Abstract: This disclosure relates to an apparatus and method 10 for protecting an electronic circuit from an airflow. The apparatus 10 comprises a base 12, wherein said base 12 comprises a cover means for covering at least part of the electronic circuit. The apparatus further comprises a guide means for guiding an airflow around the electronic circuit.

Abstract: A cooling system is operable to facilitate cooling a power module or other electronic assembly. The cooling system may be configured to facilitate cooling a DC/AC inverter or other electronic assembly where two power modules may be arranged in an opposing relationship relative to a coolant passageway. The opposing relationship may be suitable to minimizing a packaging size and footprint required to facilitate interacting both power modules with the coolant flow.

Abstract: The purpose of the present invention is to provide a power semiconductor device which has a light weight, high heat dissipation efficiency, and high rigidity. The power semiconductor device including a base 1, semiconductor circuits 2 which are arranged on the base 1, and a cooling fin 3 which cools each of the semiconductor circuits 2, in which one or more protruding portions 1a, 1b are formed on the base 1, widths of the protruding portions 1a, 1b in a direction parallel to the base 1 surface being longer than a thickness of the base 1, thereby providing power semiconductor devices 100, 200, 300, 400 which have a light weight, high heat dissipation efficiency, and high rigidity.

Abstract: A semiconductor switch insulation protection device and a power supply assembly. Said semiconductor switch protection device comprises a semiconductor switch having a metal component, an insulation component, and a pin installed at a bottom plane of said insulation component, and an insulation protection cover having a body with a second hole and a side belt. A front surface of said metal component is installed on a back surface of said insulation component. A metal portion, with a first hole and having a first height, is extended above an upper plane of said insulation component. Said second hole and said side belt are extended toward a back surface of said body, respectively, to form a hole column having a second height and a sidewall having a third height. Said metal portion is disposed in a groove formed by said back surface of said body, hole column and sidewall.

Abstract: An electronic device is provided that includes a base having a top portion and a bottom portion. The bottom portion may include a first bottom part and a second bottom part. The first bottom part may form a first plane, and the second bottom part may form a second plane, the second plane being non-planar with the first plane. The second bottom part may include an input opening. The top portion of the base may include an output opening. The input opening and the output opening may allow air to flow from behind the electronic device to over the base.

Abstract: A semiconductor control device is provided with: a plurality of semiconductor modules each having a cooling member and a semiconductor element; a circuit board mounted with a control element that controls the plurality of semiconductor modules; and a case in which the plurality of semiconductor modules and the circuit board are respectively mounted. The case is provided with a cylindrical sidewall that forms an internal space within the case, and on both ends of the sidewall, a first opening and a second opening are correspondingly formed to be opposite to each other. The plurality of semiconductor modules include a first semiconductor module mounted on the sidewall on a side of the first opening, and a second semiconductor module mounted on the sidewall on a side of the second opening. The circuit board is positioned between the first semiconductor module and the second semiconductor module, in the internal space.

Abstract: An electronic device, including a circuit board, a communication chip, a first heat sink, a fixer and a shielding mask, is provided. The circuit board has a frame having an opening and several rims surrounding the opening. The communication chip, disposed on the circuit board, is located in the opening of the frame. The first heat sink, disposed on the communication chip, has a first surface facing and contacting the communication chip. The fixer is fixed into the circuit board and the first heat sink, such that the first heat sink remains contacting the communication chip. The shielding mask, disposed on the circuit board, includes a cover and several side boards. The cover covers the communication chip and the first heat sink, such that the cover contacts a second surface of the first heat sink. The side boards are opposite and connected to the rims in parallel.

Abstract: An electrical equipment chassis includes a frame open to a first side and an opposite second side and a power board located near a mid-plane of the chassis coupling power supply modules to first networking modules and a second networking module. A first region open to the first side can receive first power supply modules. A second region open to the first side is adjacent to the first region and can receive the first networking modules and the second networking module oriented with a first orientation. A third region open to the second side can receive fan trays with fans and third networking modules. The third networking modules are oriented orthogonal to the first orientation. The power board at least partially separates the first and third regions and only partially separates the second and third regions. The chassis permits air flow from the first side to the second side.

Abstract: A heat sink assembly includes a base plate coupled to a first side of an electronic device. A plurality of fins extend from the base plate and are positioned within a housing. The housing includes a first manifold defining a plurality of first passages and a second manifold defining a plurality of second passages in fluid communication with the plurality of first passages. At least one of the plurality of first passages extends between an adjacent pair of the plurality of second passages and is oriented to channel fluid toward at least one of the plurality of fins.

Abstract: An electronic device includes a circuit board, a tray abutting a bottom surface of the circuit board, and a heat sink attached to a top surface of the circuit board. The circuit board includes a heat generating chip, and a number of through holes defined in the circuit board. The tray includes a number of clipping members. A number of elastic members are attached to the heat sink. The number of clipping members extend through the number of through holes and engaged with the plurality of elastic members, and the number of elastic members are deformable to disengage from the number of clipping members.

Abstract: A cooling system for a subterranean power line may include a cooling tube configured to house a fluid. Heat generated by the subterranean power line may be radiated and/or conducted to the cooling tube and absorbed by the fluid within the cooling tube. As the fluid heats up, it may change phase from a liquid to a gas. The hot gas may rise to a heat-exchanging condenser configured to dissipate the heat and condense the fluid back into a liquid. The cool, condensed liquid my return from the heat-exchanging condenser to the cooling tube. Risers, gas transport tubes, pressure regulation systems, fluid storage tanks, and other components described herein may increase the efficiency of the cooling system and/or otherwise improve the viability of the cooling system for subterranean power lines.

Abstract: A cooling apparatus is disclosed. The cooling apparatus comprises a first outer portion comprising a fluid inlet and a first exterior cooling surface. A first fluid-diverting structure is in fluid communication with the fluid inlet. A second outer portion comprises a fluid outlet and a second exterior cooling surface. A second fluid-diverting structure is in fluid communication with the fluid outlet. An electrical substrate is coupled to at least one of the first and second exterior cooling surfaces. An intermediate portion is in a facing relationship with the first and second outer portions. The intermediate portion defines an aperture for transferring a fluid between a first cavity and a second cavity. The first cavity is defined between the first outer portion and the intermediate portion. The second cavity is defined between the second outer portion and the intermediate portion. The fluid absorbs heat from the electrical substrate.

Abstract: A thermal management component for a Rechargeable Energy Storage Systems (RESS) assembly and a method of managing the temperature of a RESS battery module using the component are disclosed. The thermal management component comprises (i) a frame having a chamber defined therein; and (ii) a heat exchange plate in mechanical communication with at least a portion of the frame. The method comprises (a) providing a thermal management component as described herein; and (b) circulating at least one heat transfer fluid through said component.

Abstract: An assembly may include at least one duct and at least one distribution box, wherein the distribution box is mounted on the duct in fluid-tight engagement therewith for enclosing a distribution chamber therewith. Also, a method of mounting a distribution box to a duct, at a distribution point that is spaced-apart from duct ends, may include positioning a distribution point duct section in the distribution box, and hermetically sealing a distribution chamber, defined within the distribution box, from an environment of the distribution box.

Abstract: A high voltage electric cable including a cable core, a cooling pipe for cooling the cable core including a polymer and adapted for carrying a cooling fluid, and a cable covering enclosing the cable core and the cooling pipe. The electric cable further includes a heat conducting element surrounding the cable core, and being arranged in thermal contact with the cable core and the cooling pipe.

Abstract: A power module base includes a heat radiation substrate formed of a high-thermal-conduction material, an insulating substrate joined to an upper surface of the heat radiation substrate, a wiring layer provided on an upper surface of the insulating substrate, and a heat radiation fin joined to a lower surface of the heat radiation substrate. A component attachment plate thicker than the heat radiation substrate and including a through hole for accommodating the insulating substrate is joined to the upper surface of the heat radiation substrate such that the insulating substrate is located within the through hole. This power module base can maintain the upper surface of the component attachment plate flat, and various components for a power module, such as a casing, can be attached onto the component attachment plate.

Abstract: An apparatus for cooling a semiconductor element is provided. The apparatus can include an electron emitter configured to emit electrons such that at least some of the emitted electrons become attached to air particulates and an air accelerator configured to generate an electric field that accelerates the air particulates toward the air accelerator to create an air flow over at least a portion of the semiconductor element. The air flow carries heat away from the at least a portion of the semiconductor element.

Abstract: A system for suppressing an overheat condition in an electrical housing includes an electrical housing that defines a housing area including one or more electrical devices; a suppression fluid container containing a suppression fluid; a valve configured to regulate the flow of the suppression fluid from the suppression fluid container to the housing area; at least one sensor configured to sense at least one of temperature and smoke; and a controller communicatively connected to the at least one sensor and the valve, the controller configured to receive signals from the at least one sensor indicating an overheat condition in the housing area; and in response to the received signals indicating the overheat condition in the housing area, control the valve to allow the suppression fluid to flow from the suppression fluid container into the housing area, in order to suppress the overheat condition in the housing area.

Abstract: A heat sink and method for gaseous cooling of superconducting power devices. Heat sink is formed of a solid material of high thermal conductivity and attached to the area needed to be cooled. Two channels are connected to the heat sink to allow an inlet and an outlet for cryogenic gaseous coolant. Inside the hollow heat sink are fins to increase metal surface in contact with the coolant. The coolant enters through the inlet tube, passes through the finned area inside the heat sink and exits through the outlet tube.

Abstract: Cooling apparatuses, cooled electronic modules and methods of fabrication are provided for fluid immersion-cooling of an electronic component(s). The method includes, for instance: securing a housing about an electronic component to be cooled, the housing at least partially surrounding and forming a compartment about the electronic component to be cooled; disposing a fluid within the compartment, wherein the electronic component to be cooled is at least partially immersed within the fluid, and wherein the fluid comprises water; and providing a deionizing structure within the compartment, the deionizing structure comprising deionizing material, the deionizing material ensuring deionization of the fluid within the compartment, wherein the deionizing structure is configured to accommodate boiling of the fluid within the compartment.

Abstract: A system for cooling a heat generating device comprises a heat sink and a plurality of ion emitter elements that form an electrohydrodynamic (EHD) air flow device. The heat sink has a base disposed in thermal communication with a heat generating device, such as a processor. A plurality of heat sink fins is coupled to electrical ground to form ion collectors. Ion emitter elements are disposed in a non-planar pattern along first ends of the plurality of fins so that each ion emitter element is equidistant from the first end of a nearest fin. A power supply applies an electrical potential between the plurality of ion emitter elements and the plurality of fins to induce a flow of ions that cause airflow across the heat sink. It is preferable to have at least three ion emitter elements that are equidistant from each fin of the heat sink.

Abstract: An air conditioning equipment having an in-room unit connected to one end of the refrigerant pipes and an out-room unit connected to the other end of the refrigerant pipes. The air conditioning equipment includes signal coupling portions which are respectively disposed at both end parts of the refrigerant pipes. Each of the signal coupling portions couples an alternating current (AC) control signal to the refrigerant pipes and exhibits a predetermined impedance with respect to an AC electric signal. The configuration of the air conditioning equipment brings forth the advantages that the electrical insulation devices used in the prior art are dispensed with, and the signal transmissions between the in-room unit and the out-room unit can be performed by a simple apparatus configuration.

Abstract: A retaining device for a printed circuit board includes an expandable bladder. The bladder is responsive to a source of pressurized fluid for selectively clamping a printed circuit board within a slot of an associated cooling and/or storage chassis. A method for retaining a circuit card within a chassis includes pressurizing a volume of fluid, and filling an expandable bladder with the pressurized fluid; wherein filling of the bladder causes its expansion and clamps a circuit card within the chassis.

Abstract: A power electronics inverter includes a housing which forms a cold plate with coolant passages. The housing encloses an insulated gate bipolar transistor (IGBT), and a DC Link capacitor. The capacitor comprises a bus-bar which exits from a bottom side of the capacitor, and the bus-bar is positioned adjacent to the cold plate. The cold plate forms a cooling passage which underlies the IGBT and the capacitor bus-bar. Thermally conductive gap pads are located between the capacitor bus-bar and the cold plate.

Abstract: A high power drive stack system is provided which includes a cabinet having a vaporizable dielectric fluid cooling system and a plurality of receivers for accepting a plurality of modules containing power electronics. The modules are removably attachable to the receivers by at least two non-latching, dry-break connectors. Each of the at least two connectors providing both a fluid connection and an electrical connection between the cabinet and the module.

Abstract: According to one embodiment, a display device includes a housing, a circuit board device, a fan, and a wall portion. The housing includes an exhaust port. The circuit board device is housed in the housing. The fan includes an ejection port and is housed in the housing at a position separated from the exhaust port. The fan sends cooling wind to between the circuit board device and the inner surface of the housing. The wall portion is located between the inner surface of the housing and the circuit board device, and constitutes a ventilation path from the ejection port to the exhaust port. The wall portion includes a first member located in the inner surface of the housing and a second member attached to the first member and abutting on the circuit board device. The second member has a rigidity lower than the rigidity of the first member.

Abstract: A line arrangement for transmitting high-power electrical energy and a pressurized fluid, comprising a hose having a hose interior, an electrical conductor, at least one hose-terminating element having a hose-terminating element interior and at least one electrically conductive conductor-terminating element, characterized in that the electrical conductor is at least partially accommodated in the hose interior, that a fluid channel is formed in the hose interior, that the conductor-terminating element is arranged on the electrical conductor at a free end and is fastened in the hose-terminating element interior at a distance from the hose-terminating element, and that insulation means, which circumferentially enclose the electrical conductor and the conductor-terminating element, are provided at least in the transition region between the electrical conductor and the conductor-terminating element.

Abstract: An air conditioning equipment having an in-room unit connected to one end of the refrigerant pipes and an out-room unit connected to the other end of the refrigerant pipes. The air conditioning equipment includes signal coupling portions which are respectively disposed at both end parts of the refrigerant pipes. Each of the signal coupling portions couples an alternating current (AC) control signal to the refrigerant pipes and exhibits a predetermined impedance with respect to an AC electric signal. The configuration of the air conditioning equipment brings forth the advantages that the electrical insulation devices used in the prior art are dispensed with, and the signal transmissions between the in-room unit and the out-room unit can be performed by a simple apparatus configuration.

Abstract: A heat dissipation device is provided in the present disclosure, where the heat dissipation device includes a hollow heat-sink base and a set of fluid tube. The fluid tube is inserted in the heat-sink base, and a cooling medium circulates in the fluid tube. The heat-sink base includes a heat absorption area configured to absorb heat. A cooling fluid, received in the heat-sink base, may be vaporized at the heat absorption area to absorb the heat taken by the heat absorption area, and condensed at a position that is inside the heat-sink base and away from the heat absorption area and on the fluid tube to release the absorbed heat.

Abstract: A power semiconductor system and method for producing a power semiconductor system. In one embodiment, the application relates to a power semiconductor system, comprising a line system for a fluid working medium; wall element having an outer side and an inner side; and a power semiconductor circuit arranged at the outer side of the wall element, wherein the inner side of the wall element forms a fluid-tight wall of the line system.

Abstract: A method of cooling a computer server that includes a plurality of server modules, and is positioned in an enclosed room, includes transferring heat generated by a server module of the plurality of server modules to a hot plate of a liquid cooling system. The liquid cooling system may be positioned within the server module, and the hot plate may have a surface exposed to the enclosed room. The method may also include positioning a cold plate of a room-level cooling system in thermal contact with the hot plate. The method may also include directing a cooling medium through the room-level cooling system to transfer heat from the hot plate to a cooling unit positioned outside the room.

Abstract: The method of the invention makes it possible to cool electrical switchgear operating at medium voltage and high current, such as a circuit breaker. The method consists in inserting serially two heat pipes (11) inside said switchgear, putting a first end (11A) of the first heat pipe (11) in the hot portion of the hot portions (10A, 10C) of the circuit breaker (10) and a second end (11B) of the first heat pipe (11) in a portion that is cooler (10A) of the hot portions (10A, 10C). The other heat pipe (11) is put between the cooler of the hot portions (10A) and a cooler part of the circuit breaker (10). A particular application is provided for medium-voltage, high-current circuit breakers.

Abstract: An electric power conversion apparatus includes first and second electric power conversion devices and a housing. The first and second electric power conversion devices are arranged to overlap each other in an overlap direction. The housing receives both the first and second electric power conversion devices therein. The housing has a partition wall that extends between the first and second electric power conversion devices to partition the housing into first and second parts in which the first and second electric power conversion devices are respectively received. The partition wall has a coolant passage formed therein, thereby allowing a coolant to flow through the coolant passage.

Abstract: An electric power converter for a renewable power source includes at least one alternating current (AC) conduit coupled to an external AC power device and at least one direct current (DC) conduit coupled to an external DC power device. The converter also includes at least one immersion structure defining at least one immersion cavity therein and a plurality of semiconductor devices. The semiconductor devices include a substrate positioned within the immersion cavity. The substrate defines a plurality of heat transfer surfaces thereon. The semiconductor devices also include at least one semiconductor die coupled to the substrate, the AC conduit, and the DC conduit. The converter further includes a liquid at least partially filling the immersion cavity such that the semiconductor die is fully immersed in and in direct contact with the liquid. Heat generated in the semiconductor device induces a phase change in the liquid.

Abstract: A system for cooling a multi-cell power supply, the system including a water pump, a water-to-air heat exchanger in fluid communication with the water pump, and a supply water manifold in fluid connection with the water-to-air-heat exchanger. The system further includes a plurality of power cells in fluid communication with the supply water manifold via one or more water hoses, and a multi-winding device in fluid communication with the plurality of power cells via at least one water-cooled bus, wherein the at least one water cooled bus electrically connects the power cells to secondary windings of the multi-winding device. The water-cooled buses provide both electrical current as well as cooling fluid to each winding of the multi-winding device, thereby eliminating a need for separate cooling and power connections.

Abstract: A heat transferring module adapted to an electronic device is provided. The electronic device includes at least one heat source and a plurality of ready-to-heat elements. The heat transferring module includes at least one water head, at least two loop heat pipes, at least two pumps, and a working fluid. The water head is thermally connected to the heat source. The loop heat pipes are connected to the water head respectively, and at least one of the loop heat pipes is thermally connected to the ready-to-heat elements. Each pump is connected to the corresponding loop heat pipe. The working fluid flows into the water head and at least one of the loop heat pipes by at least one of the pumps, so heat generated by the heat source is transferred to at least one of the ready-to-heat elements. A method of starting up an electronic device is also provided.

Abstract: A board coolant jacket jig system includes a main frame that includes a board installation stand on which a board is installed, and a coolant jacket separation unit that is coupled to the main frame and selectively coupled to the coolant jacket coupled to the board, to separate the coolant jacket.

Abstract: A gas insulated switchgear includes: a center conductor that is arranged to extend horizontally in a tank; a cylindrical member that is arranged in the tank to surround a center conductor, and formed by curving a metal plate-like member into a cylindrical shape and then joining circumferentially opposed both ends of the plate-like member by welding to form a welding portion, the welding portion being located on a lower side of the cylindrical member; and a current transformer for instruments, through which the cylindrical member is inserted, the current transformer being supported by the cylindrical member, and being arranged to surround the center conductor. The welding portion includes a metal spacer sandwiched between the circumferentially opposed both ends of the plate-like member, and the spacer and the ends are welded to each other.

Abstract: A method and apparatus for thermally processing a substrate is provided. In one embodiment, a method for thermally treating a substrate is provided. The method includes transferring a substrate at a first temperature to a substrate support in a chamber, the chamber having a heating source and a cooling source disposed in opposing portions of the chamber, heating the substrate to a second temperature during a first time period while the substrate is disposed on the substrate support, heating the substrate to a third temperature during a second time period while the substrate is disposed on the substrate support, and cooling the substrate in the chamber to a fourth temperature that is substantially equal to the second temperature during the second time period.

Abstract: A system, configured to be disposed in a information technology equipment rack for providing ice thermal storage, includes a tank configured to hold water, a heat exchanger disposed in water in the tank and configured to convey a two-phase liquid and vapor refrigerant and to transfer heat between the water and the refrigerant, a first valve connected to a liquid and a vapor refrigerant line and configured to selectively connect the liquid refrigerant line to a first port and the vapor refrigerant line to a second port in a first mode and to connect the liquid refrigerant line to the second port and the vapor refrigerant line to the first port in a second mode, a thermostatic expansion valve connected to an inlet of the heat exchanger, and a liquid/vapor pump connected to an outlet of the heat exchanger and to the second port of the first valve.

Abstract: Disclosed herein is a semiconductor package. The semiconductor package includes a semiconductor module, a first heat dissipation unit, a second heat dissipation unit and a housing. The semiconductor module contains a semiconductor device. The first heat dissipation unit is provided under the semiconductor module. The first heat dissipation unit includes at least one first pipe through which first cooling water passes. A first rotator is rotatably disposed in the first pipe. The second heat dissipation unit is provided on the semiconductor module. The second heat dissipation unit includes at least one second pipe through which second cooling water passes. A second rotator is rotatably disposed in the second pipe. The housing is provided on opposite sides of the semiconductor module, the first heat dissipation unit and the second heat dissipation unit and supports the semiconductor module, the first heat dissipation unit and the second heat dissipation unit.

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

Abstract: Described embodiments include a device, a method, and a system. A described device includes a closed-cycle heat transfer device. The device includes a hollow member configured to be thermally coupled with and to be disposed substantially parallel to a length of a live transmission line of an overhead power transmission system. The power transmission system is configured to transport electric power from one place to another. The device includes a working fluid contained within the hollow member and tuned to transport heat received from the live transmission line to a heat removal structure. The device includes the heat removal structure configured to dissipate the transported heat.

Abstract: A high-voltage transformer for providing an alternating voltage in the kV range, comprising at least one secondary winding wound on a coil carrying body surrounding a transformer core, and an insulation housing encapsulating the secondary winding is provided to electrically insulate the secondary winding. Said insulation housing is walled by the coil carrying body carrying the secondary winding and by an enveloping body made of plastic and enveloping the secondary winding so that an annular gap is formed, wherein the annular gap between the secondary winding and the enveloping body is filled with an insulating fluid. The annular gap has a gap width of less than or equal to 20 mm viewed in the cross-section, and the enveloping body has a wall thickness of less than or equal to 20 mm, wherein the plastic is polypropylene, and a separate expansion volume is not provided for the insulating fluid.

Abstract: A multi-case rack for an industrial computer includes a rack body and a plurality of removable cases. The removable case can be installed with either its axial end positioned ahead, thus compatible to both a front circuit board and a rear circuit board. The removable case has an anti-shock HD mount capable of holding either two 2.5? hard drives or one 3.5? hard drive. The removable case allows heat-dissipating fans to be installed and positioned in a screw-free, hot-swap manner. The removable cases can be readily installed into or from a rack body.

Abstract: A method, system, and structure are provided for implementing a flex circuit cable and connector with a dual shielded air plenum. A flex circuit cable is provided with a connector. The flex circuit cable includes a stack of three spaced flex cable members with a plurality of gasket separators that are configured to form a pair of air plenums between the inner flex cable member and the respective outer flex cable members carrying cooling air coupled to the connector. The respective outer flex cable members together with the gasket separators provide a shielding function.

Abstract: The invention provides a printed circuit board and a method for fabricating the same. The printed circuit board includes a core substrate having a first surface and an opposite second surface. A first through hole and a second through hole are formed through a portion of the core substrate, respectively from the first surface and second surfaces, wherein the first and second through holes are laminated vertically and connect to each other. A first guide rail and a second guide rail are, respectively, formed through a portion of the core substrate and connected to the second through hole, so that a fluid flows sequentially from an outside of the printed circuit board through the first guide rail, the second through hole and the second guide rail, to the outside of the printed circuit board.

Abstract: Systems and methods for reducing problems and disadvantages associated with traditional approaches to cooling information handling resources are provided. A method for cooling information handling resources, may include conveying a flowing fluid proximate to one or more information handling resources such that the flowing fluid is thermally coupled to the one or more information handling resources and heat generated by the one or more information handling resources is transferred to the flowing fluid. The method may also include conveying the flowing fluid to a cooling unit such that heat is transferred from the flowing fluid.

Abstract: Disclosed is an embodiment of a rack system including a cooled universal hardware platform having a frame, a module insertion area on a first side of the rack system and a universal backplane mounting area on a second side of the rack system opposite to the first side, a power bus, a plurality of cooled partitions, a plurality of module bays, two or more service unit backplanes and a coolant source. The power bus may be configured to provide power to the universal backplane mounting area and the plurality of cooled partitions. The rack system may also include a plurality of service units that may be configured to have different functions within the rack system.

Abstract: A water jacket includes a channel which accommodates MCM and through which a coolant runs, and the channel has a throttle part of which a flow passage sectional area is smaller than other parts and which is at the upstream of the MCM.