Abstract: A heat sink assembly includes a heat sink main body and a contact member attached to a base of the heat sink main body. The contact member includes a container with thermal grease contained therein and a movable cover movably attached to the container. The container includes a bottom plate configured to contact a heat generating component, and a plurality of holes defined in the bottom plate. When the heat sink is attached to the heat generating component, the movable cover is pressed towards the container and impels the thermal grease out from the holes to spread the thermal grease between the bottom plate of the container and the heat generating component.

Abstract: A package structure includes a substrate; a die over and flip bonded on the substrate; a heat sink over the die; and one or more spacer separating the heat sink from the substrate.

Abstract: A heat spreader is provided for use with a memory module. The memory module has at least a first side with a first plurality of integrated circuits thereon. The heat spreader includes a first segment mountable on the memory module to be in thermal communication with a plurality of integrated circuits on the first side, and to be substantially thermally isolated from at least one integrated circuit on the first side. The heat spreader further includes a second segment mountable on the memory module to be in thermal communication with the at least one integrated circuit on the first side that is substantially thermally isolated from the first segment.

Abstract: An electronic device comprises a semiconductor device having a package substrate with bumps. The semiconductor device is bonded to a mounting substrate by flip-chip bonding. A standoff member supports the package substrate on the mounting substrate with a predetermined standoff between the package substrate and the mounting substrate. The standoff member comprises a hole provided in the mounting substrate, an insertion portion provided to be contained in the hole, and a standoff portion provided to contact and support the package substrate such that the standoff portion has a height, equivalent to the predetermined standoff, on the mounting substrate and enables relative displacement of the package substrate to the mounting substrate.

Abstract: A thermal management configuration for a flip chip semiconductor device is disclosed. The device includes a high power silicon based die having a metal bonding surface. A plurality of interconnects are formed on the metal surface and connected to a substrate. A plurality of thermal management stud bumps are formed on the metal bonding surface, the thermal management stud bumps positioned distinct from the interconnects and local to die hot spots, exposed ends of the thermal management stud bumps spaced from the substrate.

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: In one embodiment the present invention includes a semiconductor power device. The semiconductor power device includes a single gauge lead frame, a semiconductor die, and a heat sink. The semiconductor die is attached to a first level of the lead frame. The heat sink is attached to a second level of the lead frame. A molding compound encapsulates the semiconductor die and a portion of the lead frame, such that a portion of the heat sink is outside of the molding compound. The resulting device may be efficiently manufactured as compared to dual gauge lead frame devices or devices where the semiconductor die is not attached to the lead frame.

Abstract: According to an aspect of the present invention, there is provided an electronic device including: a substrate board; a semiconductor device mounted on the substrate board; a heat sink configured to radiate heat from the semiconductor device; a first conductive portion provided on the substrate board; and a second conductive portion provided on the substrate board, the second conductive portion separated from the first conductive portion by a discharge gap, wherein: the heat sink is electrically connected to the first conductive portion; and the second conductive portion is grounded.

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: A fastening apparatus for fastening a first device to a second device is disclosed. The apparatus comprises a standoff member disposed through a through hole of the first device; a clamp member having a clamp portion for clamping the standoff member; a sleeve member having a hollow body and enclosing the clamp member, wherein the clamp member is compressed in the hollow body; a resilient member wrapping around the sleeve member; a rotatable cam member pivotly coupled to the clamp member; and a cap member arranged between the rotatable cam member and the resilient member, wherein the rotatable cam member is rotated to a first location to compress the resilient member for causing a first preload force exerted on the second device.

Abstract: A semiconductor device comprising a semiconductor module that has a joint surface, a first fitting portion and a second fitting portion provided on the joint surface, the second fitting portion having a shape different from the first fitting portion; and a radiating fin that has a joint surface, a third fitting portion and a fourth fitting portion provided on the joint surface, the fourth fitting portion having a shape different from the third fitting portion; the semiconductor module is bonded to the radiating fin so that the first fitting portion is fitting into the third fitting portion or the third fitting portion is fitting into the first fitting portion, and the second fitting portion is fitting into the fourth fitting portion or the fourth fitting portion is fitting into the second fitting portion.

Abstract: An apparatus is disclosed. The apparatus includes a processor having a major surface, where the processor generates heat when energized. It also includes a heat dissipation plate comprising a thermally conductive material, and includes a first portion with flat opposing surfaces and a second portion substantially perpendicular to the first portion. The heat dissipation plate is adapted to dissipate heat from the processor. It also includes an array of pins, where the pins in the array of pins are substantially perpendicular to the flat opposing surfaces of the heat dissipation plate, and a heat dissipating material contacting the heat dissipation plate and the major surface of the processor. The heat dissipating material does not contact the second portion of the heat dissipating plate, and the pins are configured to be received in a socket assembly on a circuit board.

Abstract: A heat sink assembly is mounted on a printed circuit board to dissipate heat generated by an electronic component. The heat sink assembly includes a heat sink and a plurality of fasteners fixing the heat sink to the printed circuit board. The fastener includes a head, a post extending downwardly from the head through the heat sink, an elastic member encircling the post and compressed between the head and the heat sink, and an engaging member fixed to the printed circuit board. A top of the engaging member is fastened to a bottom of the post. When the post, together with the head, is rotated relative to an axis thereof toward a locked position, the post would be driven by the engaging member to automatically lock with the engaging member at the locked position.

Abstract: A semiconductor package module having a heat dissipation device includes one or more semiconductor packages with each semiconductor package having semiconductor chips and solder balls connected to the semiconductor chips. A printed circuit board is electrically connected to each of the semiconductor packages. The heat dissipation device dissipates heat generated within the semiconductor package module and includes a fastening member having a fastening body. The fastening member is placed in the space between the semiconductor chips and the printed circuit board, which occurs due to the presence of the solder balls. A coupling groove is defined in an upper surface of the fastening body, and a heat dissipation member covers the semiconductor packages. A through-hole is defined in the heat dissipation member at a position corresponding to the coupling groove, and a coupling member is disposed within the through-hole and is coupled to the coupling groove.

Abstract: An electronic device having an electrical circuit carrier and a body is specified, in which at least one riveted connection is formed between the electrical circuit carrier and the body. In the case of such a device, the electrical circuit carrier can be mechanically incorporated in a stable manner and with little technical complexity. An electrical circuit carrier having at least one rivet is also specified.

Abstract: A printed circuit board employing a heat sink retaining apparatus and method of use is disclosed. In one form of the disclosure, a heat sink apparatus can include a heat sink operable to be coupled to a first portion of a printed circuit board having an integrated circuit, and a retaining mechanism operably coupled along a first surface of the heat sink. The retaining mechanism can be coupled to a second portion of the printed circuit board to produce a tension between the first surface of the heat sink and the second portion of the printed circuit board.

Abstract: Disclosed is an attachment apparatus. The attachment apparatus may facilitate attachment of various components to a printed circuit board (PCB) including a thermal management component.

Abstract: A circuit module includes: a thermally conductive board forming a part of a housing; a circuit board disposed above the thermally conductive board; a semiconductor chip connected to a plurality of electrode pads on a upper surface of the circuit board through solder; a heat sink connected to a upper surface of the semiconductor chip; a thermally conductive member thermally connecting the thermally conductive board to the semiconductor chip; and a plurality of fasteners passing through the thickness of the circuit board in an area surrounding the semiconductor chip to attach the heat sink to the thermally conductive board.

Abstract: A power semiconductor module comprising: a power semiconductor element; a case for receiving the power semiconductor element; a control terminal which is connected to a control electrode of the power semiconductor element, the control terminal is installed in a state of protruding from an upper surface of the case; and a conductive spring which is inserted into the control terminal so that an inner surface of the spring makes contact with at least a part of the side surface of the control terminal, the conductive spring is electrically connected to a printed substrate placed as opposed to the upper surface of the case by making pressurization contact with the printed substrate.

Abstract: A structure for mounting a heat-generating component includes a circuit board on which a heat-generating component is mounted, a base on which the circuit board is disposed upright, a cover having thermal conductivity, a heat-conductive member electrically isolated from the heat-generating component and a heat transfer plate. The heat transfer plate is attached to the circuit board so as to extend in the sliding direction of the cover to cover a surface of the heat-conductive member. The cover presses the heat transfer plate by an inner surface thereof against the heat-conductive member in a direction perpendicular to the heat-conductive member so that the heat-generating component is thermally connected to the inner surface of the cover through the heat-conductive member and the heat transfer plate.

Abstract: A thermal module includes a heat sink disposed on a contact surface of the heat source, a mounting bracket having first and second ends, a fastening member, a pressing member, and at least one clip. The mounting bracket surrounds the heat source. The first end has at least one latch portion. The second end has at least one mounting slot and at least one first opening in communication with the mounting slot. The fastening member is slidably mounted in the mounting slot. The clip spans the heat sink and has two ends respectively engaged with the latch portion and a portion of the fastening member respectively. The pressing member includes a pressing tightly engaged with the clip and urges the heat sink when an operation portion of the pressing member is rotated from the first predetermined position to the second predetermined position.

Abstract: An electrical configuration having at least one component which has at least one current bar, particularly a lead frame, and having an electronic circuit which has at least one heat dissipation surface and at least one electric terminal that is connected mechanically and electrically to the current bar. It is provided that the unit made up of the component and the electronic circuit is mounted on a support layer that effects the heat dissipation in such a way that, because of the fastening of the component onto the support layer, the heat dissipation surface is pushed against the support layer, based on the spring property of the current bar.

Abstract: An apparatus and method for supporting a plurality of components, at least one of which is a heat-generating electrical device such as a power semiconductor device, are disclosed. In some embodiments, the apparatus includes a first structure having a first surface on one side of the structure configured for interfacing a first of the plurality of components and a second surface on another side of the structure, and also includes a second structure capable of receiving the first structure, where one of the second surface and an additional surface of the second structure includes a tip that is in contact with the other of those surfaces. The apparatus further includes at least one component configured to assist in retaining the first and second structures relative to one another, where notwithstanding the at least one component the first structure is capable of pivoting relative to the second structure about the tip.

Abstract: A securing device includes a securing member defining a securing hole, and a fastener. The fastener includes a spring, and a bolt having a main portion, a bottom fixing portion, and a top head portion. The securing hole includes an inner portion and an outer portion extending horizontally from the inner portion to an outside. A width of the outer portion is smaller than the fixing portion and larger than the main portion. The main portion enters into the inner portion through the outer portion. The fixing portion abuts against a bottom of the securing member. The spring is compressed between a top of the securing member and the head portion. A concave is depressed from the securing member and surrounds the inner portion. A lower portion of the spring is fittingly received in the concave.

Abstract: A heat dissipation device for removing heat from an electronic component mounted on a printed circuit board, includes a heat sink having a bottom for in contact with the electronic component and a plurality of fasteners securing the heat sink onto the printed circuit board. Each fastener includes a first latching member, a second latching member rotatably connected to the first latching member and an operating member rotatably connected to the first latching member and having a pressing part engaging a curved portion defined on a top of the second latching member. The heat sink and the printed circuit board are located between the first and second latching members of each fastener. The operating member is rotated to force the first and the second latching members to rotate toward each other to closely clip the heat sink and printed circuit board together.

Abstract: A semiconductor die package includes: an assembly including a semiconductor die, a clip structure attached to an upper surface of the semiconductor die, and a heat sink attached to an upper surface of the clip structure; and a molding material partially encapsulating the assembly, wherein an upper surface of the heat sink is exposed through the molding material.

Abstract: A heat dissipating apparatus includes a base, a heat sink received in the base, and a retaining cover attached to the base. The retaining cover defines two crossing slots for cooperatively forming at least one flap. Each free portion of flap has a free portion. The free portion of each flap elastically curves towards the heat sink to bias the heat sink towards the base.

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 semiconductor device (1) has a semiconductor component (2), a first electrode (6) and a control electrode (7) being arranged on the top side (4). The semiconductor device (1) furthermore has a circuit carrier (3) having a chip island (9) and a plurality of flat conductors (10). The rear side (5) of the semiconductor component (2) is mounted on the chip island (9). The first electrode (6) is electrically connected to a first flat conductor (13) via a first contact clip (16) and the control electrode (7) is electrically connected to a control flat conductor (14) via the second contact clip (19). The upper surface (33) of the first contact clip (16) is at least partly arranged in a plane which is further away from the top side (4) of the semiconductor component (2) than the entire upper surface (34) of the second contact clip (19).

Abstract: An assembly for clamping electrical components against a heat-dissipating surface of a heat sink may include the heat sink, one or more electrical components, two or more springs, and a fastener. Each of the springs may include a first surface, and a second surface opposite the first surface. The second surface of each of the springs may include an attachment region and two contact regions. The attachment region may be between the two contact regions. The second surface of one of the springs may overlap the first surface of another one of the springs. Each of the springs may be positioned to hold the electrical components against the heat dissipating surface of the heat sink. Each of the two contact regions of each of the springs may be positioned to hold the electronic components against the heat-dissipating surface. The fastener may couple the springs together in the attachment region of each of the springs and may further couple the springs to the heat sink.

Abstract: A heat sink assembly includes a heat sink and a clip assembly. The clip assembly includes a clip and a pair of movable fasteners pivotally connected to the clip. The clip includes a main body, two pressing portions extending from two opposite ends of the main body and two locking arms extending oppositely from the two pressing portions, respectively. The movable fasteners each include a main body, a pair of receiving portions curved upwardly from the main body and receiving a corresponding locking arm therein and a hook extending downwardly from the main body and engaging with a clasp on a printed circuit board. A distance from each of the hooks of the movable fasteners to a corresponding clasp can be adjustable via rotation of the movable fasteners around the locking arms of the clip.

Abstract: A heat sink assembly includes a heat sink and a clip for mounting the heat sink to an electronic component of a printed circuit board. The heat sink includes a base and a plurality of fins extending from the base. The clip includes a pressing member and a pair of elongated arms formed on opposite ends of the pressing member. The pressing member has a lower portion protruding toward the base of the heat sink. A middle one of the fins extends upwardly through the pressing member in a manner such that the lower portion of the pressing member resiliently abuts against the heat sink. The two arms are located on opposite lateral sides of the heat sink and bent downwardly to engage with the printed circuit board so that the pressing member exerts a force on the heat sink toward the electronic component.

Abstract: A power module constructs a pressurizing tool by laminating an elastic member as well as a DC positive-side wiring member and DC negative-side wiring member in which currents flow in opposite directions. The pressurizing tool presses a first fixing tool, and then the first fixing tool presses semiconductor equipment. The semiconductor equipment is fixed to a heat dissipating member with its heat dissipating surface brought into surface contact with side wall surfaces of the heat dissipating member. The power module can enhance heat dissipation between a heat dissipating member and semiconductor equipment, and enables the semiconductor equipment to be fixed to the heat dissipating member without adding other components to the power module.

Abstract: A securing device (30) is used for securing a heat sink (10) to a printed circuit board (40) with a heat-generating electronic component (41) mounted thereon. The securing device includes a V-shaped elongated main body (31), a first locking leg (34), a second locking leg (332) and a resilient member (32). The first locking leg and second locking leg are connected to two opposite ends of the main body respectively for engaging with a retention frame (20) on the printed circuit board. The resilient member includes a planar-shaped supporting plate (321) engaging with a bottom portion of the main body and at least one resilient foot (322) extending downwardly from the supporting plate. The resilient foot deforms to exert a resilient force on the heat sink when the heat sink is assembled to the electronic component by the securing device.

Abstract: An integrated circuit die includes a substrate having a front surface and a back surface, wherein the substrate front surface has electrical circuits formed thereon, and the substrate back surface has a plurality of metal layers formed thereon. The plurality of metal layers comprises at least one layer having a thickness of greater than about ten micrometers. The outermost metal layer may be mechanically and thermally bonded to a package using a die attach layer comprising a thermally conductive reflowable material. The invention advantageously facilitates the dissipation of heat from the integrated circuit die.

Abstract: A power semiconductor module and a method of manufacture thereof includes a lead frame carrying lead having inner and outer lead portions. The outer lead portions, which are connected by soldering to semiconductor chips simultaneously, eliminate the need for using bonding wires. Since no bonding wire is used for connecting the leads and the semiconductor chips, a sufficient current capacity is obtained. The bonding between an insulating circuit board and the semiconductor chips and the bonding between the semiconductor chips and the leads can be made simultaneously in a single step of reflow-soldering. As a result, the mounting time can be shortened and the power semiconductor module can be manufactured more efficiently.

Abstract: In one embodiment a thermal dissipation heat slug sandwich includes a circuit board, a circuit package having an integrated heat slug mounted to an obverse side of the circuit board, and a lower heat sink plate on a reverse side of the circuit board thermally coupled to the heat slug and a housing enclosing the circuit board An upper heat sink plate may be mounted to the obverse side of the circuit board to cover the circuit package. The upper heat sink plate thermally coupled to the lower heat sink plate through the circuit board. An insulating cover may also be provided to redirect radiant heat from the circuit package to the housing.

Abstract: A heat dissipation device includes a heat sink, a retention module and a locking device for securing the heat sink to the retention module. The heat sink includes a base for contacting with a heat-generating component. The retention module includes a bottom wall and a first spring clip secured at one side thereof. The locking device is pivotably connected to the retention module and includes a second spring clip attached thereon. The heat sink rests on the bottom wall of the retention module with an end thereof being pressed by the first spring clip, and an opposite end thereof being pressed by the second spring clip. The locking device can be at a released position where the locking device is pivotable, so that the heat sink is removable from the retention module, and a locked position where the locking device presses the base of the heat sink.

Abstract: A clip includes a body, a moveable fastener and an actuating member. The body includes a pressing part, a flat portion and a latching leg. The movable fastener includes a connecting portion, a pivot axis connected at a top end of the connecting portion and an engaging portion. The connecting portion extends through the flat portion. The actuating member defines a guiding groove therein. The guiding groove angles outward to form a height difference along a longitudinal axis of the actuating member between a topmost end and a bottommost end thereof. The actuating member is above the flat portion and connected to the pivot axis of the moveable fastener. The actuating member is levelly moveable relative to the movable fastener so that the pivot axis can slide along the guiding groove to render the moveable fastener vertically moveable between a locked position and a released position.

Abstract: An apparatus for mounting a plurality of heat sinks onto a circuit board during testing while the circuit board is tested in a fixed manufacturing station. The apparatus has a polygonal shaped frame with a size that is limited to an area on the circuit board which contains a plurality of data processing elements to be cooled. At least four apertures are on the frame, wherein each of the apertures corresponds to a different one of the plurality of data processing elements to be cooled. A slot is positioned on the frame to receive oversized processing elements. At least four pillars extend from the frame and mount into mounting holes provided on the circuit board. The apertures on the frame support the heat sinks above the data processing elements to be cooled. No additional screws, adhesives, clips or other fixing mechanisms are required to secure the heat sinks.

Abstract: A heatsink structure and method for the cooling of closely spaced packaged heat-producing devices, such as dual-in-line memory modules (DIMMs). A folded sheet metal heatsink structure is provided which is constituted of a coined metallic material and which has a large plurality of waffle-shaped ridges extending therefrom constituting additional surface areas which are adapted to enable heat generated by hub chips to pass upwardly and then outwardly through waffle-like ridges and, thus, dissipated to the exterior, thereby imparting an improved degree of cooling to heat-producing components or devices.

Abstract: Methods, apparatus and assemblies for enhancing heat transfer in electronic components using a flexible thermal pillow. The flexible thermal pillow has a thermally conductive material sealed between top and bottom conductive layers, with the bottom layer having a flexible reservoir residing on opposing sides of a central portion of the pillow that has a gap. The pillow may have roughened internal surfaces to increase an internal surface area within the pillow for enhanced heat dissipation. In an electronic assembly, the central portion of the pillow resides between a heat sink and heat-generating component for the thermal coupling there-between. During thermal cycling, the flexible reservoir of the pillow expands to retain thermally conductive material extruded from the gap, and then contracts to force such extruded material back into the gap. An external pressure source may contact the pillow for further forcing the extruded thermally conductive material back into the gap.

Abstract: A thermal module includes a heat sink (20), a heat pipe (10) and a fastening device (100). The heat pipe has a condenser section (14) connected with the heat sink. The fastening device includes a base member (50) for fixing an evaporator section of the heat pipe, a positioning pole (58) disposed on and connected to the base member, and an elastic member (30). The positioning pole includes a neck (580) and a head (582). The elastic member includes an abutting portion (32) defining therein a positioning hole (320), and two locking portions (34) extending from the abutting portion. The neck of the positioning pole is freely and loosely received in the positioning hole of the abutting portion. A maximal outer diameter of the head of the positioning pole exceeds a diameter of the fixing hole.

Abstract: A plurality of disc-shaped substrates carry light emitters and are axially stacked, spaced apart, in a metal housing to dissipate the heat produced by the light emitters. The housing comprises mutually connected elongate planar ribs that abut the light emitters or substrates for thermally connecting the light emitters to the housing. The ribs have shoulders. The substrates are received between the ribs and abut the shoulders. The shoulders are positioned proximate each light emitter in intimate contact with the substrate for efficient heat dissipation.

Abstract: A technique for installing a heatsink in an electronic assembly includes simultaneously applying force to multiple fastener assemblies that each retain a respective fastener in a body of the heatsink. The heatsink is then attached to the electronic assembly by actuating the fasteners while the force is simultaneously applied to the multiple fastener assemblies.

Abstract: A heat dissipation apparatus (10) includes a heat spreader (30), and first and second resilient plates (40, 50) provided at two opposite sides of the heat spreader. The first resilient plate includes a mounting arm (41) and two fixing arms (42) extending from two opposite ends of the mounting arm, respectively. The mounting arm defines a first mounting hole (43) therein, and each of the fixing arms defines a first fixing hole (44) therein. The second resilient plate defines a second mounting hole (53) and two second fixing holes (54) therein. The first resilient plate is fixed on the heat spreader via the first fixing holes. The second resilient plate is fixed on the heat spreader via the second fixing holes. The heat spreader is fixed on a circuit board via the first and the second mounting holes.

Abstract: A power semiconductor module (1) with a housing (2) and at least one semiconductor chip (3, 3?) located in it is devised. At least one semiconductor chip (3, 3?) has a first main electrode side (31) and a second main electrode side (32) opposite the first main electrode side, the first main electrode side (31) making thermal and electrical contact with the first base plate (4, 4?). The first cooling device (6) makes thermal and electrical contact with the side of the first base plate (41) facing away from the first main electrode side. The second main electrode side (32) makes thermal and electrical contact with a second base plate (5, 5?). A second cooling device (7) makes thermal contact with the side of the second base plate (51) facing away from the second main electrode side. The heat sink (65) of the first cooling device is supported against the housing (2).

Abstract: A semiconductor apparatus having improved thermal fatigue life is provided by lowering maximum temperature on jointing members and reducing temperature change. A jointing member is placed between a semiconductor chip and a lead electrode, and a thermal stress relaxation body is arranged between the chip and a support electrode. Jointing members are placed between the thermal stress relaxation body and the chip and between the thermal stress relaxation body and the support electrode. A second thermal stress relaxation body made from a material having a thermal expansion coefficient between the coefficients of the chip and the lead electrode is located between the chip and the lead electrode. The first thermal stress relaxation body is made from a material which has a thermal expansion coefficient in between the coefficients of the chip and the support electrode, and has a thermal conductivity of 50 to 300 W/(m·° C.).

Abstract: A semiconductor switching module includes a power semiconductor element that is embodied in planar technology. In at least one embodiment, the power semiconductor element is provided with a base layer, a copper layer, and at least one power semiconductor chip that is mounted on the copper layer, and another electrically conducting layer which covers at least one load terminal of the power semiconductor chip. According to at least one embodiment of the invention, devices are provided for safely connecting the load terminal to a load circuit. The devices are configured such that a contact area thereof presses in a planar manner onto the electrically conducting layer.

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.