Abstract: A heat spreader for an integrated circuit has a base portion and a top portion. The base portion is attachable to a surface of the integrated circuit, and has at least one channel extending therethrough. The top portion that is larger than the base portion such that the heat spreader is generally T-shaped in cross-section. The top portion has a hole at its center that extends from a top surface of the top portion to the at least one channel of the base portion. Mold compound is injected through the hole and out through the channels.

Abstract: A power conversion apparatus is provided which includes a semiconductor module which include a switching element, a cooler which cools the semiconductor module, and has a pair of cylindrical pipes which introduce a cooling medium to a channel therein or discharge the cooling medium, a frame which holds the cooler, and a pair of clamps which fix the cylindrical pipes to the frame. Each of the clamps has a fastener portion which is fastened to the frame, and a pressing portion which presses the cylindrical pipe toward the frame. Each of the cylindrical pipes is held between a concave support portion, which is formed in the frame, and the clamp. Each of the cylindrical pipes is supported by two support surfaces of the concave support portion and the pressing portion of the clamp at three support points when viewing from the direction in which the cylindrical pipe extends.

Abstract: A heatsink may include an area in thermal contact with a semiconductor microchip surface and a first trench of a first depth. The first trench may be substantially continuous around the area. A first substance, such as ferrite, may be positioned in the first trench to attenuate electromagnetic interference. A second trench having a second depth may be formed around and further from the area than the first trench. A second substance may be positioned in the second trench.

Abstract: A portable electronic device includes a housing, a radiating assembly, a display, a battery, and a heat sink assembly. The housing includes a front portion and a back portion opposite to the front portion. Both the radiating assembly, the display, the battery, and heat sink assembly are received in the housing. The heat sink assembly is a semiconductor cooling plate, and dissipates heat from the radiating assembly out of the housing.

Abstract: The invention relates to a light emitting module (10) comprising a light source (20) and a heat sink (30). The light source is thermally connected to the heat sink. The heat sink is configured to be detachably mounted on a cooling body (50), at least part of an outer wall (40) of the heat sink having a shape matching at least a part of an outer wall (56) of the cooling body to enable the transfer of heat generated by the light source to the cooling body. The effect of the measures according to the invention is that they enable the active cooling of the light emitting module to be separated from the light emitting module itself, thereby reducing the complexity of the light emitting module while still relatively easily enabling active cooling via the cooling body. The cooling body may, for example, be a cooling pipe through which a cooling fluid flows.

Abstract: An electronic device comprises a cooler comprises a plurality of first locking members, a backboard defining pluralities of first and second positioning holes, and a circuit board. The backboard is attached to the cooler through the first locking members engaged with the second positioning holes. A first mounting member and a second mounting member are adapted to receive the heat generating component. The first mounting member defines a plurality of locking holes. The first positioning holes are among the second positioning holes. The second mounting member receives the heat generating component, the circuit board is between the second mounting member and the backboard, the first mounting member is secured to the circuit board; when the first mounting member receives the heat generating component, the circuit board is between the first mounting member and the backboard, the first mounting member is secured to the backboard.

Abstract: A thermal interface unit includes a pedestal, a first contact surface below the pedestal to interface with a first die and a flat spring to enable the first contact surface to adapt to a variable height of a first die of a multi-chip package (MCP).

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: The present invention relates to a heat sink (1), which is in thermal connection with at least one electronic component (4). The heat sink (1) has at least one chamber (2), which has at least one wall with at least one porous element (3a). Pressure producing means (7) are connected to the chamber (2), in order to cyclically modulate the air pressure P1 in the chamber (2). Thus, a “breathing” of air through the at least one porous element (3a) can be achieved and a cooling effect is obtained. Additionally, holes (8) can be provided to the chamber (2), which produce cyclic air jets (9) due to the fluctuating chamber air pressure P1.

Abstract: Disclosed is a heat exchanger wherein warping (bending) of an intervening member and a frame is suppressed when the intervening member and a wall portion of the frame member having different linear expansion coefficients are welded with each other. A method for manufacturing the heat exchanger, a semiconductor device wherein warping (bending) of an intervening member and a frame is suppressed, and a method for manufacturing the semiconductor device are also disclosed. Specifically disclosed is a heat exchanger wherein a fin member provided with a plurality of fins forming flow channels for a refrigerant is arranged within a frame which forms the outer casing. The frame has a first frame member (a first wall portion) to which insulating plates (intervening members) interposed between the frame and heat-generating bodies (semiconductor elements are welded. The insulating plates (intervening members) have a linear expansion coefficient different from that of the frame.

Abstract: A heat sink includes a contact portion, a first support rib, a second support rib, a third support rib and a fourth support rib radially extended from the contact portion, and a plurality of parallel fins radially extended from the first support rib, the second support rib, the third support rib and the fourth support rib between two adjacent support ribs. The contact portion contacts with a first heat source. A distance from the contact portion to an edge of the plurality of parallel fins between the first support rib and the second support rib is a first distance. A distance from the contact portion to an edge of the plurality of parallel fins between the third support rib and the fourth support rib is a second distance. The first distance is less than the second distance.

Abstract: According to one aspect of the present invention, there is provided a heat spreader to be mounted on an IC package, the IC package including: a circuit board; an IC chip mounted on one surface of the circuit board; and a plurality of connection terminals formed on the other surface of the circuit board, the heat spreader including: a top wall formed into a rectangular shape; a circumferential wall formed continuously from the top wall, the circumferential wall and the top wall defining a block-like cavity for enclosing the IC chip when the heat spreader is mounted on the IC package; and ear portions formed at lengthwise central portions of a facing pair of side walls of the circumferential wall so to extend outwardly from bottom edges of the facing pair of side walls, respectively.

Abstract: An apparatus for passively cooling electronics. The apparatus for passively cooling electronics includes at least one heat sink configured to be thermally coupled to at least one cabinet. When the at least one cabinet is thermally coupled to the at least one heat sink, the at least one heat sink draws heat from the at least one cabinet.

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: A COF includes, in at least one embodiment, a heat dissipating material on a back surface of an insulating film. The heat dissipating material has a slit for reducing a degree of thermal expansion. Thus, at least one embodiment of the invention provides the COF in which deformation and disconnection of wiring are prevented.

Abstract: The invention relates to an electrical connector assembly. The electrical connector assembly includes a main circuit board having a through hole, a processor, and an auxiliary circuit board. The processor includes a chip and a substrate. The chip is electrically connected to the substrate and located in the through hole. The substrate is at least partially located in the through hole. The auxiliary circuit board has a transitional connecting surface. A first conducting region and a second conducting region electrically connected to each other are disposed on the transitional connecting surface. The first conducting region is electrically connected to the substrate, and the second conducting region is electrically connected to the main circuit board.

Abstract: An auxiliary device for conductively removing the heat produced by one or more components on an electronic card includes a heat sink covering all or part of the card. The device includes at least a first heat-conducting element mounted to absorb the heat produced by the one or more components, a movable second heat-conducting element, a heat pipe connecting the first element with the second element, and clamping means designed to press the movable second element against a cold wall.

Abstract: In order to achieve reduction in loss, a semiconductor power module comprises DC terminals to be connected to a condenser module and the semiconductor power module is used in combination with a cooling jacket for cooling, and the DC terminals protrude toward the condenser module beyond the cooling jacket.

Abstract: An apparatus is disclosed that may include one or more printed circuit boards (PCBs) and an electronics package may be disposed about the first surface of one or more of the PCBs. The PCBs may include a metal layer and a core, and, in some aspects, may include multiple cores interposed between multiple metal layers, and in some embodiments a backplane may be disposed along the core(s). A plurality of PCB's may be set apart and connected by pins to dissipate heat from one PCB to another, and/or to convey electrical connectivity. Pins may be configured to pass through or into one or both the PCBs including the cores to conduct heat generated by the electronics package away for dispersion. In some embodiments, the pins may pass into the backplane. The apparatus may include LEDs, lights, computer devices, memories, telecommunications devices, or combinations of these.

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: An electronic device includes a casing, a fan, and a heat sink. The casing defines a plurality of through holes therein. The fan defines air outlet at one side thereof facing the through holes of the casing. The air outlet includes a first portion and a second portion. Air pressure in the first portion is larger than air pressure of the second portion. The heat sink includes a first fin set arranged on the first portion and a second fin set arranged on the second portion. A first passage is defined between each two neighboring first fins. A second passage is defined between each two neighboring second fins. A width of the second passage is less than that of the first passage.

Abstract: Disclosed herein are a heat-radiating substrate and a method of manufacturing the same. The heat-radiating substrate includes: a base substrate with a heat sink, having a groove; an insulating layer formed on the base substrate by performing anodization thereon; and a circuit layer formed on the insulating layer, whereby the heat-radiating substrate with the heat-sink, made of metal material, is manufactured, thereby making it possible to protect devices weak against heat and thus solve the problem in view of reduced life span and degraded reliability.

Abstract: A circuit board module includes a circuit board and a heat-dissipating device. The circuit board includes a ceramic substrate, and a circuit pattern formed on a surface of the ceramic substrate. The circuit board is sinter-bonded to a main body of the heat-dissipating device. A method of making the circuit board module is also disclosed.

Abstract: An article and method of forming the article is disclosed. The article includes a heat source, a substrate, and a thermal interface element having a plurality of freestanding nanosprings disposed in thermal communication with the substrate and the heat source. The nanosprings of the article include at least one inorganic material and also at least 50% of the nanosprings have a thermal conductivity of at least 1 watt/mK per nano spring.

Abstract: Some embodiments of a method, apparatus and computer system are described for vortex generator enhanced cooling. The computer system may include a housing and an apparatus. The apparatus may include one or more vortex generators coupled to a heat spreader and positioned in close proximity to an electronic component, and a flow of air to provide for an exchange of thermal energy, where the flow of air is provided by a configuration of the housing, and where the one or more vortex generators may promote turbulence to enhance the exchange of thermal energy of the electronic component. In some embodiments, an air mover may be used to increase the flow of air in the housing. Other embodiments are described.

Abstract: A thermal interface includes a plurality of elevated regions and a plurality of mechanical tolerance circuits coupled to the plurality of elevated regions. The thermal interface is configured to be disposed between an array of heat generating elements and a heat sink with each of the plurality of elevated regions thermally coupled to a corresponding one or more of the array of heat generating elements. In one embodiment, the thermal interface provides a thermal path between a printed wiring board having a plurality of flip-chip circuit components disposed on an external surface thereof and a heat sink disposed over the flip-chip circuit components.

Abstract: In accordance with an embodiment of the present invention, a device includes a circuit board with a thermally conductive core layer and a chip disposed over the circuit board. The device further includes a heat sink disposed over the chip. The thermal conductivity of the heat sink along a first direction is larger than a thermal conductivity along a second direction. The first direction is perpendicular to the second direction. The heat sink is thermally coupled to the thermally conductive core layer.

Abstract: Distribution and coupling of waste heat from planar non-concentration photovoltaic cells and semiconductor electrical devices is enhanced by forming dielectric relief structures and thermal conductive and emissive coatings on the cover and/or backing plate. The composite relief structures of layers, voids, and fins on the back surface mitigate the differential thermal expansion of dissimilar material and optimize convective heat transfer and radiant heat transfer with respect to costs. This leads to higher performance of the photovoltaic and semiconductor cells, a stronger and lighter backing plate components, and lower cost per watt for mounted devices.

Abstract: A heat-radiating component is bonded via a thermal interface material (TIM) to an electronic component (chip) mounted on a wiring board. The heat-radiating component includes a plate-like portion thermally bonded to the chip through the TIM, and a foot portion formed on a surface which faces the electronic component, of the plate-like portion. The foot portion is formed in a ring shape at a position which surrounds a region corresponding to a mounting area of the electronic component, on the inner side of the periphery of the plate-like portion.

Abstract: An inner-layer heat-dissipating board and a multi-chip stack package structure having the inner-layer heat-dissipating board are disclosed. The inner-layer heat-dissipating board includes a metal board body formed with a plurality of penetrating conductive through holes each comprising a plurality of nano wires and an oxidative block having nano apertures filled with the nano wires. The multi-chip stack package structure includes a first chip and an electronic component respectively disposed on the inner-layer heat-dissipating board to thereby facilitate heat dissipation in the multi-chip stack structure as well as increase the overall package rigidity.

Abstract: An illuminated sign includes a plurality of straight fin heat sinks framed together; a plurality of LED plates framed together, each LED plate comprising a plurality of LEDs arranged in rows on a front surface, and a plate heat sink on a rear surface, the plate heat sinks being in contact with the straight fin heat sinks; and an LCD panel mounted in front of the LED plates by framing.

Abstract: The present invention provides a method for manufacturing a heat transfer member which method allows peel-off and cracking possibly caused by thermal expansion to be inhibited. That is, the present invention provides a method for manufacturing a heat transfer member 10, the method at least including a step of forming metal powder into a coating film 12 on a surface of a base material 11 by spraying the metal powder in a solid state onto the surface of the base material 11 together with compressed gas. In the film forming step, a spraying pressure at which the metal powder is sprayed onto the surface of the base material 11 is set so that the coating film 12 has a porous structure.

Abstract: The present invention relates generally to a heat sink comprising a plurality of fins, each fin having two or more prongs extending from a root section of the fin. In certain embodiments, the heat sink may be assembled by aligning the plurality of fins within slots between protrusions extending from a base of the heat sink. However, in other embodiments, the plurality of fins may have connector ends having female sides and opposite male sides, wherein the plurality of fins may be attached to each other via the interlocking female and male sides, thereby forming at least part of the base of the heat sink, and fortified with reinforcing members.

Abstract: A mounting assembly includes a circuit board, a securing member and a heat dissipating device. A retainer is located on the circuit board. The securing member includes a positioning portion and a claw connected to the positioning portion. The heat dissipating device includes a base attached to the circuit board and a number of fins perpendicularly located on the base. The number of fins defines a number of first air paths and a number of second air paths substantially perpendicular to the number of first air paths. The positioning portion is received in at least one of the number of first air paths and at least one of the number of second air paths, and the claw is engaged with the retainer.

Abstract: A heat sink for an electronic device is made of thermally conductive materials and is formed by winding a rod into a helix so as to have a plurality of loops of progressively smaller diameters. With the above-mentioned structure, the heat sink can provide improved heat dissipation and air convection because of large surface area of the rod and no dead angle.

Abstract: 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.

Abstract: Vapor condensers and cooling apparatuses to facilitate vapor condensation cooling of a coolant employed in cooling an electronic device or electronic subsystem. The vapor condenser includes a thermally conductive base structure having an operational orientation when the condenser is facilitating vapor condensate formation, and a plurality of thermally conductive condenser fins extending from the thermally conductive base structure. The plurality of thermally conductive condenser fins have a varying cross-sectional perimeter along at least a portion of their length. The cross-sectional perimeters of the plurality of thermally conductive condenser fins are configured to increase in a direction of condensate travel.

Abstract: A heat sinking element and a method of treating a heat sinking element are provided. The heat sinking element includes a metal substrate. The metal substrate is mainly composed of aluminium. A surface of the metal substrate has a plurality of micro-nano holes and a diameter of the micro-nano holes is smaller than 300 nm. The method of treating a heat sinking element includes performing an oxidation process and an etching process on the metal substrate so as to form the plurality of micro-nano holes.

Abstract: Systems and methods for thermal management for telecommunications enclosures are provided. In one embodiment, a method for thermal management for modular radio frequency (RF) electronics housed within an electronics enclosure comprises: distributing heat generated from an RF electronics component installed on a first thermal region of an electronics module base plate across the first thermal region using at least one primary heat pipe that laterally traverses the first thermal region; distributing heat generated from the RF electronics component to a second thermal region using at least one secondary heat pipe not parallel with the at least one primary heat pipe; conductively transferring heat across a thermal interface between the electronics module back-plate and a backplane of an electronics enclosure that houses the electronics module, wherein the backplane comprises a plurality heat sink fins aligned with the at least one primary heat pipe and the at least one secondary heat pipe.

Abstract: A memory module is provided having a plurality of integrated circuit packages. The memory module includes a first thermal conduit in thermal communication with a first set of integrated circuit packages on the first side, and substantially thermally isolated from a second set of one or more integrated circuit packages on the first side. The memory module further includes a second thermal conduit in thermal communication with the set of one or more integrated circuit packages.

Abstract: The invention provides an apparatus for dissipating heat produced by a laser for lighting projection to enable a passive encapsulated enclosure. The laser is mounted into a collar system which integrates to the internal enclosure body with a single or plurality of bonded extending facet planes. The facet planes can conduct and radiate heat to the internal enclosure body planes which dissipate heat to the outside environment of the closed enclosure as a heat sink.

Abstract: Provided is a heat sink clip for fastening a heat sink on a printed circuit board (PCB). The heat sink clip includes two hooks and a wire clip. The two hooks are inversely fixed to the PCB at two opposite sides of the heat sink. The wire clip includes a pressing wire pressing the heat sink, two pairs of deforming wires extending from the lateral of the pressing wire along two radial directions of the pressing wire and away from the PCB, and two engaging wires engaging with the respective hooks such that the deforming wires are bent towards the PCB.

Abstract: An electronic device includes a bottom plate, a circuit board having an electronic component, a fan, and an airflow guide member. The circuit board is fixed to the bottom plate. The fan is arranged at the front of the circuit board. The airflow guide member is arranged between the fan and the circuit board. The airflow guide member includes an airflow guide wall defining a number of spaced slots, and a number of stop plates selectively inserted into the corresponding slots of the airflow guide wall, to leave some of the slots directly in front of the bottom of the electronic component open.

Abstract: A cooling device for cooling electronic components includes a base plate, a power source, and a cooling module. The cooling module includes a cooling sheet and a thermal conductive base. The cooling sheet includes a hot surface and a cooling surface. The thermal conductive base is located above the cooling surface of the cooling sheet, and configured to support electronic components on a printed circuit board and transfer heat between the electronic components and the cooling surface. When the cooling sheet is powered on, the cooling surface is in a constant state of low temperature. Due to the heat transfer between the cooling surface and the thermal conductive base, heat from the electronic components can be transferred from the thermal conductive base to the cooling surface continuously.

Abstract: A locking device providing thermal management for an electrical assembly board is described and includes a fluid-permeable member saturated with a fluid and disposed between the electrical assembly board and a heat sink; a pair of locking device substrates substantially orthogonal to the electrical assembly board and the heat sink; and an actuator coupled to at least one of the locking device substrates. The fluid-permeable member is disposed between the locking device substrates. The actuator is configured to compress the fluid-permeable member by at least one of the locking device substrates forcing a portion of the fluid out of the fluid-permeable member and forming at least one fluid contact interface with the electrical assembly board and the heat sink in a reversible process. A method for making a locking device is also described.

Abstract: An image displaying apparatus, which is excellent in heat radiation efficiency and has an excellent back design, includes a display panel for displaying an image; a heat generating member provided on a back side of the display panel; and a cabinet for covering the display panel and the heat generating member at least from the back side of the display panel. In the cabinet, an aperture is provided at a position facing the heat generating member, and an opening/closing unit enables switching between closing and opening of the aperture. In a state that the aperture is opened by the opening/closing unit and one part of a heat-transfer member is positioned on a side of the cabinet opposite to the display panel, the other part of the heat-transfer member extends through the aperture so that the heat-transfer member can thermally be connected to the heat generating member.

Abstract: Solid state switching device having a heatsink, a solid state switching element in heat conductive relationship with the heatsink, and an enclosure having ventilation openings adjacent to the heatsink through which air can flow to remove heat from the heatsink. In some disclosed embodiments, the heatsink has fins and ducts aligned with ventilation openings in the enclosure for removing heat by radiation and convection. In others, the heatsink is a generally planar baseplate, with ventilation openings in a side wall of the enclosure next to the baseplate for removing heat from the device. Spacers project laterally from the devices and permit a plurality of the devices to mounted side-by-side with space between the devices through which air can flow.

Abstract: A semiconductor device is disclosed that includes an insulation substrate, a metal wiring layer, a semiconductor element, a heat sink, and a stress relaxation member located between the insulation substrate and the heat sink. The heat sink has a plurality of partitioning walls that extend in one direction and are arranged at intervals. The stress relaxation member includes a stress absorbing portion formed by through holes extending through the entire thickness of the stress relaxation member. Each hole is formed such that its dimension along the longitudinal direction of the partitioning walls is greater than its dimension along the arranging direction of the partitioning walls.

Abstract: An exemplary heat dissipation device includes a fin assembly, a heat pipe, and a protective member. The fin assembly includes stacked fins and air passages between fins. Each fin includes a main body, an extending hole defined in the main body, and a flange extending from the main body around the extending hole. The heat pipe is received in the extending holes of the fins and abuts the flanges of the fins. The protective member includes a plurality pairs of elastic arms. Each pair of elastic arms is sandwiched between a free end of the flange of a corresponding fin and the main body of a corresponding adjacent fin to prevent solder associated with the heat pipe from flowing into the corresponding air passage.

Abstract: A heat sink is thermally coupled to a component with a thermal filler and an intermediate layer applied between the heat sink and the component. The intermediate layer is formed with apertures and the heat sink is pressed against the component with a given force in order for the thermal filler to penetrate the apertures of the intermediate layer.