substrate have substantially identical coefficients of thermal expansion. | 12-02-2010 |
| 20110317367 | LIQUID-COOLED ELECTRONICS RACK WITH IMMERSION-COOLED ELECTRONIC SUBSYSTEMS - Liquid-cooled electronics racks are provided which include: immersion-cooled electronic subsystems; a vapor-condensing heat exchanger to condense dielectric fluid vapor egressing from the immersion-cooled electronic subsystems; a dielectric fluid vapor return coupling in fluid communication the vapor outlets of the immersion-cooled electronic subsystems and the vapor-condensing heat exchanger; a reservoir for holding dielectric fluid; a gravity drain line coupled to drain dielectric fluid condensate from the vapor-condensing heat exchanger to the reservoir; an immersed, sub-cooling heat exchanger disposed within the reservoir; a dielectric fluid supply manifold coupling in fluid communication the reservoir and the dielectric fluid inlets of the immersion-cooled electronic subsystems; and a pump for supplying under pressure dielectric fluid from the reservoir to the dielectric fluid supply manifold for maintaining dielectric fluid in a liquid state within the immersion-cooled electronic subsystems. | 12-29-2011 |
| 20090201645 | COOLING SYSTEM FOR ELECTRONIC EQUIPMENT - In a cooling system for an electronic device of the present invention, server rooms in which a plurality of servers are placed, an evaporator which is provided close to each of the servers, and cools exhaust air from the server by vaporizing a refrigerant with heat generating from the server, a cooling tower which is provided at a place higher than the evaporator, cools the refrigerant by outside air and water sprinkling, and condenses the vaporized refrigerant, and a circulation line in which the refrigerant naturally circulates between the evaporator and the cooling tower. According to the cooling system, an electronic device which is required to perform a precise operation with a heat generation amount from itself being large, such as a computer and a server, can be efficiently cooled at low running cost. | 08-13-2009 |
| 20120206880 | THERMAL SPREADER WITH PHASE CHANGE THERMAL CAPACITOR FOR ELECTRICAL COOLING - A cooling assembly comprises an electronic component, a thermal spreader, a cold plate, and a phase change thermal capacitor. The thermal spreader conducts heat freely between the electronic component, the phase change thermal capacitor, and the cold plate. The cold plate dissipates heat. The phase change thermal capacitor stores undissipated heat in a phase transition of a phase change material. | 08-16-2012 |
| 20120026691 | APPARATUS AND METHOD FOR FACILITATING DISSIPATION OF HEAT FROM A LIQUID-COOLED ELECTRONICS RACK - Apparatus and method are provided for facilitating cooling of one or more components of an electronics rack. The apparatus includes a liquid-cooled structure associated with the electronic component(s) to be cooled, and a liquid-to-air heat exchanger coupled in fluid communication with the liquid-cooled structure via a coolant loop to receive coolant from and supply coolant to the liquid-cooled structure. The heat exchanger is disposed external to the electronics rack within a cool air plenum of the data center containing the rack, and the plenum is coupled to a cool air source providing cooled air to the data center. Cooled air of the cool air plenum passes across the heat exchanger and cools coolant passing through the heat exchanger, which dissipates heat from the coolant passing therethrough to the cool air passing across the heat exchanger to facilitate liquid cooling of the electronic component(s) associated with the liquid-cooled structure. | 02-02-2012 |
| 20120106084 | Heat Pipe, Method For Manufacturing A Heat Pipe, And A Circuit Board With A Heat Pipe Function - A heat pipe for cooling an exothermic body by the vaporization and condensation of an enclosed cooling medium is disclosed. The heat pipe comprises a flat plate-like upper plate, a flat plate-like lower plate opposed to the upper plate, and a plurality of flat plate-like intermediate plates overlaid on each other between the upper plate and the lower plate and having internal through-holes. The internal through-holes formed in each of a plurality of the intermediate plates are adapted such that only part of each through-hole is overlapped on each other to form capillary tube paths, each having a cross-sectional area smaller than the cross-sectional area of the through-hole in the flat surface direction. | 05-03-2012 |
| 20120063092 | HEAT-DISSIPATING DEVICE AND ELECTRIC APPARATUS HAVING THE SAME - A heat-dissipating device and an electronic apparatus having the same are disclosed. The heat-dissipating device includes a heat-transferring heat pipe unit having a wick type of a heat pipe, in which a wick is formed on an inner surface of the heat pipe and a working fluid is injected into the heat pipe, and a heat-dissipating heat pipe unit having an oscillating capillary type of a loop heat pipe, in which the loop heat pipe is formed as a capillary and a working fluid is injected into the loop heat pipe. Here, the heat pipe includes a radiator being disposed adjacent to a heat source and transporting heat transferred from the heat source to the loop heat pipe, and the loop heat pipe includes a heat-receiving portion, which is thermally coupled to the radiator, and a heat-dissipating portion, which releases heat absorbed from the heat-receiving portion. | 03-15-2012 |
| 20090161315 | HEAT DISSIPATING APPARATUS WITH HEAT PIPE - A heat dissipating apparatus includes a heat spreader ( | 06-25-2009 |
| 20110069453 | APPARATUS AND METHOD WITH FORCED COOLANT VAPOR MOVEMENT FOR FACILITATING TWO-PHASE COOLING OF AN ELECTRONIC DEVICE - Apparatus and method are provided for two-phase dielectric cooling of an electronic device. The apparatus includes a coolant flow path, a vapor condenser and one or more vapor fans. The coolant flow path is in fluid communication with the electronic device, where liquid dielectric coolant within the flow path vaporizes upon contacting the electronic device, forming dielectric coolant vapor, and thereby facilitating cooling of the electronic device. The vapor condenser is also in fluid communication with the coolant flow path and facilitates condensate formation from the dielectric coolant vapor. The one or more vapor fans are disposed within the flow path to actively move dielectric coolant vapor into contact with the vapor condenser, and thereby enhance cooling of the electronic device by facilitating coolant condensate formation and thus recirculation of the coolant condensate as liquid dielectric coolant. | 03-24-2011 |
| 20110075372 | EVAPORATORS FOR USE IN HEAT TRANSFER SYSTEMS, APPARATUS INCLUDING SUCH EVAPORATORS AND RELATED METHODS - An evaporator includes a liquid barrier wall made of a ceramic material, a vapor barrier wall made of a ceramic material, and a wick made of a ceramic material and being positioned between the liquid barrier wall and the vapor barrier wall. | 03-31-2011 |
| 20110080711 | POWER-ELECTRONIC ARRANGEMENT - A power-electronic arrangement comprising semiconductor components ( | 04-07-2011 |
| 20100290189 | HEAT DISSIPATION STRUCTURE FOR COMMUNICATION CHASSIS - A heat dissipation structure for communication chassis. The heat dissipation structure includes an enclosure. At least one first copper heat absorption component and at least one first heat pipe assembly are disposed in the enclosure. The first heat pipe assembly is connected with the first copper heat absorption component and a section not in contact with the first copper heat absorption component. The first heat pipe assembly serves to quickly transfer heat absorbed by the first copper heat absorption component to the section not in contact with the first copper heat absorption component to dissipate the heat. | 11-18-2010 |
| 20100246128 | Circuit Pack Cooling Solution - An improved apparatus and system are provided for heat dissipation in a bank of circuit components using heat pipes and/or vapor chambers, wherein the heat pipes and/or vapor chambers efficiently transport heat away from high heat components. | 09-30-2010 |
| 20100246129 | Electronic Apparatus - An electronic apparatus including: a body; a circuit board housed in the body; a heating body mounted on the circuit board; a heat pipe having: an end portion, a heat emitting portion located on an opposite side to the end portion, and a heat receiving portion located between the end portion and the heat emitting portion and thermally connected to the heating body; a bonding member disposed between the heating body and the heat receiving portion and that bonds the heating body and the heat receiving portion; and an extension that extends toward the circuit board. | 09-30-2010 |
| 20100208428 | COMMUNICATION CHASSIS HEAT DISSIPATION STRUCTURE - A communication chassis heat dissipation structure includes a chassis body defining an inner receiving space. The chassis body is divided into at least one heat concentration portion and at least one heat dissipation portion. A first heat pipe set is arranged in the receiving space to extend between and connect to the heat concentration portion and the heat dissipation portion, so that heat absorbed by the heat concentration portion is quickly transferred via the first heat pipe set to the heat dissipation portion and then dissipates from the heat dissipation portion into ambient air. Therefore, heat inside the chassis body can be quickly dissipated outward, enabling a communication chassis to have excellent heat dissipation effect. | 08-19-2010 |
| 20110182033 | DEVICE FOR COOLING AN ELECTRONIC CARD BY CONDUCTION COMPRISING HEAT PIPES, AND CORRESPONDING METHOD OF FABRICATION - In a device for cooling an electronic circuit board comprising at least one component covered with an exchanger cover, the device includes a heat sink covering all or some of the electronic circuit board, and at least one heat pipe per component, each heat pipe being capable of carrying away the heat from the component with which it is associated to at least one end of the electronic circuit board via a zone of the heat pipe called the condensing zone. The device further includes at least one heat-exchange part located on the end of the electronic circuit board and mounted freely on the heat sink, each heat pipe being attached to the heat-exchange part by means of its condensing zone. | 07-28-2011 |
| 20090059527 | Heat dissipating device - A heat dissipating device includes a sealed container having hollow floors and floor-spacing assemblies. Each floor-spacing assembly includes hollow spacing walls. Each hollow spacing wall extends from a respective hollow floor and is spaced apart from an adjacent one of the hollow spacing walls of an adjacent one of the floor-spacing assemblies by an air gap. Each two adjacent ones of the hollow floors are interconnected through the hollow spacing walls disposed therebetween. The sealed container defines a liquid reservoir, a condensate reservoir, and a plurality of fluid passages extending through the hollow spacing walls and the hollow floors that are disposed between the liquid reservoir and the condensate reservoir. | 03-05-2009 |
| 20090059526 | HEAT SINK ASSEMBLY AND METHOD MANUFACTURING THE SAME - A heat sink assembly includes a base plate, a fin group and a heat pipe thermally connecting the base plate with the fin group. The fin group includes a plurality of fins. The heat pipe includes a straight evaporating section contacting with the base plate, a first condensing section extending upwardly from an end of the evaporating section and through the fins, a second condensing section bent downwardly from a free end of the first condensing section and through the fins, and a third condensing section extending upwardly from an opposite end of the evaporating section and through the fins. Periphery walls of at least two of the first, second and third condensing sections substantially totally contact with the fins to increase a contact area between the heat pipe and the fins. | 03-05-2009 |
| 20090097205 | ELECTRONIC EQUIPMENT SYSTEM - In a space of a data center or the like where many disk array apparatuses and electronic equipment systems are arranged, it is an object of the present invention to reduce the energy required for cooling the apparatus itself and cooling the space. In electronic equipment having heat generating elements such as a disk array apparatus or CPU, low-temperature waste heat exhausted from the equipment is heated through a vapor compression cycle once and then recovered as cold water through an absorption refrigeration cycle. In the space of a data center or the like where many disk array apparatuses and electronic equipment systems are arranged, this can reduce the energy required for cooling the apparatus itself and cooling the space, drastically improve the processing speed and reliability of the apparatus/system and realize capacity and speed enhancements. | 04-16-2009 |
| 20120075805 | HEAT DISSIPATION DEVICE - An exemplary heat dissipation device for a portable electronic device includes a heat pipe and a heat dissipating member. The heat pipe includes an evaporator section and a condenser section. The evaporator section is attached to a heat source of the portable electronic device. The heat dissipating member includes a sheath, and a porous heat dissipating layer and a working fluid contained in the sheath. The porous heat dissipating layer defines gaps therein. The working fluid is filled in the gaps. The condenser section of the heat pipe is received in the porous heat dissipating layer and thermally contacts the porous heat dissipating layer. | 03-29-2012 |
| 20100008043 | HEAT-TRANSPORTING DEVICE, ELECTRONIC APPARATUS, SEALING APPARATUS, SEALING METHOD, AND METHOD OF PRODUCING A HEAT-TRANSPORTING DEVICE - A heat-transporting device includes a casing, a working fluid, a first substrate, a second substrate, and a third substrate. The casing includes a first side and a second side opposed to the first side. The working fluid is sealed inside the casing and transports heat by a phase change. The first substrate includes an inlet through which the working fluid is injected and constitutes the first side of the casing. The second substrate is disposed opposite to the first substrate and constitutes the second side of the casing. The third substrate includes a contact portion that is brought into contact with the inlet so that the inlet is sealed when the inlet is pressed, the third substrate being interposed between the first substrate and the second substrate. | 01-14-2010 |
| 20100328891 | CONDENSER BLOCK STRUCTURES WITH CAVITIES FACILITATING VAPOR CONDENSATION COOLING OF COOLANT - Condenser structures and cooling apparatuses are provided which facilitate vapor condensation heat transfer of a coolant employed in cooling an electronic device. The condenser structure includes a thermally conductive condenser block with multiple exposed cavities therein extending from a first main surface towards a second main surface. The condenser block is a monolithic structure, and the first main surface is a coolant vapor condensate formation surface when the condenser structure is operationally facilitating cooling of an electronic device. The exposed cavities extend from the first main surface into the condenser block to increase a condensation surface area of the condenser block, thereby facilitating coolant vapor condensate formation on the condenser block, and thus cooling of the electronic device using a two-phase coolant. The condenser structure also includes coolant-carrying channels for facilitating cooling of the condenser block, and thus vapor condensate formation on the condenser block. | 12-30-2010 |
| 20100328890 | CONDENSER STRUCTURES WITH FIN CAVITIES FACILITATING VAPOR CONDENSATION COOLING OF COOLANT - Vapor condensers and cooling apparatuses are provided which facilitate vapor condensation cooling of a coolant employed in cooling an electronic device. The vapor condenser includes a thermally conductive base structure with a plurality of condenser fins extending from the base structure. The condenser fins have a proximal end coupled to the base structure and a remote end remote from the base structure. At least one exposed cavity is provided within each condenser fin extending from the remote end towards the proximal end. The exposed cavities are sized to provide greater condenser fin surface area for facilitating vapor condensate formation, and thereby facilitate cooling of an electronic device using a two-phase coolant. | 12-30-2010 |
| 20100328889 | COOLED ELECTRONIC MODULE WITH PUMP-ENHANCED, DIELECTRIC FLUID IMMERSION-COOLING - Cooled electronic modules and methods of fabrication are provided with pump-enhanced, dielectric fluid immersion-cooling of the electronic device. The cooled electronic module includes a substrate supporting an electronic device to be cooled. A cooling apparatus couples to the substrate, and includes a housing configured to at least partially surround and form a sealed compartment about the electronic device. Additionally, the cooling apparatus includes dielectric fluid and one or more pumps disposed within the sealed compartment. The dielectric fluid is in direct contact with the electronic device, and the pump is an impingement-cooling, immersed pump disposed to actively pump dielectric fluid within the sealed compartment towards the electronic device. Multiple condenser fins extend from the housing into the sealed compartment in an upper portion of the sealed compartment, and a liquid-cooled cold plate or an air-cooled heat sink is coupled to the top of the housing for cooling the condenser fins. | 12-30-2010 |
| 20110038122 | Phase Change Heat Spreader Bonded to Power Module by Energetic Multilayer Foil - Power electronic devices are solder to a phase change heat spreader using an energetic multilayer foil. This foil may be sandwiched between layers of solder, the first layer in contact with the power electronic devices and the second layer in contact with the phase change heat spreader. When activated, this foil may induce the solder to physically and thermally bond the power electronic devices to the phase change heat spreader. Certain embodiments may also employ energetic multilayer foil to thermally bond the phase change heat spreader to a heat dissipation structure. Other embodiments may employ a phase change heat spreader with an integrated heat dissipation structure. In addition, some embodiments may employ a heat sink as the heat dissipation structure, while other embodiments employ a liquid cooling system. | 02-17-2011 |
| 20110235277 | HEAT PIPE CAPABLE OF TRANSFORMING DYNAMIC ENERGY INTO ELECTRIC ENERGY AND RELATED HEAT-DISSIPATING MODULE - A heat pipe includes a conductive hollow case, a conductive capillary layer, a piezoelectric component, and a flexible component. The conductive hollow case has a first end and a second end. The first end is connected to a heat-generating component. The second end is a heat-dissipating end. The conductive capillary layer is formed on an inner wall of the conductive hollow case. A liquid stored in the conductive capillary layer can be heated to evaporate by the heat-generating component and then move toward the second end. The piezoelectric component is connected to the conductive capillary layer. The flexible component is disposed at a side of the piezoelectric component for being driven by the evaporated liquid so as to exert force upon the piezoelectric component. Thus, the piezoelectric component can generate electric energy, which can be transmitted from the conductive capillary layer to the conductive hollow case. | 09-29-2011 |
| 20090040726 | Vapor chamber structure and method for manufacturing the same - A vapor chamber structure includes a casing, a working fluid, a wick layer, a plurality of structure strengthening bodies, and a plurality of backflow accelerating bodies. The casing has an airtight vacuum chamber. The working fluid is filled into the airtight vacuum chamber. The wick layer is formed on a surface of the airtight vacuum chamber. The structure strengthening bodies are respectively arranged in the airtight vacuum chamber for supporting the casing. The backflow accelerating bodies are respectively arranged in the airtight vacuum chamber for increasing the backflow velocity of the working fluid. Therefore, the present invention can maintain the completeness of the vapor chamber structure and increase the backflow velocity of the working fluid due to the match of the structure strengthening bodies and backflow accelerating bodies. Because the backflow velocity of the working fluid is increased, the heat-transmitting efficiency is increased. | 02-12-2009 |
| 20120087090 | HEAT DISSIPATION DEVICE AND RADIO FREQUENCY MODULE WITH THE SAME - A heat dissipation device and a radio frequency module with the same are provided. The heat dissipation device includes a substrate ( | 04-12-2012 |
| 20120087089 | CARDLOCK CLAMP - A cardlock clamp is described that is used to secure an electronics module in a channel of a card cage. The cardlock clamp is configured to convert an input compression force into clamping forces in at least two radial directions perpendicular to the input compression force. The described cardlock clamp also provides self-alignment and self-center functions for the electronics module inserted into the channel. Further, variations of the cardlock clamp are described that provide more effective heat transfer from the electronics module to the card cage. | 04-12-2012 |
| 20120281358 | COOLED ELECTRONIC SYSTEM WITH THERMAL SPREADERS COUPLING ELECTRONICS CARDS TO COLD RAILS - Liquid-cooled electronic systems are provided which include an electronic assembly having an electronics card and a socket with a latch at one end. The latch facilitates securing of the card within the socket or removal of the card from the socket. A liquid-cooled cold rail is disposed at the one end of the socket, and a thermal spreader couples the electronics card to the cold rail. The thermal spreader includes first and second thermal transfer plates coupled to first and second surfaces on opposite sides of the card, and thermally conductive extensions extending from end edges of the plates, which couple the respective transfer plates to the liquid-cooled cold rail. The thermally conductive extensions are disposed to the sides of the latch, and the card is securable within or removable from the socket using the latch without removing the cold rail or the thermal spreader. | 11-08-2012 |
| 20120327602 | Providing A Cooling System For A Medum Voltage Drive System - In an embodiment, a medium voltage drive system includes a transformer, multiple power cubes each coupled to the transformer, and a manifold assembly. Each power cube includes cold plates each coupled to a corresponding switching device of the cube, an inlet port in communication with a first one of the cold plates and an outlet port in communication with a last one of the cold plates. The manifold assembly can support an inlet conduit and an outlet conduit and further support first and second connection members to enable blind mating of each of the first connection members to the inlet port of one of the power cubes and each of the second connection members to the outlet port of one of the power cubes to enable two phase cooling of the plurality of power cubes. | 12-27-2012 |
| 20120250257 | ELECTRONIC APPARATUS - According to one embodiment, an electronic apparatus includes a housing, a circuit board in the housing, a first back plate on the circuit board, a second back plate on the circuit board, and a connecting portion connecting the first back plate with the second back plate. | 10-04-2012 |
| 20130114209 | HEAT MANAGEMENT DEVICE AND ELECTRONIC APPARATUS - An electronic apparatus includes a heat dissipating module and an electronic device. The heat dissipating module includes a base and a plurality of heat dissipating layers. The heat dissipating layers are formed on a surface of the base in sequence. Each heat dissipation layer has at least one heat dissipating structure, and the heat dissipation structure has a heat storage/dissipation area and a heat conductive area. The heat storage/dissipation area surrounds the heat conductive area, and a gap is configured between the heat storage/dissipation area and the heat conductive area. The electronic device is attached to the heat dissipating module. A heat management device is also disclosed. | 05-09-2013 |
| 20130120937 | HEAT DISSIPATION MODULE - A heat dissipation module for an electronic component is provided. The heat dissipation module includes a supporting structure and a heat pipe. The supporting structure is adjacent to the heat electronic component. The heat pipe is connected to the supporting structure by soldering, and the bottom surface of the heat pipe is directly in contact with the upper surface of the electronic component. | 05-16-2013 |
| 20080198550 | HEAT SINK MODULE FOR DUAL HEAT SOURCES - A heatsink module for dual heat sources for dissipating heat generated by a first and a second heat-generating element disposed on a circuit board is provided. The heatsink module includes a first heat-conducting plate, a second heat-conducting plate, a fixing member, a heat pipe, and a pressing flat spring. The first and second heat-conducting plates contact the first and second heat-generating elements respectively. The fixing member when fixed to the circuit board presses the second heat-conducting plate against the second heat-generating element. One end of the pressing flat spring is under the traction of the fixing member fixed to the circuit board, and presses the first heat-conducting plate against the first heat-generating element. The fixing member and the first heat-conducting plate then clamp the heat pipe, so as to conduct the heat generated by the first and second heat-generating elements to the heat pipe via the connecting elements. | 08-21-2008 |
| 20130148299 | COOLING DEVICE, PRINTED CIRCUIT BOARD UNIT, AND ELECTRONIC DEVICE - A cooling device includes: a heat sink and a heat pipe that are connected with each other; a metal plate that is connected with the heat pipe; an elastic member that is provided in the metal plate; and a securing member that is attachable with a printed circuit board on which a beating part is mounted, is able to be secured to the elastic member to be elastically deformed such that the metal plate is pushed to the heating part, and is able to position the metal plate in a state where the securing member is not secured to the elastic member. | 06-13-2013 |
| 20130148300 | Well logging tool - The present invention relates to a device for transfer of heat energy in a well logging tool, where a variable heat flow from a chamber for electronics via a thermovalve is transmitted into a heat sink consisting of cooled metal, thereby establishing an approximately constant temperature in the chamber for electronics. The device comprises an electronics modular unit and a heat sink modular unit, which modular units are connected via an intermediate section, where a heat-regulating thermovalve provides heat conduction between a conical piston and a conical piston seat, for transferring heat energy. | 06-13-2013 |
