Abstract: An apparatus for heatsink attachment and a method for forming the apparatus. The apparatus includes a substrate, a semiconductor chip on top of and physically attached to the substrate, and a lid on top of the substrate. The lid includes a first thermally conductive material. The apparatus further includes a heatsink on top of the lid. The heatsink includes a second thermally conductive material. The semiconductor chip and the substrate share a common interface surface that defines a reference direction perpendicular to the common interface surface and pointing from the substrate towards the semiconductor chip. The lid is disposed between the substrate and the heatsink. The lid includes a first protruding member. The first protruding member of the lid is farther away from the substrate than a portion of the heatsink in the reference direction.

Abstract: A heat sink assembly includes an air duct, a heat sink and a fan. The air duct defines an air guiding channel therein. The heat sink is configured to contact a heat source to dissipate heat from a heat source. The heat sink includes a plurality of heat pipes. The heat sink is placed on one side of the air guiding channel, and the heat pipes contacts the air duct to transmit heat to the air duct. The fan is placed on the other side of the air guiding channel to communicate with the heat sink via the air duct. The fan forces air to flow through the air guiding channel to the heat sink to dissipate heat on the air duct and the heat sink.

Abstract: A semiconductor module has a housing, including a power semiconductor, a cooler bearing against the latter and serving for dissipating heat loss. In at least one embodiment, a spring element, which is supported between housing and cooler, is arranged on the side of the cooler remote from the power semiconductor and prestresses the cooler against the power semiconductor.

Abstract: An apparatus for cooling a surface having a metal structure made of a material with high thermal conductivity, and designed to provide efficient cooling of the surface while minimizing mechanical stress between the metal structure and the surface.

Abstract: The invention concerns a power electronic arrangement comprising an insulating substrate, a cooling element arranged beneath the insulating substrate and one or more power electronic components disposed on a respective metallization surface of the insulating substrate. Disposed on the surface of the insulating substrate is a metal layer portion which projects beyond the insulating substrate at all sides. The region of the metal layer portion, that projects beyond the insulating substrate, forms a metal flange which borders the insulating substrate. The cooling element, on its side towards the insulating substrate, beneath the insulating substrate, has one or more recesses, whereby a cavity delimited by the insulating substrate and wall surfaces of the one or more recesses is formed beneath the insulating substrate for receiving a liquid cooling agent. The metal flange is further connected to the cooling element.

Abstract: The invention includes semiconductor packages having grooves within a semiconductor die backside; and includes semiconductor packages utilizing carbon nanostructures (such as, for example, carbon nanotubes) as thermally conductive interface materials. The invention also includes methods of cooling a semiconductor die in which coolant is forced through grooves in a backside of the die, and includes methods of making semiconductor packages.

Abstract: An electronic control apparatus can be reduced in size and cost by eliminating certain parts such as a power board, etc. The apparatus includes a housing, a heat sink attached to one end of the housing, semiconductor switching elements mounted on the heat sink, a circuit board arranged in opposition to the heat sink, and a plurality of conductive plates electrically connecting the circuit board and the semiconductor switching elements. The heat sink is composed of a heat sink main body, and an anodized aluminum film formed at least on a surface of the heat sink main body at a side at which the power device is mounted thereon, and the heat sink main body has outer peripheral end faces arranged in opposition to inner wall surfaces of an opening portion of the housing.

Abstract: Various apparatuses and methods for a preferentially cooled electronic device are disclosed herein. For example, some embodiments provide an electronic apparatus including a package substrate and with a semiconductor die electrically and thermally connected to the package substrate by a plurality of connection nodes. At least one thermal trace interconnects at least one subset of the plurality of connection nodes. At least one heat dissipation trace on the package substrate is connected to the at least one subset of the plurality of connection nodes.

Abstract: A heat dissipation device assembly includes a heat dissipation device for dissipating heat from an electronic element and a protective device assembly. The heat dissipation device includes a base with fasteners extending therethrough, a plurality of fins arranged on a top of the base, and a heat conducting plate attached on a bottom of the base. A thermal interface material is spread on a bottom surface of the heat conducting plate. The protective device assembly includes a first cover attached to a bottom of the heat conducting plate and a second cover separated from the first cover and attached to a lateral side of the base. The first cover protects the thermal interface material from being contaminated and the second cover protects the fasteners from dropping from the base, when the heat dissipation device is transported.

Abstract: A semiconductor device comprises: a semiconductor element; a mounting substrate with the semiconductor element mounted thereon; a first high thermal conductivity member formed on a surface of the mounting substrate; and a first cooling member thermally connected to at least a part of the first high thermal conductivity member. The first high thermal conductivity member is thermally connected to the semiconductor element, and the first high thermal conductivity member has an outer edge which is located outside an outer edge of the semiconductor element.

Abstract: A method and apparatus are provided for manufacturing a lead frame based, over-molded semiconductor package (7) with an exposed pad or power die flag (70) having multiple integrated THT heat spreader pins (71) configured for insertion into one or more vias (77) formed in a printed circuit board (78). The through hole heat spreader pins (71) may be formed as an integral part of the exposed pad (52) or may be solidly connected with the exposed pad (62).

Abstract: A semiconductor device comprises a semiconductor substrate comprised of an interposer having one surface and a semiconductor element provided on the one surface of the interposer, the semiconductor element including a light receiving portion for receiving light thereon; a transparent substrate having light-transmitting property and one surface facing the light receiving portion, the transparent substrate arranged in a spaced-apart relationship with the one surface of the interposer through a gap formed between the one surface of the interposer and the one surface of the transparent substrate; and a spacer formed in a shape of a frame, the spacer positioned between the one surface of the interposer and the one surface of the transparent substrate for regulating the gap, and the spacer having an inner surface and an outer surface, wherein the one surface of the interposer, the one surface of the transparent substrate and the inner surface of the spacer form a space which is hermetically sealed, and wherein the

Abstract: A heat dissipation device for a heat-generating electronic component includes a heat sink (10) and a fan (20) mounted on a lateral side of the heat sink. The heat sink defines a plurality of channels (162) therein. A fan holder (30) is rotatably mounted on the heat sink. The fan is fixedly mounted on the fan holder and faces towards the channels of the heat sink. An airflow generated by the fan flows through the channels of the fan. When the fan holder rotates with respect to the heat sink, an airflow direction of the fan is changed accordingly.

Abstract: An electronic control apparatus can be reduced in size and cost by eliminating certain component parts such as a power board, etc. The apparatus includes a housing, a heat sink, semiconductor switching elements having terminals and mounted on the heat sink, a circuit board arranged in opposition to the heat sink, conductive plates connecting between the circuit board and the semiconductor switching elements, and a cover receiving the semiconductor switching elements and the circuit board in cooperation with the heat sink. The conductive plates have the press-fit terminal portions press-fitted into the through holes in the circuit board, and the individual conductive plates are arranged along a lead-out direction in which the individual terminals of the semiconductor switching elements lead out, and are bonded to the individual terminals.

Abstract: An apparatus and method are provided for limiting failure noise and smoke emissions produced as a result of electrical failure conditions and/or failed electronic devices or assemblies of electronic equipment, such as IT and telecommunications equipment. In one aspect, the apparatus includes a conformable pad, a gasket and a clip that are disposed along one or more surfaces or planes of one or more electronic devices or assemblies such that the apparatus helps to form a substantially air tight seal around the one or more devices or assemblies. The air tight seal the apparatus defines minimizes or eliminates failure noise and smoke emissions generated as a result of failure conditions or catastrophic failure of the one or more devices or assemblies. The apparatus thereby provides a non-electronic solution to limiting failure noise and smoke that is relatively inexpensive to manufacture and implement, and enables in-field servicing of its components and the devices or assemblies to which it is applied.

Abstract: A modular heat-radiation structure includes a module for generating heat, including a first main unit having a heat-radiation fin, fixed to the top face of the first main unit for radiating heat generated in the module and a resin-made and insulating heat shield inserted between the printed circuit board and the first main unit.

Abstract: There is described an arrangement for cooling electrical components disposed on a board-shaped mounting substrate, particularly SMD power components on a printed circuit board, wherein at least one heat sink assigned to a component is present which is disposed on the same side as the components and which is connected in a thermally conductive manner to the assigned component by means of a thermally conductive layer implemented on the mounting substrate. The heat sink is implemented as a bent sheet-metal part and is connected to the thermally conductive layer by means of a solder joint, wherein the bent sheet-metal part has at least one heat sink element which extends in a longitudinal direction and said longitudinal direction is oriented obliquely to the plane of the board-shaped substrate.

Abstract: An enhanced heat transposer comprised is of a vapor chamber. The surface of the vapor chamber that holds the fluid comprises an array of carbon nanotubes (CNTs) that are grown in a way that enables the fluid to come into maximum contact with the CNTs. The fluid evaporates in the sealed vapor chamber when it is in touch with a hot surface. The vapor comes in contact with a hollow pin-fin structure that provides additional surface area for vapor cooling and heat transfer. The condensed vapor then drops back into the fluid container, and the cycle continues.

Abstract: A multiple-gate transistor structure which includes a substrate, source and drain islands formed in a portion of the substrate, a fin formed of a semi-conducting material that has a top surface and two sidewall surfaces, a gate dielectric layer overlying the fin, and a gate electrode wrapping around the fin on the top surface and the two sidewall surfaces separating source and drain islands. In an alternate embodiment, a substrate that has a depression of an undercut or a notch in a top surface of the substrate is utilized.

Abstract: A heat sink (100) includes a plurality of metal fins (10) interlocked with each other by interlocking units (11) formed between them. The interlocking units each include a protruding finger (122), a hole (114) and a controlling member (116, 117). The protruding finger, the hole and the controlling member are aligned with each other. The protruding finger includes a connecting tab (112a) which extends from a flange (14) of the metal fin and a locking tab (112b) which is curved inwardly from the connecting tab towards a main plate (12) of the metal fin. The locking tab of a rear metal fin extends into the hole of a front metal fin and fittingly abuts with the controlling member of the front metal fin so as to firmly interlock the rear and front metal fins together.

Abstract: The present invention is a MEMS-based two-phase LHP (loop heat pipe) and CPL (capillary pumped loop) using semiconductor grade silicon and microlithographic/anisotrophic etching techniques to achieve a planar configuration. The principal working material is silicon (and compatible borosilicate glass where necessary), particularly compatible with the cooling needs for electronic and computer chips and package cooling. The microloop heat pipes (?LHP™) utilize cutting edge microfabrication techniques. The device has no pump or moving parts, and is capable of moving heat at high power densities, using revolutionary coherent porous silicon (CPS) wicks. The CPS wicks minimize packaging thermal mismatch stress and improves strength-to-weight ratio. Also burst-through pressures can be controlled as the diameter of the coherent pores can be controlled on a sub-micron scale. The two phase planar operation provides extremely low specific thermal resistance (20-60 w/cm2).

Abstract: A heat sink device for a display card includes a heat sink, the heat sink having a base and a plurality of heat-dissipating fins on the base, the base having two hooks respectively beside two lateral sides of the groove; a heat-dissipating fan, having a blade wheel and a power wire for the blade wheel, the blade wheel being on the base and the power wire being inside the groove of the base; and a fastener, having two engagement parts respectively corresponding to the hooks, wherein the fastener covers the groove so as to position the power wire by means of engagement of the hooks with the engagement parts. Therefore, the power wire of the heat-dissipating fan can be properly arranged on the heat sink.

Abstract: In one embodiment, the present invention includes a semiconductor package having a plurality of fan blades embedded within a first surface of the package, where a first group of the fan blades extend from a first side of the package and a second group of the fan blades extend from a second side of semiconductor package. The fan blades may be powered by piezoelectric devices to cause motion of the fan blades. Other embodiments are described and claimed.

Abstract: Provides semiconductor devices and method for fabricating devices having a high thermal dissipation efficiency. An example device comprises a thermally conducting structure attached to a surface of the semiconductor device via soldering. The thermally conducting structure is essentially formed of a thermally conducting material and comprises an array of freestanding fins, studs or frames, or a grid of connected fins. A process for fabricating such a semiconductor device includes forming a thermally conducting structure on a carrier and attaching the thermally conducting structure formed on the carrier to a surface of the semiconductor device via soldering.

Abstract: A heat dissipation device includes a heat sink and an LED module attached to the heat sink. The heat sink includes a base and a plurality of fins mounted on the base. A plurality of channels is defined between the fins of the heat sink and slits are defined in two opposite side edges of the base. The slits extend through the base and corresponding fins and cross with corresponding channels. A plurality of grooves is defined in the fins opposite to the LED module. Each of the grooves interconnects corresponding two aligned slits.

Abstract: A heat dissipation device adapted for dissipating heat from a heat-generating electronic element, includes a plurality of fins assembled together. Each of the fins has a rectangular body and four arch-shaped flanges extending from edges of the body to form four round corners in four corners of the body. Each main body of the fins defines a plurality of locking members thereon to engage with corresponding locking members of a corresponding front fin. The arch-shaped flanges in four respective corners of the fins cooperate with each other to form four arced faces in four corners of the assembled fins along an entire length of the assembled fins.

Abstract: Electrode plates acting as a heat sink are arranged to sandwich a power transistor and a diode. Electrode plates at their surfaces opposite cooling elements at a portion opposite power transistor and diode are formed to be smaller in thickness at a portion adjacent to power transistor and diode substantially at the center than at a periphery. Cooling elements are disposed geometrically along electrode plates to sandwich electrode plates.

Abstract: A heat sink includes a generally rectangular flat base, a plurality of fins provided on the surface of the base in parallel to each other, a protrusion provided on the surface of the base along substantially the overall width of the base in the transverse direction to the fins. The fins become gradually shorter on one end side of the base. The ends of the fins are arranged on an oblique line with respect to a line perpendicular to the fins.

Abstract: A semiconductor substrate having metal oxide semiconductor (MOS) devices, such as an integrated circuit die, is mechanically coupled to a stress structure to apply a stress that improves the performance of at least a portion of the MOS devices on the die.

Abstract: A LED projector light module comprising a main body, a LED unit, a heat-radiating unit, a voltage conversion unit and a base is disclosed. The main body is made of metallic material with good thermal conductivity (e.g. copper) and contains a space for accommodating the LED unit. The LED unit and the voltage conversion unit are electrically connected. The voltage conversion unit is configured inside the base. The base is connectable to the main body. The bottom surface of base is disposed with an electrically conductive pin that matches the projector socket. The electrically conductive pin is electrically connected to the voltage conversion unit at one end.

Abstract: A light assembly includes a heat-dissipating device, a light-emitting device, and a reflector. The heat-dissipating device defines an accommodating space. The light-emitting device is disposed in the accommodating space. The reflector serves to reflect light emitted by the light-emitting device, extends into the accommodating space, and surrounds the light-emitting device.

Abstract: A power semiconductor module includes: a power semiconductor device; a first heat dissipation plate; a second heat dissipation plate; a first channel; a second channel; a first channel wall; a second channel wall; a first refrigerant outlet provided on the first channel wall in a position corresponding to the power semiconductor device; a second refrigerant outlet provided on the second channel wall in a position corresponding to the power semiconductor device; first pin fins provided on at least one of the first heat dissipation plate and the second heat dissipation plate so as to be arranged radially around at least one of the first refrigerant outlet and the second refrigerant outlet; and second pin fins arranged in a staggered manner or in a tessellated manner around the first pin fins that are arranged radially.

Abstract: The invention discloses an encapsulation comprising a metal substrate, a PCB on the metal substrate, a thermo-electric element in and/or on the PCB, and an LED on the thermo-electric element. Encapsulating methods are also provided by the invention.

Abstract: The present invention provides an integrated circuit and method of manufacture therefore. The integrated circuit, in one embodiment, includes heat conducting elements located proximate a plurality of heat generating components located over a substrate. The integrated circuit may further include a heat radiating element comprising one or more fins in thermal communication and physical contact with the heat conducting elements, the heat radiating element configured to dissipate heat generated by the heat generating components away from the integrated circuit.

Abstract: Disclosed herein is a cooling fin, which is excellent in cooling performance and is simply manufactured, a package substrate comprising the cooling fin, and a manufacturing method thereof. Fireable paste containing a carbon component is applied into grooves of a mold, thus forming a cooling fin having a pattern corresponding to the grooves. Thus, it enables the production of cooling fins having various configurations, thus improving a cooling performance of a package substrate incorporating the cooling fin.

Abstract: A semiconductor device includes an insulating substrate; at least one semiconductor element mounted on a first principal surface of the insulating substrate; and a heat radiator joined through a solder member to a second principal surface of the insulating substrate opposite to the first principal surface on which the semiconductor element is mounted. The solder member contains at least tin and antimony, and the antimony content of the solder member is in a range of from 7% by weight to 15% by weight, both inclusively. Thus, reliability of the semiconductor device is improved.

Abstract: A heat sink for dissipating a heat from an object includes a plurality of fins. The fins are arranged radially about a center axis to be spaced away from one another, and extend outward in a radial direction substantially perpendicular to the center axis. Each fin is branched at at least two different positions in the radial direction into at least three fin end portions spaced away from one another.

Abstract: A circuit element having a heat-conducting body having top and bottom surfaces, and a die having an electronic circuit thereon is disclosed. The die includes first and second contact points for powering the electronic circuit. The die is in thermal contact with the heat-conducting body, the die having a bottom surface that is smaller than the top surface of the heat-conducting body. The first contact point on the die is connected to a first trace bonded to the top surface of the heat-conducting body. An encapsulating cap covers the die. The first trace has a first portion that extends outside of the encapsulating cap and a second portion that is covered by the encapsulating cap. The heat-conducting body is preferably constructed from copper or aluminum and includes a cavity having an opening on the first surface in which the die is mounted. The die preferably includes a light-emitting device.

Abstract: A heat sink comprising: a heat dissipating portion comprising a plurality of metal fins each having a heat receiving portion and a heat dissipating portion having elasticity; a fin fixing member to transfix said plurality of metal fins; a metal plate having a plurality of slits into which said respective heat dissipating portions are inserted and press-connected thereto with use of said elasticity; and a joining portion to join said metal plate and said heat dissipating portions which are inserted into said respective slits and fixed thereto.

Abstract: A heat sink assembly (10) compatible with an ATX motherboard (20) and a BTX motherboard (30), includes a heat sink and a plurality of fasteners (15) extending through the heat sink. The heat sink includes a base (12) defining a slot (1220) therein. The fastener is capable of sliding along the slot between a first position to a second position to make the heat sink assembly in accordance with the preferred embodiment of the present invention to be adapted for use with the ATX motherboard or the BTX motherboard.

Abstract: A heat dissipation device includes a heat sink, a fan and a fan holder locking the fan on the heat sink. The heat sink defines two slots in two opposite lateral sides thereof. The fan holder includes two opposite first beams and another two opposite second beams. Each of the first beams has a latching leg extending downwardly therefrom and two locking tabs extending upwardly therefrom. The two latching legs are engaged into the two slots of the heat sink. The locking tabs are fastened to two lateral sides of the fan.

Abstract: A compound heat sink for the removal of thermal energy useful for, inter alia, electronic devices or other components. The compound heat sink includes a die cast base element; an extruded dissipation element having a thermal conductivity of at least about 150 W/m-K; and a thermal connection material positioned between and in thermal contact with each of the base element and the dissipation element, wherein the thermal connection material having an in-plane thermal conductivity greater than the thermal conductivity of the dissipation element.

Abstract: A heat exchanger comprises at least one first fluid passage contiguous with at least one second fluid passage. The first fluid passage is separated from the second fluid passage by a common boundary, the boundary having a first surface and a second surface. The first surface is described by a plurality of curvilinear surfaces joined at the ends thereof into a sinuous curvilinear surface and the second surface is described by a plurality of curvilinear surfaces joined at the ends thereof into a sinuous curvilinear surface. The curvilinear surfaces of the first and the second curvilinear surfaces are defined by a portion of an inverse square curve.

Abstract: A heat dissipation device includes a heat sink (10) for contacting a heat-generating component and a fan (20) mounted to the heat sink. The fan includes a frame (22) and a motor (24) received in the frame. The fan has an intake. The frame has a top level and a bottom level. An airflow is generated by the fan and flows through the heat sink. An anti-backflow plate (30) is mounted between the top level and the bottom level of the fan. The anti-backflow plate extends outwardly and beyond an extremity of the heat sink to prevent the airflow flowing through the heat sink from entering the intake of the fan.

Abstract: A microelectronic assembly is provided, having thermoelectric elements formed on a die so as to pump heat away from the die when current flows through the thermoelectric elements. In one embodiment, the thermoelectric elements are integrated between conductive interconnection elements on an active side of the die. In another embodiment, the thermoelectric elements are on a backside of the die and electrically connected to a carrier substrate on a front side of the die. In a further embodiment, the thermoelectric elements are formed on a secondary substrate and transferred to the die.

Abstract: A heat dissipating device includes a heat sink, and an adjusting member. The heat sink includes a base, and a plurality of fins formed on a top surface of the base. The adjusting member includes a mounting portion mounted to a side surface facing an airflow-generating source of the base, a first air-blocking portion connected to an upper portion of the mounting part, and a second air-blocking portion connected to a lower portion of the mounting part. Positions of the first air-blocking portion and the second air-blocking portion relative to the base are adjustable for adjusting distribution of an airflow on top and bottom sides of the base when the airflow flows through the heat dissipating device.

Abstract: An electronic apparatus includes a case, a fan, a plurality of electronic parts, and a heat sink mounted for each electronic part. The heat sink includes a fluid unit, and a shutter plate controlling the quantity of air flowing in the heat sink through an action of the fluid unit actuated by heat of the electronic part. The fluid unit includes a container with liquid. The container is heated from the electronic part. When generated heat of the electronic part is large, the fluid inside the container expands, allowing the shutter plate to operate in an opening direction increasing the quantity of air flowing in the heat sink, and in a case when a generated heat quantity of the electronic part is small, the fluid inside the container shrinks, allowing the shutter plate to operate in a closing direction reducing the quantity of air flowing in the heat sink.

Abstract: An exemplary light source module includes a printed circuit board (PCB), a heat-dissipating assembly, and a number of light emitting elements. The PCB includes a first surface, an opposite second surface, and a number of through holes. The heat-dissipating assembly is located adjacent to the second surface and includes a base, a number of heat-conducting elements, and a number of heat dissipation fins. The base includes a third surface defining a number of cavities therein and an opposite fourth surface. The heat dissipation fins extend from the fourth surface. Each of the heat-conducting elements is inlaid in a corresponding cavity. Each of the light emitting elements is placed in a corresponding through hole and thermally contacts a corresponding heat-conducting element. Each light emitting element electrically connects with the PCB and defines a respective light emitting surface located outside the corresponding through hole.

Abstract: A chip scale package has a semiconductor MOSFET die which has a top electrode surface covered with a layer of a photosensitive liquid epoxy which is photolithographically patterned to expose portions of the electrode surface and to act as a passivation layer and as a solder mask. A solderable contact layer is then formed over the passivation layer. The individual die are mounted drain side down in a metal clip or can with the drain electrode disposed coplanar with a flange extending from the can bottom. The metal clip or drain clip has a plurality, a parallel spaced fins extending from its outwardly facing surface.

Abstract: In the semiconductor device, a control power MOSFET chip 2 is disposed on the input-side plate-like lead 5, and the drain terminal DT1 is formed on the rear surface of the chip 2, and the source terminal ST1 and gate terminal GT1 are formed on the principal surface of the chip 2, and the source terminal ST1 is connected to the plate-like lead for source 12. Furthermore, a synchronous power MOSFET chip 3 is disposed on the output-side plate-like lead 6, and the drain terminal DT2 is formed on the rear surface of the chip 3 and the output-side plate-like lead 6 is connected to the drain terminal DT2. Furthermore, source terminal ST2 and gate terminal GT2 are formed on the principal surface of the synchronous power MOSFET chip 3, and the source terminal ST2 is connected to the plate-like lead for source 13. The plate-like leads for source 12 and 13 are exposed, and therefore, it is possible to increase the heat dissipation capability of the MCM 1.