Abstract: One aspect of the disclosure is directed to a heat sink assembly for dissipating heat from an electronic component. The heat sink assembly includes a heat sink having a base and at least one fin extending from the base. The at least one fin has an opening formed therein that is configured to receive a fastener. The heat sink assembly also includes a clip. The clip has a first portion configured to receive the fastener and at least one second portion flexibly coupled to the first portion. The at least one second portion is configured to secure the heat sink to the electronic component proximate to the base in response to a force being applied to the first portion by the fastener.

Abstract: A heat sinking device for a component mounted on an electronic circuit board, including: a hollow body, of straight cylindrical or prismatic form, including a first material, arranged vertically on top of the electronic circuit board, the useful volume of the body including at least the component, a resin including a second material, at least partially filling the internal volume of the body so as to contain the component. The heat sinking device can be arranged on an insulating separator element, the resin can be introduced in the liquid state.

Abstract: A graphite structure includes a graphite plate (1) that is made of a highly heat conductive material and has a thickness of 15 ?m or less. A Ti layer (3) having a thickness of 10 nm to 200 nm covers the inner surfaces of through holes (2) penetrating the laminate of the graphite plate (1) from the front side to the back side of the laminate. Furthermore, continuous holes (4) are formed inside the through holes (2). This configuration can achieve a smaller thickness and high reliability while keeping high thermal conductivity of graphite.

Abstract: A printed circuit board assembly (PCBA) is connected to a frame within a passage. The PCBA includes a circuitry package attached to a printed circuit board. The circuitry package has a peripheral edge extending from the printed circuit board to a distal end joined to a cap. A cover is attached to the frame to enclose the PCBA. A thermal interface material (TIM) is disposed between the cover and the PCBA, the TIM defining an opening sized to receivingly engage the circuitry package in a close mating engagement contacting the TIM simultaneously against the cap and the peripheral edge to conduct heat away from the circuitry package. A heat conductor attached to the other side of the printed circuit board in an overlapping opposition to the circuitry package conducts heat away from the printed circuit board that is generated by the circuitry package.

Abstract: A method of manufacturing an electronic component includes disposing a heat radiation material including a plurality of linear structures of carbon atoms and a filling layer of a thermoplastic resin provided among the plurality of linear structures above a first substrate, disposing a blotting paper above the heat radiation material, making a heat treatment at a temperature higher than a melting temperature of the thermoplastic resin and absorbing the thermoplastic resin above the plurality of linear structures with the absorption paper, removing the blotting paper, and adhering the heat radiation material to the first substrate by cooling to solidify the thermoplastic resin.

Abstract: A system includes a removable module to process data when installed in the system, where the module includes a first surface via which heat, that is generated by the module, is transferred. The system also includes a port into which the module is installed; and a heat sink, associated with the port, to dissipate the heat received from the first surface, where the heat sink includes a second surface on which a material is applied, and where the material makes contact with the first surface when the module is installed that allows the heat to be received from the first surface, conforms to an American Society for Testing Materials (ASTM)-B607-91 standard or a United States military specification-C-26074, and transfers the heat to the second surface that allows the module to operate at a temperature that is less than a threshold.

Abstract: A device including a structural member having a heat spreader and an electronic device mounted directly to a first surface of the heat spreader of the structural member. The device also includes a cold plate mounted directly to the first surface of the heat spreader of the structural member.

Abstract: An electronic device includes an electronic component with a mating surface. A thermal interface sheet is attached to the mating surface. A substrate carries the electronic device and includes a face. The electronic component is secured to the substrate with the thermal interface sheet positioned between the mating surface and the face. The mating surface is relatively less flat than the face and the mating surface is relatively smoother than the face.

Abstract: A power supply converter (100) comprising a first FET (210) connected to ground (230), the first FET coupled to a second FET (220) tied to an input terminal (240), both FETs conductively attached side-by-side to a first surface of a metal carrier (120) and operating as a converter generating heat; and a packaged load inductor (110) tied to the carrier and an output terminal (241), the inductor package wrapped by a metal sleeve (113) in touch with the opposite surface of the metal carrier, the sleeve operable to spread and radiate the heat generated by the converter.

Abstract: A mobile terminal is provided. The mobile terminal comprises at least one element, a connector selectively connected to another device to provide a data exchange path between the at least one element and the other device, and a thermal conduction frame having one side coming into contact with the at least one element and the other side coming into contact with the connector to transfer heat generated from the at least one element to the connector. The connector is connected to the element included in the mobile terminal and the other device through the thermal conduction frame to effectively transfer heat generated from the element to the other device through the connector.

Abstract: The sheet structure includes a plurality of linear structures of carbon atoms, a filling layer filled in gaps between the linear structures for supporting the plurality of linear structures, and a coating film formed over at least one ends of the plurality of linear structures and having a thermal conductivity of not less than 1 W/m·K.

Abstract: A power module includes a power module board including an insulating layer and a conductive circuit formed on the insulating layer, a power device provided on the power module board and electrically connected to the conductive circuit, and a thermal conductive sheet for dissipating the heat generated from the power module board and/or the power device. The thermal conductive sheet contains a plate-like boron nitride particle and the thermal conductivity in a direction perpendicular to the thickness direction of the thermal conductive sheet is 4 W/m·K or more.

Abstract: Provided is a terminal box for a solar cell module that has excellent heat radiation. The terminal box (10) is provided with multiple terminal boards (21), a reverse load bypass diode (22) that is connected to two corresponding terminal boards (21), a primary resin layer (23) that is attached to the diode (22) and covers the area around the diode (22), and a secondary resin layer (41) that is made from a resin different to that of the primary resin layer (23) and is adhered to parts other than the diode (22) and does not cover the area around the diode (22).

Abstract: A Light Emitting Diode (LED) module includes a circuit board having a front side and a back side, a heat sink coupled to the back side of the circuit board, a thermal pad disposed on a front side of the circuit board, an LED disposed on the front side of the circuit board. The LED is in thermal contact with the thermal pad. The module further includes a heat spreading device placed over the thermal pad and in thermal contact with the thermal pad.

Abstract: A printed circuit board includes an insulating layer, a signal trace, a ground trace, and a fin. The insulating layer has a first surface and an opposite second surface. The signal trace and the ground trace are formed on the first surface of the insulating layer. The first fin is directly formed on the ground trace. Also provided is a method for manufacturing the printed circuit board.

Abstract: One embodiment of the present invention sets forth a heat spreader module for dissipating thermal heat generated by electronic components. The assembly comprises a printed circuit board (PCB), electronic components disposed on the PCB, a thermal interface material (TIM) thermally coupled to the electronic components, and a heat spreader plate thermally coupled to the TIM. The heat spreader plate includes an embossed pattern. Consequently, surface area available for heat conduction between the heat spreader plate and surrounding medium may be increased relative to the prior art designs.

Abstract: One embodiment of the present invention sets forth a heat spreader module for dissipating thermal heat generated by electronic components. The assembly comprises a printed circuit board (PCB), electronic components disposed on the PCB, a thermal interface material (TIM) thermally coupled to the electronic components, and a heat spreader plate thermally coupled to the TIM. The heat spreader plate includes an embossed pattern. Consequently, surface area available for heat conduction between the heat spreader plate and surrounding medium may be increased relative to the prior art designs.

Abstract: Carbon nanotube material is used in an integrated circuit substrate. According to an example embodiment, an integrated circuit arrangement (100) includes a substrate (110) with a carbon nanotube structure (120) therein. The carbon nanotube structure is arranged in one or more of a variety of manners to provide structural support and/or thermal conductivity. In some instances, the carbon nanotube structure is arranged to provide substantially all structural support for an integrated circuit arrangement. In other instances, the carbon nanotube structure is arranged to dissipate heat throughout the substrate. In still other instances, the carbon nanotube structure is arranged to remove heat from selected portions of the carbon nanotube substrate.

Abstract: An electronic control device for controlling an electric actuator, including an air passage within a casing that is fixable to an actuator housing of the electric actuator. A circuit board is accommodated in the casing. A projecting portion is formed in the casing, on which a region of the circuit board in which the heat generating part is installed is seated. A vent hole extends through the casing to communicate to an outside of the casing. A communication hole extends through the casing to communicate to an inside of the actuator housing. The air passage allows air to flow between the vent hole and the communication hole when the electric actuator is driven in a state that the casing is fixed to the actuator housing.

Abstract: A tube includes a tube body and a heat-dissipating member. A light-emitting module and a first electronic component connected electrically to the light-emitting module are disposed in the tube body. At least one opening is formed on the tube body in correspondence to the first electronic component. The heat-dissipating member is placed over the opening. The heat-dissipating member provides a first heat-dissipating path for the first electronic component.

Abstract: A heat dissipation module for an electronic apparatus including a heat-generating structure is provided. The heat dissipation module includes a heat dissipation structure and a heat-conducting structure. The heat-conducting structure includes a heat-conducting portion and an extending portion. The heat-conducting portion is adhered between the heat-generating structure and the heat dissipation structure. The heat generated by the heat-generating structure is transmitted to the heat dissipation structure through the heat-conducting portion. The extending portion is connected to the heat-conducting portion and exposed to the heat-generating structure and the heat dissipation structure.

Abstract: Cooling apparatuses and methods are provided for immersion-cooling one or more electronic components. The cooling apparatus includes a housing at least partially surrounding and forming a fluid-tight compartment about the electronic component(s), and a boiling fluid mixture of first and second dielectric fluids within the fluid-tight compartment, with the electronic component(s) immersed within the mixture. A condensing fluid is also provided within the fluid-tight compartment, and is immiscible with the boiling fluid mixture. The condensing fluid has a lower specific gravity and a higher thermal conductivity than the boiling fluid mixture, and facilitates condensing of vaporized boiling fluid mixture. A cooling structure is provided within the compartment, and includes a condensing region and a sub-cooling region, with the condensing region being in contact with the condensing fluid, and the sub-cooling region being in contact with the boiling fluid mixture.

Abstract: A thermal module for mounting to and using with a solar inverter includes a heat sink, at least one cooling module, and a thermal insulator. The heat sink has a heat-receiving portion and a heat-radiating portion, and the cooling module has a hot side and a cold side. The hot side of the cooling module is in contact with the heat-receiving portion of the heat sink while the cold side is in contact with a heat-producing source on the solar inverter. The thermal insulator is provided in a space between the heat-receiving portion of the heat sink, the cooling module, and the heat-producing source of the solar inverter. With the cooling module provided between the heat sink and the solar inverter, the solar inverter can have largely upgraded heat dissipation efficiency.

Abstract: An electronic module is provided in which a chip is disposed over a substrate and electrically connected to the substrate by a plurality of electrical connect structures disposed between the chip and the substrate. A heat distributor, fabricated of a thermally conductive material, is disposed between the chip and the substrate and sized to extend beyond an edge of the chip to facilitate conduction of heat laterally out from between the chip and substrate. The heat distributor includes openings sized and positioned to allow the electrical connect structures to pass through the heat distributor without electrically contacting the heat distributor. The heat distributor is electrically isolated from the electrical connect structures, the chip and the substrate. In one implementation, the heat distributor physically contacts a thermally conductive enclosure of the electronic module to facilitate conduction of heat from between the chip and substrate to the enclosure.

Abstract: The disclosed embodiments relate to a system that facilitates thermal conductance in a system that includes a module comprising a circuit board with integrated circuits, such as a solid-state drive. A thermal-coupling material between one side of the circuit board and an adjacent baseplate is used to increase thermal conduction between the circuit board and the baseplate. Furthermore, the module may include another thermal-coupling material between the baseplate and a housing that at least in part surrounds the circuit board, thereby increasing thermal conduction between the baseplate and the housing. In these ways, the baseplate and/or the housing may be used as a heat-transfer surfaces or heat spreaders that reduce hotspots associated with operation of the integrated circuits.

Abstract: A heat dissipating system includes a shell, a main circuit board, at least two heat generating elements, and at least one fan. The shell includes a first sidewall, a second sidewall facing the first sidewall, and a third sidewall connected to the first sidewall and the second sidewall. The at least one fan are arranged on the first sidewall. The second sidewall defines a number of vents. The main circuit board is positioned between the at least one fan and the vents. The heat dissipating system further includes a connection assembly positioned between the first and second circuit boards. The main circuit board includes a first circuit board and a second circuit board. The first circuit board is electrically connected to the second circuit board through the connection assembly. The at least two heat generating elements are respectively positioned on the first circuit board and the second circuit board.

Abstract: An electronic device having one or more components that generate heat during operation includes a structure for temperature management and heat dissipation. The structure for temperature management and heat dissipation comprises a heat transfer substrate having a surface that is in thermal communication with the ambient environment and a temperature management material in physical contact with at least a portion of the one or more components of the electronic device and at least a portion of the heat transfer substrate. The temperature management material comprises a polymeric phase change material having a latent heat of at least 5 Joules per gram and a transition temperature between 0° C. and 100° C., and a thermal conductive filler.

Abstract: A method, system, and apparatus for cooling one or more devices through use of a cooling plate. An example system includes multiple heat generating devices coupled to a cooling plate, each through an individual thermal interface unit. The thermal interface unit includes a compressible solid pad with at least one surface having a plurality of projections carrying a flowable material. The thermal interface units are pressed between the heat generating devices and the cooling plate so that the flowable material is completely enclosed.

Abstract: Carrier device for placement of thermal interface materials. At least some embodiments are systems including a first electrical component that defines a first surface at a first elevation relative to an underlying structure, a second electrical component that defines a second surface at a second elevation relative to the underlying structure, a metallic member configured to conduct heat from the electrical components, and a carrier between the electrical components and the metallic member. The carrier includes a third and fourth surface configured to mate with the first and second surfaces, respectively, a first aperture through the third surface, and a second aperture through the fourth surface. The system further includes a first thermal interface material coupled between the first electrical component and the metallic member through the first aperture, and a second thermal interface material coupled between the second electrical component and the metallic member through the second aperture.

Abstract: A thermally enhanced electronic package comprises a driver chip, an insulator, a flexible carrier, and carbon nanocapsules. The flexible carrier includes a flexible substrate, a wiring layer formed on the substrate, and a resistant overlaying the wiring layer. The driver chip is connected to the wiring layer. The insulator is filled in the gap between the driver chip and the flexible carrier. The carbon nanocapsules are disposed on the driver chip, on the resistant, on the flexible carrier, or in the insulator to enhance heat dissipation of electronic packages.

Abstract: A plasticized ceramic thermal dissipation module comprises a heating electrical component, a cooling body, and a thermal conductive device. They are located orderly. The thermal conductive device is a substrate and the heating electrical component is arranged on the substrate, in which the cooling body is a plasticized ceramic and seamlessly integrated with the thermal conductive device together as a component (All-In-One).

Abstract: 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.

Abstract: In a Cr—Cu alloy that is formed by powder metallurgy and contains a Cu matrix and flattened Cr phases, the Cr content in the Cr—Cu alloy is more than 30% to 80% or less by mass, and the average aspect ratio of the flattened Cr phases is more than 1.0 and less than 100. The Cr—Cu alloy has a small thermal expansion coefficient in in-plane directions, a high thermal conductivity, and excellent processibility. A method for producing the Cr—Cu alloy is also provided. A heat-release plate for semiconductors and a heat-release component for semiconductors, each utilizing the Cr—Cu alloy, are also provided.

Abstract: A multi-hybrid module includes a plurality of hybrid assemblies that are perpendicularly mounted with respect to a plane of a circuit board. The hybrid assemblies are mounted on opposing sides of a heat sink. The heat sink has a first column disposed at a first end, a second column disposed at a second opposing end, and a generally flat center wall extending between the first column and the second column to which the hybrid assemblies are mounted. During operation the hybrid assemblies are mounted on edge perpendicular with respect to the circuit board to minimize an area profile of the multi-hybrid module on the circuit board.

Abstract: The present invention provides a non-intrusive method for dissipating heat from open-frame DC-DC power converters where bottom side components are exposed. A thermal interface material is placed between the motherboard to which the power converter is soldered and power dissipating and temperature sensitive components on the bottom of the power converter. The thermal interface material fills the gap between the power converter components and the motherboard, thereby providing a heat conductive path for dissipating heat from the power converter to the motherboard.

Abstract: Disclosed is a composition, in particular a dispersion, which contains nanofiber material in at least one organic matrix component, said nanofiber material being pre-treated in at least one method step for adjusting the physical properties of the composition.

Abstract: The invention relates to a power semiconductor module including a module underside, a module housing, and at least two substrates spaced from each other. Each substrate has a topside facing an interior of the module housing and an underside facing away from the interior of the module housing. The underside of each substrate includes at least one portion simultaneously forming a portion of the module underside. At least one mounting means disposed between two adjacent substrates enables the power semiconductor module to be secured to a heatsink.

Abstract: The present invention discloses a method of cooling an ultramobile device with microfins attached to an external wall of an enclosure surrounding the ultramobile device.

Abstract: A heat transfer film includes a heat transfer layer formed of a first constituent material containing C (carbon) for transferring heat in an in-plane direction thereof and a layer thickness direction thereof; and a strain relaxation layer formed of a second constituent material and laminated on the heat transfer layer for relaxing a strain in the heat transfer layer. The first constituent material includes a graphite, and the second constituent material includes an amorphous material.

Abstract: A circuit card enclosure comprises a backplane including a plurality of connectors. First and second conduction rails are thermally coupled to a heat exchanger, the first and second conduction rails each comprising an inner body at least partially encapsulated by an outer body. The inner body comprises a thermally conductive material. The outer body comprises a structural material. Card slots of the circuit card enclosure are defined between opposed card channels of the first and second conduction rails. Each card slot is constructed and arranged to register an inserted circuit card with at least one of the connectors, the card channels including a thermally conductive region constructed and arranged to thermally interface with a thermal frame of an inserted circuit card, the thermally conductive region of the card channels being thermally coupled to the inner body of the conduction rail.

Abstract: The present invention relates to an epoxy resin composition for electronic parts encapsulation, including the following components (A) to (E), (A) an epoxy resin having an ICI viscosity of from 0.008 to 0.1 Pa·s and an epoxy equivalent of from 100 to 200 g/eq; (B) a phenol resin having an ICI viscosity of from 0.008 to 0.1 Pa·s and a hydroxyl-group equivalent of from 100 to 200 g/eq; (C) a curing accelerator; (D) an inorganic filler; and (E) a silicone compound, in which the component (D) is contained in an amount of from 82 to 88 wt % of the whole of the epoxy resin composition, the component (E) is contained in an amount of from 5 to 15 wt % of the whole of organic components in the epoxy resin composition, and the epoxy resin composition has a gelation time of 15 to 25 seconds.

Abstract: An electronic assembly includes a heat source having a maximum operating temperature, a heat dissipating device, a thermal interface material sandwiched between the heat source and the heat dissipating device. The thermal interface material includes a base and a plurality of first thermally conductive particles dispersed in the base. The first thermally conductive particles have a size monotonically changing from a first size less than 100 nanometers and a first melting temperature below the maximum operating temperature, to a second size larger than 100 nanometers and a second melting temperature above the maximum operating temperature when the heat source operates at a temperature above the first melting temperature and at or below the maximum operating temperature.

Abstract: The exemplary embodiments of the present invention provide a method and system for aligning graphite nanofibers in a thermal interface material to enhance the thermal interface material performance. The method includes preparing the graphite nanofibers in a herringbone configuration, and dispersing the graphite nanofibers in the herringbone configuration into the thermal interface material. The method further includes applying a magnetic field of sufficient intensity to align the graphite nanofibers in the thermal interface material. The system includes the graphite nanofibers configured in a herringbone configuration and a means for dispersing the graphite nanofibers in the herringbone configuration into the thermal interface material. The system further includes a means for applying a magnetic field of sufficient intensity to align the graphite nanofibers in the thermal interface material.

Abstract: A multilayer printed circuit board has an embedded heater layer having at least one elongated heater element trace of copper which is densely arranged in a predetermined circuitous path over at least part of the area of the board. The heater element has inputs configured for connection to a standard high current, low voltage power supply, and may also have ground connections for selective connection to a ground layer. The heater layer may be embedded in a carrier board of a surface mount module close to the lower solder interface layer, or may be embedded in a host board of an electronics assembly close to the mounting surface.

Abstract: An article and method of forming the article is disclosed. The article includes a heat source, a heat-sink, and a thermal interface element having a plurality of freestanding nanosprings, a top layer, and a bottom layer. The nanosprings, top layer, and the bottom layers of the article include at least one inorganic material. The article can be prepared using a number of methods including the methods such as GLAD and electrochemical deposition.

Abstract: A thin portable electronic device with a display is described. The components of the electronic device can be arranged in stacked layers within an external housing where each of the stacked layers is located at a different height relative to the thickness of the device. One of the stacked layers can be internal metal frame. The internal metal frame can be configured to act as a heat spreader for heat generating components located in layers adjacent to the internal frame. Further, the internal metal frame can be configured to add to the overall structural stiffness of the device. In addition, the internal metal frame can be configured to provide attachment points for device components, such as the display, so that the device components can be coupled to the external housing via the internal metal frame.

Abstract: A display panel includes an airtight casing and a thermally conductive member. A thermal conductivity of the thermally conductive member in a longitudinal direction of spacers is higher than a thermal conductivity of the thermally conductive member in a direction in which the spacers are provided side by side, and the thermal conductivity of the thermally conductive member in the direction in which the spacers are provided side by side is higher than a thermal conductivity of the thermally conductive member in a thickness direction.

Abstract: An electronic device includes a casing, an electronic component accommodated in the casing; and a composite heat conductive layer between the casing and the electronic component. The composite heat conductive layer includes a graphite layer and a thermal pad layer between the electronic component and the graphite layer. The thermal pad layer is attached to the electronic component. The graphite layer is attached to an inner surface of the casing. The graphite layer is located between the casing and the thermal pad layer. Heat conductive efficiency of the graphite layer along a horizontal spreading direction thereof exceeds that along a vertical thickness direction thereof. A surface area of the graphite layer is not less than that of the electronic component. Heat generated by the electronic component is evenly transferred and is spread to the casing via the graphite layer of the composite heat conductive layer.

Abstract: A heat sink assembly is provided for a pluggable module. The heat sink assembly includes a heat sink having a module side and an end surface that intersects the module side. The module side is configured to thermally communicate with the pluggable module. A holder extends from the end surface of the heat sink. A thermal interface material (TIM) layer extends on the module side of the heat sink. The TIM layer is configured to engage the pluggable module. The TIM layer includes an end that is engaged between the end surface and the holder of the heat sink.

Abstract: This document describes apparatus and methods for a self-contained assembly having an encapsulated electronic module coupled to a heat removal device by a thermally conductive substance. In an illustrative example, the module includes at least one heat dissipating device thermally coupled by internal members to selected portions of a housing. The module housing includes a flat top surface with a perimeter adjoined to side surfaces. In one example, the heat removal device includes a cavity interior surface with an upper surface to match the module top surface, and side walls that match at least 50% by area of the selected portions of the module side surfaces. The cavity interior surface may receive at least 50% of the housing surface area. The matched portion of the cavity side surfaces may be at least 33% by area of the portion of the cavity upper surface that matches the module top surface.