Abstract: An electronics enclosure is provided. The electronics enclosure includes a heat dissipating body comprising: a heat conducting surface, a first flange adjacent to the heat conducting surface, and a first part of a latch mechanism adjacent to the heat conducting surface. The first part of the latch mechanism is adjacent an edge of the heat conducting surface opposite to the first flange, such that a portion of the heat conducting surface is between the first flange and the first part of the latch mechanism. The electronics enclosure also includes a plurality of electronic modules configured to mount to the heat dissipating body.

Abstract: An arrangement and method for placing a frequency converter in a cabinet, wherein the frequency converter is fitted in an instrument cabinet having a frame and walls, wherein the frame (101) of the instrument cabinet is of modular construction, and wherein the frequency converter is integrated in the instrument cabinet to form one or more frequency converter modules, each of which comprises a frame part and electric components in such manner that the electric components of the frequency converter are ready installed in the instrument cabinet frame at least mainly before being brought to the site of utilization.

Abstract: An electric power converter has a main circuit section including a semiconductor module and a cooling device; a control circuit substrate section electrically connected to a signal terminal of the semiconductor module, and having a control circuit; and a power wiring section connected to a main electrode terminal of the semiconductor module. The main circuit section is interposed between the control circuit substrate section and the power wiring section.

Abstract: A baffle has a slot, with the slot positioned between first and second adjacent components when the baffle is installed above the components. A pair of heatsinks are inserted into the slot, with at least one heatsink having a heat dissipating portion that remains above the slot after insertion into the slot. A spring is inserted into the slot between the pair of heatsinks.

Abstract: A semiconductor device includes: a first output unit configured to output a first phase; a second output unit configured to output a second phase different from the first phase, the second output unit being disposed to be stacked on the first output unit; and a controller configured to control the output units.

Abstract: A baffle manages airflow through optionally mounted electronic components by using flexible members formed to extend to empty connectors and flex away from the connectors to accommodate electronic components mounted to the connectors.

Abstract: The main objective of the present invention is a modular outdoor LED power supply disposed inside or outside of an outdoor LED light or an LED device so as to decrease the distance between the power supply and a LED light base for preventing an output power drop from an output of the power supply to the LED light base. One or more than one power supply can be disposed in a groove of a main heat-dissipating outer cover of the power supply according to the actual requirements, so that the production and installation thereof become more convenient. The power supply is characterized by being water-resistant, moisture-proof, dust-proof, antirust and direct heat-dissipating, wherein the water-resistant effect is above the IP 65 standard, and thus the reliability and the lifetime of the power supply are increased.

Abstract: The disclosure describes directly cooling a three-dimensional, direct metallization (DM) layer in a power electronics device. To enable sufficient cooling, coolant flow channels are formed within the ceramic substrate. The direct metallization layer (typically copper) may be bonded to the ceramic substrate, and semiconductor chips (such as IGBT and diodes) may be soldered or sintered onto the direct metallization layer to form a power electronics module. Multiple modules may be attached to cooling headers that provide in-flow and out-flow of coolant through the channels in the ceramic substrate. The modules and cooling header assembly are preferably sized to fit inside the core of a toroidal shaped capacitor.

Abstract: A heat-dissipating mechanism includes a first heat-dissipating device, a first positioning device, a second heat-dissipating device and a second positioning device. The first heat-dissipating device is contacted with a memory module. The first positioning device is disposed on the first heat-dissipating device and includes a protrusion. The second heat-dissipating device is connected with the first heat-dissipating device. The second positioning device has a positioning rail formed in the second heat-dissipating device and corresponding to the protrusion. The second heat-dissipating device is connected with the first heat-dissipating device when the protrusion of the first positioning device is embedded into the positioning rail second positioning device.

Abstract: An electronic device with a cooling system includes an enclosure. A first electronic component and a second electronic component in parallel are received in the enclosure. Air inlets are defined in a front board of the enclosure to receive cool air. A first flow of the cool air passes through a main airflow path to cool the first electronic component and the second electronic component. A second flow of the cool air passes through an auxiliary airflow path to cool the second electronic component. The main airflow path and the auxiliary airflow path are separated by a clapboard. The cool air heated by the first and second electronic components is then exhausted through the air outlets defined in a back board of the enclosure.

Abstract: A power amplification device includes a first power amplification unit having the positions of connectors thereof reversed, a second power amplification unit not having the positions of connectors thereof reversed, and a heat sink having a first flank thereof abutted on the heat radiation surface of the first power amplification unit, and having a second flank abutted on the heat radiation surface of the second power amplification unit. A transmitter using the power amplification device includes a plurality of power amplification devices, a distributor directly coupled to the input connectors of the power amplification devices, and a synthesizer directly coupled to the output connectors of the power amplification devices.

Abstract: A semiconductor device includes: a first output unit configured to output a first phase; a second output unit configured to output a second phase different from the first phase, the second output unit being disposed to be stacked on the first output unit; and a controller configured to control the output units.

Abstract: Embodiments for cooling electronic modules are disclosed. In accordance with at least one embodiment, an electronic module is inserted into a cooling sled that is equipped with a bay. The bay of the cooling sled is equipped with a pair of sides to retain the electronic module. The electronic module contains a working fluid that is sealed inside the module with one or more electronic components. During the operation of the electronic module, the working fluid is vaporized by the heat generated by the one or more electronic components. The electronic module is then cooled via the cooling sled. The cooling of the electronic module condenses the working fluid that is vaporized by the heat generated by the one or more electronic components. The condensed cooling fluid is then returned to the one or more electronic components via a wick structure that is also sealed in the electronic module.

Abstract: A receptacle assembly includes a housing that is configured to hold an electrical module. An energy transfer element, which is held by the housing, is positioned to directly engage the electrical module. The transfer element absorbs thermal energy produced by the electrical module. The receptacle assembly also includes a heat sink that is remotely located from the transfer element. A thermally conductive member extends between the heat sink and the transfer element to convey thermal energy therebetween.

Abstract: Modular soft starters are disclosed having a plurality of soft starter modules with stacked SCRs and heat sinks for accommodating a single phase of a three phase motor, where the modules may be connected serially for starting each phase of a higher voltage motor, and where the modules can be mounted in a cabinet in a variety of different orientations to facilitate optimized cabinet space utilization.

Abstract: A heat sink assembly includes a base frame and a heat sink having a module engagement surface configured to be in thermal communication with an engagement surface of a pluggable module. The heat sink assembly also includes transfer links extending between the heat sink and the base frame. The transfer links are movable to transfer the heat sink with respect to the base frame. The heat sink is movable between a recessed position and an elevated position, wherein the transfer links maintain the heat sink in a predetermined orientation with respect to the engagement surface of the pluggable module as the heat sink is transferred, between the recessed position and the elevated position.

Abstract: An electric power converter has a main circuit section including a semiconductor module and a cooling device; a control circuit substrate section electrically connected to a signal terminal of the semiconductor module, and having a control circuit; and a power wiring section connected to a main electrode terminal of the semiconductor module. The main circuit section is interposed between the control circuit substrate section and the power wiring section.

Abstract: A facility is described that includes one or more enclosures defining an interior space, a plurality of power taps, a plurality of coolant supply taps, and a plurality of coolant return taps. A flow capacity of the supply taps and a flow capacity of the return taps can be approximately equal over a local area of the interior space. The plurality of power taps, the plurality of supply taps, and the plurality of return taps can be divided into a plurality of zones, with taps of each zone are configured to be controllably coupled to a power source or a coolant source independently of the taps of other zones. The taps can be positioned along paths, and paths of the power taps can be spaced from associated proximate paths of supply and return taps by a substantially uniform distance along a substantial length of the first path.

Abstract: According to the storage control device of the present invention, individual cooling passages are formed for each region in the enclosure and the respective cooling passages are formed bent so as to bypass the connection substrate. As a result, the interior of the enclosure is cooled efficiently. The interior of the enclosure is divided in the front-rear direction by the connection substrate. Logic substrates and battery devices are provided on the front side of the connection substrate and logic substrates and power supply devices are provided on the rear side of the connection substrate. The battery devices and power supply devices located on the left and right sides of the enclosure are each cooled by means of individual cooling passages. The logic substrates are cooled by means of different cooling passages.

Abstract: A modular high-density computer system has an infrastructure that includes a framework component forming a plurality of bays and has one or more cooling components. The computer system also has one or more computational components that include a rack assembly and a plurality of servers installed in the rack assembly. Each of the one or more computational components is assembled and shipped to an installation site separately from the infrastructure and then installed within one of the plurality of bays after the infrastructure is installed at the site.

Abstract: A duct work assembly is coupled to an end of an electronics enclosure that houses one or more heat generating devices, such as electronics servers. The duct work assembly includes individual duct guides that each have a deformable end, which is configured to locally deform around the electrical connection lines extending from the rear of one or more electronics servers. The deformable end can be made of bristles, as in a brush, or foam that includes slits and/or holes.

Abstract: A heat dissipation device used for removing heat from a plurality of memory module cards, includes a first bracket, a second bracket placed on the first bracket and a fin set arranged on the second bracket. The first bracket has a plurality of first sheets extending downwardly from a bottom thereof and defines a plurality of slots therein. The second bracket has a plurality of second sheets extending downwardly from a bottom thereof. The first sheets are respectively attached to sides of the memory module cards. The second sheets are respectively extended through the slots of the first bracket and attached to opposite sides of the memory module cards and opposite to the first sheets.

Abstract: A method and apparatus for heat sinking for multiple high power circuit board modules, is provided. One implementation involves providing a compact nested fin integral heat sink assembly for each high power circuit board module, and positioning fin sections on the heat sink assembly such that a plurality of nested fin sections emanate from each board side heat spreader plate of the assembly, thereby providing efficient airflow gap, pressure drop, and heat sink base spreading performance. The fin section can be placed essentially directly over high power components on each board module to minimize spreading resistance in a heat sink base of the assembly. The fin sections on each board module side provide channel depth without extending from an opposite side heat sink base, thereby increasing fin surface area for each local region of fins from either heat sink base.

Abstract: A system including an electronic module with a heat spreader. One embodiment provides a plate including a thermally conductive material and a guiding member arranged along an edge of the plate. The plate and the guiding member of the heat spreader are configured to form, when attached to a first memory module, together with another heat spreader attached to a second memory module or together with a wall of another device, a duct channeling a flow of a coolant.

Abstract: An apparatus comprising a chassis providing a plurality of module bays, one or more modules received in the module bays, wherein each module has at least one damper actuator extending from a distal end of the module. A fan assembly and a plurality of air flow dampers are secured in a distal end of the chassis, wherein each damper is aligned with one module bay to control air flow through the aligned module bay. Each damper is biased to close in the absence of contact with a damper actuator and opens in response to contact with a damper actuator. Each damper opens to a variable extent determined by the profile of the contacting damper actuator. The damper actuator of a particular module has a profile corresponding to the thermal load of that module, such that installing a module into the chassis automatically opens the aligned damper to the desired extent.

Abstract: The present invention provides methods and systems for storage of data. In one aspect, the invention provides a data storage system that includes a plurality of storage devices, such as, disks, for storing data, and a controller that implements a policy for managing distribution of power to the storage devices, which are normally in a power-off mode. In particular, the controller can effect transition of a storage device from a power-off mode to a power-on mode upon receipt of a request for reading data from or writing data to that storage device. The controller further effects transition of a storage device from a power-on mode to a power-off mode if no read/write request is pending for that storage device and a selected time period, e.g., a few minutes, has elapsed since the last read/write request for that storage device. In another aspect, the present invention provides a data storage system that includes a plurality of cooling plates, each with one or more storage devices thermally coupled thereto.

Abstract: A cooling system has at least one heat conducting element in thermal contact with an electronic component. A heat exchanger is in fluid communication with the heat conducting element. The heat exchanger is configured to provide a working fluid to the at least one heat conducting element to facilitate dissipation of heat from the respective electronic component. The heat exchanger has a form factor dimensioned and configured for mounting in a preconfigured hardware unit slot of a computer chassis.

Abstract: An electronic module and chassis/module installation and cooling method are disclosed. The installation comprises a chassis including a metallic heat input region. An electronic module including an electronic component is adapted to be connected to the chassis. An uninterrupted thermal pathway thermally connects the electronic component of the module to the heat input region of the chassis. The thermal pathway comprises a chimney, a heat channel thermally connected to the chimney, and a heat output block thermally connected to the heat channel. A first electrically insulative non-metallic layer thermally couples the chimney to the electronic component. A second electrically insulative non-metallic layer thermally couples the heat output block to the chassis heat input region.

Abstract: An electric power converter has a main circuit section including a semiconductor module and a cooling device; a control circuit substrate section electrically connected to a signal terminal of the semiconductor module, and having a control circuit; and a power wiring section connected to a main electrode terminal of the semiconductor module. The main circuit section is interposed between the control circuit substrate section and the power wiring section.

Abstract: A method of cooling a module attached to a board by a spring mechanism that provides access to the module during testing. A cold plate assembly features a dry thermal interface coupled with spring loaded plunger to ensure a module, such as a dual chip module (DCM), for example, remains in place during individual cold plate removal.

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 heat dissipation apparatus includes a first commponent connector defining a first component slot immediately adjacent the first component connector, wherein the first component connector is located adjacent to and spaced apart from a second component connector that defines a second component slot. A heat dissipating member is thermally coupled to a heat producing component such that the heat dissipating member is located in the second component slot that is defined by the second component connector when the heat producing component is coupled to the first component connector and located in the first component slot. The heat dissipation apparatus may be coupled to a heat producing component and used to dissipate heat from the heat producing component when there are empty component connector slots located adjacent the component connector that the heat producing component is coupled to.

Abstract: A folded heatsink for cooling heat-producing devices. The folded heatsink includes a substantially planar base having a first end and a second end. The base is intended to be affixed in thermal contact to an exposed, substantially planar surface of one or more heat-producing devices. The folded heatsink also includes two shoulders each having a proximal end and a distal end. The proximal ends of the shoulders project substantially at right angles from the first and second ends of the base. The folded heatsink also includes two arms each having a proximal end and a distal end. The proximal ends of the arms project substantially at right angles from the distal ends of the shoulders such that the base, shoulders and arms from a nearly closed rectangular tube formed from a continuous sheet of metal.

Abstract: An inverter type drive unit for feeding AC electric power of variable parameters to an electric motor has an electronic control section, and a power converting and output section which includes one or more identical power modules, each forming a complete 3-phase output stage. The power modules are arranged side-by-side in a multiplying direction and are clamped by retaining devices to a cooling structure. The power modules are connected in parallel to DC input terminals and to AC output terminals via conductive sheets which are insulated from each other. The DC connected conductive sheets cover substantially the entire physical surface area covered by the power modules so as to accomplish an even, simultaneous and low impedance DC current supply to all power modules.

Abstract: According to embodiments of the present invention, an optical transponder module generates heat when operating and a heat pipe disposed in the module body performs active heat transfer from a hot end of the optical transponder module to a cooler end of the optical transponder module. A heat pipe disposed in an external clip-in heat sink may remove heat from the optical transponder body.

Abstract: A redundant power supply system includes a system cabinet, a first power supply apparatus, a second power supply apparatus and a power converting circuit board. The system cabinet at least includes a first receptacle and a second receptacle. The first power supply apparatus has a first connection interface. The second power supply apparatus has a second connection interface. The power converting circuit board is disposed inside the system cabinet and includes a first insertion slot, a second insertion slot and a power converting circuit. A voltage outputted from the first power supply apparatus and/or the second power supply apparatus is converted by the power converting circuit into a regulated voltage when the first connection interface of the first power supply apparatus and the second connection interface of the second power supply apparatus are inserted into the first insertion slot and the second insertion slot, respectively.

Abstract: In a disk array apparatus according to an aspect of the invention, temperatures of disk drives arranged in a casing are equalized to reduce a noise. A disk array apparatus 50 comprises plural disk drives 2, fans 5, and a casing 1. The disk drives 2 are arranged in an array, the fans 5 are provided on one end side of rows of the disk drives, and the casing 1 accommodates the disk drives 2 and the fans 5. Air which has already cooled the disk drives flows through an air duct 10. A sub-fan 6 exhausts the air flowing through the air duct to the outside of the casing 1. A nozzle 11 is arranged in a front end portion of the air duct. One end portion of the nozzle 11 is arranged between the disk drives.

Abstract: A heat-dissipating element with connecting structures comprises at least two opposite stop edges. Each stop edge is formed with at least one connecting structure, and each connecting structure includes a first connecting portion which has a fastener and a fastening hole and a second connecting portion which has a positioning concave portion and a positioning protrusion. The heat-dissipating elements are assuredly assembled with each other through the engagement and fastening connection of the first connecting portion and the second connecting portion.

Abstract: A mechanical set of plates is able to simultaneously and quickly removably secure and remove one or more printed circuit boards (PCBs) in an enclosure in one single motion, and act as a heat sink to conduct heat away from the PCBs. The PCBs are removably secured through a clamping mechanism that may be a screw type or cam lever action by clamping down on the exposed card edges, thus allowing thermal transfer to begin on all cards. The apparatus may be used with any enclosure requiring thermal transfer from PCBs to the enclosure, including cages and enclosures that may or may not use forced airflow (fans or blowers) for heat dissipation.

Abstract: According to one embodiment, a composite module includes a substrate, a first module mounted on the substrate, a second module mounted on the substrate and provided to be independent from the first module, and a heat radiating plate. The heat radiating plate is thermally connected to each of the first module and the second module, and serves to radiate heat from these modules to an outside.

Abstract: An electronic module and chassis/module installation are disclosed. The installation comprises a chassis including a metallic heat input region. An electronic module including an electronic component is adapted to be connected to the chassis. An uninterrupted thermal pathway thermally connects the electronic component of the module to the heat input region of the chassis. The thermal pathway comprises a chimney, a heat channel thermally connected to the chimney, and a heat output block thermally connected to the heat channel. A first electrically insulative non-metallic layer thermally couples the chimney to the electronic component. A second electrically insulative non-metallic layer thermally couples the heat output block to the chassis heat input region.

Abstract: A disk array apparatus comprises a casing, a disk drive group configured by a plurality of disk drives, a controller unit configured by a plurality of circuit substrates, a plurality of cooling fans, and backflow prevention members. The plurality of cooling fans is provided so as to be aligned between the disk drive group and the controller unit in the casing. The backflow prevention members are provided so as to protrude on the side of the disk drive group or on the side of the controller unit from between the cooling fans while extending to define a space on the inlet side or the outlet side of the cooling fans.

Abstract: An improved redundant computing apparatus includes a chassis assembly configured to (i) mount to a standard electronic equipment rack and (ii) consume substantially 1U of space in a particular direction (e.g., vertical height) within the standard electronic equipment rack. The chassis assembly includes a housing and a midplane disposed within the housing. The apparatus further includes a set of power supply/blower assemblies configured to connect to the midplane of the chassis assembly through a front of the housing in a field replaceable manner, and a set of computing devices configured to connect to the midplane of the chassis assembly through a back of the housing in a field replaceable manner. By way of example, the set of computing devices is adapted to move data into and out of a set of disk drives on behalf of a set of external host computers.

Abstract: There is described a module for an automation device with a plurality of adjacent modules, having a housing capsule that has at least one rear wall and two side walls and which is provided for housing electric components. There is also described an automation device having modules of said type. It is proposed that one of the side walls of the modules be embodied as being thermally conductive and that the other side wall be embodied as being thermally insulated. That will on the one hand result in improved heat dissipation for the modules and, on the other, will prevent the thermal coupling of adjacent modules of the automation device.

Abstract: A heat sink device for conventional memory modules, such as DIMMs, that is configured to be positioned between adjacent memory modules mounted in substantially parallel connectors on a printed circuit board. Each heat sink device includes thermally conductive first and second members configured to thermally couple with electronic components of a conventional memory module. The first and second members may be resiliently biased away from one another so that the resilient bias causes the members to abut respective electronic components when placed between adjacent memory modules. A separate wedge, or a lever-mounted wedge, may be provided for insertion between the members to urge them away from one another and into abutting relationship with electronic components on facing surfaces of the adjacent memory modules. When abutting opposing electronic components, a single heat sink device facilitates heat dissipation from both of the adjacent memory modules.

Abstract: In a disk array apparatus according to an aspect of the invention, temperatures of disk drives arranged in a casing are equalized to reduce a noise. A disk array apparatus 50 comprises plural disk drives 2, fans 5, and a casing 1. The disk drives 2 are arranged in an array, the fans 5 are provided on one end side of rows of the disk drives, and the casing 1 accommodates the disk drives 2 and the fans 5. Air which has already cooled the disk drives flows through an air duct 10. A sub-fan 6 exhausts the air flowing through the air duct to the outside of the casing 1. A nozzle 11 is arranged in a front end portion of the air duct. One end portion of the nozzle 11 is arranged between the disk drives.

Abstract: A method and assembly for mounting power electronics modules in an equipment cabinet, cubicle or other like equipment space. According to the invention, the power electronics modules are mounted in the equipment space (1) with the help of mounting bases (3), such that the mounting bases (3) comprise fixture means (13, 14) for fixing the mounting base in the equipment space (1) and a mounting plate (16) fixed supportedly by the fixture means (13, 14) so that the first end of the mounting plate is situated closer to the fixture means (14) of the first end than the opposite end (11) of the mounting plate (3) from the fixture means (13) of this opposite end, whereby the mounting plate (16) becomes aligned in a slanted position in the equipment space.

Abstract: A structure may be coupled to an adapter coupling two or more modules together. In some embodiments, the structure may direct air and/or dissipate heat from the modules into the air. The structures may direct air to components on a module that might receive less airflow without the structures. In some embodiments, the structure may be coupled to the adapter through a fastener (e.g., multiple structures may be manufactured with a plate, and the plate may be coupled to the adapter). In some embodiments, thermally conductive pathways may be used on the modules to conduct heat from components on the modules to a heat dissipating structure on the adapter.

Abstract: A power stack includes cooling pipes and semiconductor modules which are alternately laminated. Each cooling pipe includes an inside space dissected into cooling passages in which coolant flows. Both surfaces of the semiconductor module in a laminating direction are brought into contact with surfaces of neighboring cooling pipes. The semiconductor modules are classified into a plurality of groups mutually differentiated in their heat generation rates. And, any two semiconductor modules belonging to the same group having the highest heat generation rate are spaced from each other so that a cooling pipe is not sandwiched between these semiconductor modules in the laminating direction.

Abstract: A cooling apparatus for an electronics assembly having a substrate and one or more electronics devices includes an enclosure sealably engaging the substrate to form a cavity, with the electronics devices and a heat exchange assembly being disposed within the cavity. The heat exchange assembly defines a primary coolant flow path and a separate, secondary coolant flow path. The primary coolant flow path includes first and second chambers in fluid communication, and the secondary flow path includes a third chamber disposed between the first and second chambers. The heat exchange assembly provides a first thermal conduction path between primary coolant in the first chamber and secondary coolant in the third chamber, and a second thermal conduction path between primary coolant in the second chamber and secondary coolant in the third chamber. The heat exchange assembly further includes coolant nozzles to direct primary coolant towards the electronics devices.