Abstract: A solar water heating and cooling system including a solar energy collection assembly having a heat absorbing element, a heat exchanger and a shield. The system also includes a cooling assembly, the cooling assembly is integral with the shield. The system has a check valve in fluid communication with the solar collection assembly and the cooling assembly, and a fluid pump in fluid communication with the solar energy collection assembly. A working fluid is disposed within the solar energy collection assembly, the cooling assembly, the check valve and the fluid pump. A cooling loop is defined by the solar energy collection assembly, the cooling assembly and the check valve. When the fluid pump is off, the working fluid circulates through the cooling loop, but when the fluid pump is on, the working fluid circulates through a heating loop that is defined by the solar energy collection assembly and the fluid pump.

Abstract: A temperature control element for a measuring device for controlling the temperature of a measurement sample, comprising first and second heating elements delivering thermal energy to the measurement sample, and control means for controlling the heating of the measurement sample, wherein the first and second heating elements heat the measurement sample until a limit temperature has been reached, and wherein thermal resistivity between the first and second heating elements is increased starting at the limit temperature, and the control means disconnects the contact between the first and second heating elements when the limit temperature is reached. A cooling element withdraws thermal energy, and the control means controls cooling of the measurement sample, wherein thermal energy is withdrawn from measurement sample by bringing the cooling element closer to the shut-off of the first heating element, and interrupting the contact between the cooling element and the shut-off of the first heating element.

Abstract: Resources Recovery Scheme and Removal to that extent—lost in the direction and furnish with a foundation of knowledge, is a uniform aim. The whole complex of factors, surroundings the Ecological Community who supports Trade with a piece of equipment that automatically controls temperature used to keep the canister hot or cold. Another supplies a mixture formed toward instances of sweeping the beginning of, and the additional flow—that is waste over Public health equality.

Abstract: An air dehumidifier, and a method for dehumidifying, for a frequency converter arrangement including a surface to be cooled, on which humidity condenses when the surface is being cooled and when, at the same time, the inside of the frequency converter cabinet is possibly being heated. The air dehumidifier is positioned inside the frequency converter cabinet and including at least one air/liquid heat exchanger.

Abstract: An incubator is fitted with an enclosure which surrounds the incubator. A cold air generation system supplies relatively cold air to a space formed between enclosure and the incubator. The system supplying the cold air can be embodied in a cart or base upon which the incubator sits. The enclosure is also placed on the base in a manner such that it substantially envelops the incubator. The top of the cart has openings for egress of cold air and return of air so that air may circulate in a closed loop. The incubator, cold air supply system and enclosure present a solution for incubating samples in a nominal 20-25° C. temperature environment. The enclosure, which is preferably insulated, may include a void or opening which exposes doors or other access device of the incubator, allowing direct access to the samples in the incubator while the rest of the incubator is enveloped by the enclosure.

Abstract: Embodiments of substrate supports with temperature control are provided herein. In some embodiments, a substrate support includes a first member to distribute heat to a substrate when present above a first surface of the first member; a heater coupled to the first member and having one or more heating zones to provide heat to the first member; a second member disposed beneath the first member in a spaced apart relation to the first member to at least partially define a gap between the first member and the second member, the second member fixed relative to the first member; and a plate movably disposed in the gap such that a distance between the plate and the first and second members can be selectively controlled. In some embodiments, the position of plate in the gap controls the rate of heat transfer from the first member to the plate.

Abstract: A cooling system for cooling a superconducting device by a low-temperature fluid is provided. A flow generator for producing a flow in the low-temperature fluid is provided in the cooling system. The low-temperature fluid flowing through the superconducting device is heated. The flow generator is used to produce a flow in the heated low-temperature fluid. The low-temperature fluid is cooled and supplied to the superconducting device.

Abstract: Disclosed embodiments include thermoelectric-based thermal management systems and methods configured to heat and/or cool an electrical device. Thermal management systems can include at least one electrical conductor in electrical and thermal communication with a temperature-sensitive region of the electrical device and at least one thermoelectric device in thermal communication with the at least one electrical conductor. Electric power can be directed to the thermoelectric device by the same electrical conductor or an external power supply, causing the thermoelectric device to provide controlled heating and/or cooling to the electrical device via the at least one electrical conductor.

Abstract: The present invention relates to the use of a compound consisting of a linear saturated C8-C24 hydrocarbon-based chain bearing at each end a nitrogen-containing functional group, other than —NH2, for the storage of thermal energy. It also relates to a process for the storage and optionally for the release of thermal energy, comprising the contacting of a wall to be cooled with a first heat transfer fluid then of said first heat transfer fluid with a material comprising said compound and optionally the contacting of said material with a second heat transfer fluid then of said second heat transfer fluid with a wall to be heated.

Abstract: A total evaporator for fluids, including a cold chamber to prevent pre-evaporation, an evaporation region connected thereto having narrow flow cross-section for fast evaporation of the fluid, and a subsequent vapor chamber for pulsation damping and the controlled superheating of the vapor, the evaporation region being formed by a gap between concentrically nested cylindrical and/or conical tube sections and heat required for the evaporation and superheating processes is supplied by electric heating and/or by hot fluid and/or by catalytic or homogeneous combustion via the wall of the concentric tubes.

Abstract: The invention relates to a method for heating/cooling and coating a substrate in a vacuum chamber, comprising the following steps: (1) arranging the lower face of the substrate on a substrate holder, (2) lifting the substrate by a predefined distance relative to the substrate holder, and (3) heating the lifted substrate via its upper face by means of a heating device such as a radiant heating device, (4) coating the hot substrate, for example by moving it in or through a coating zone, (5) cooling the substrate by lowering it onto the chuck and (6) optionally further coating the cold substrate. The method according to the invention further enables process sequences to be executed, wherein various defined temperatures can be set on the substrate during each step, and optionally one or more coating processes can be executed immediately subsequently at said substrate temperature.

Abstract: A temperature control unit for an electronic component and a handler apparatus, which are excellent in responsibility during cooling and heating, is obtained. The temperature control unit for an electronic component includes a cooling cycle device having a refrigerant passage circulating through a compressor, a condenser, an expander, and an evaporator; a thermally conductive block having an outer surface capable of coming in contact with the electronic component that is an object to be temperature-controlled, where an inner surface corresponding to the outer surface is placed opposite to the outer surface so as to be brought in contact with or apart from the evaporator; at least one first heater for heating the thermally conductive block; and a compressed air feeding circuit for feeding compressed air between facing surfaces of the evaporator and the thermally conductive block to part them.

Abstract: Treatment of a layer comprising self-assemblable polymer at a surface of a substrate is disclosed. In an embodiment, the treatment includes arranging a zone of temperature change to sweep across the layer, wherein a temperature of the layer within the zone differs from an initial temperature of the layer prior to passage of the zone.

Abstract: Apparatuses useful in printing, fixing devices and methods of preheating substrates in apparatuses useful in printing are provided. An exemplary embodiment of the apparatuses useful in printing includes a first member including a first surface; a second member including a second surface forming a nip with the first surface; a substrate cooler disposed downstream from the nip to receive a first substrate exiting the nip, the substrate cooler removing heat from the first substrate by conduction; a substrate pre-heater disposed upstream from the nip; and a first heat transfer system for transferring heat from the substrate cooler to the substrate pre-heater. The substrate pre-heater applies the heat to conductively pre-heat a second substrate before the second substrate enters the nip.

Abstract: Methods for cooling process chamber components are provided herein. In some embodiments, a method of cooling a process chamber component may include reducing a power provided to a heater disposed proximate a surface of the process chamber component to reduce an amount of heat provided to the component by the heater; providing a coolant to coolant channels disposed within the process chamber component using a pulsed flow having a duty cycle until the process chamber component reaches a temperature that is less than or equal to a predetermined magnitude above a temperature of the coolant; and after the process chamber component reaches the temperature less than or equal to the predetermined magnitude above a temperature of the coolant, reducing the duty cycle of the pulsed flow of the coolant to zero.

Abstract: A conditioning system for conditioning a part of a lithographic apparatus, includes an evaporator positioned in thermal contact with the part for extracting heat from the part by evaporation of a fluid inside the evaporator; a condenser for removing heat from the fluid inside the condenser; fluid lines arranged between the evaporator and the condenser to form a fluid circuit; a pump arranged in the circuit to circulate the fluid in the circuit; an accumulator to hold fluid, wherein the accumulator is in fluid communication with the circuit and comprises a heat exchanger to transfer heat from or to fluid inside the accumulator; a temperature sensor to provide a signal representative of the fluid temperature; and a controller to maintain a substantially constant temperature of the fluid inside the circuit by regulating the amount of heat transferred by the heat exchanger based on the signal.

Abstract: The invention relates to a device for controlling the climate in a greenhouse, comprising a first heat exchanger (7) with a first series of channels (7a) and a second series of channels (7b), greenhouse supply means (1) leading from the greenhouse to the first series of channels, outside supply means (5) leading from outside to the second series of channels, greenhouse discharge means (4) leading from the device to the greenhouse and outside discharge means (6) leading from the device to the outside, wherein the greenhouse discharge means connect to the first series of channels and the outside discharge means connect to the second series of channels. The air is hereby retained in the greenhouse without supply of new air, while the temperature of the air in the greenhouse can be adjusted while maintaining a separation between greenhouse air and outside air.

Abstract: A modular heating or cooling system includes a heating and/or cooling unit and a plurality of storage modules that may be releasably connected to the heating and/or cooling unit by a releasable coupling. The storage modules may include a heat exchanger having a thermal transfer bladder filled with eutectic fluid. The storage modules may include a hydroelectric generator and/or turbine assembly placed in-line in a circulation line for transporting heated or cooled fluid to and/or from the heat exchanger, the hydroelectric generator and/or turbine assembly operative to drive an electric light or a fan. A base station in the form of a movable cabinet is also disclosed for storing a plurality of the storage modules. The base station includes circulation lines that attach to fluid supply lines from a heating or refrigeration unit and may include terminals with releasable couplings for connecting to the storage modules stored therein.

Abstract: A water transfer apparatus and a wafer transfer method are provided. The wafer transfer apparatus is provided with a heating component and a cooling component, the heating component heats the wafer carrying component to a temperature the same as the wafer when it is just unloaded from the rapid thermal anneal tool, and the cooling component cools the wafer carrying component along with the wafer to room temperature, thereby avoiding the large temperature difference between the wafer and the wafer transfer apparatus, preventing the high thermal stress induced inside the wafer during wafer transfer, avoiding wafer breakage, and ensuring the completeness of the wafer.

Abstract: A temperature controlling unit (X1) includes a holder (11) for a liquid receiver (40), a heating block (12) for heating the liquid in the liquid receiver (40), and a cooling block (13) for cooling the liquid in the liquid receiver (40). The holder (11) maintains a first temperature for keeping the temperature of the liquid in the liquid receiver (40) at a lower target temperature. The heating block (12) maintains a second temperature higher than a higher target temperature above the lower target temperature. The cooling block (13) maintains a third temperature lower than the lower target temperature. A temperature controlling method of the present invention includes a heating step for bringing a heating block (12) into contact with the liquid receiver (40) held by the holder (11) and a cooling step for bringing a cooling block (13) into contact with the liquid receiver (40) held by the holder (11).

Abstract: A unified heat exchanger includes a first heat exchanging arrangement and a second heat exchanging arrangement. The first heat exchanging arrangement is adapted to exchange heat between high pressure refrigerant and conditioning air. The second heat exchanging arrangement is adapted to exchange heat between low pressure refrigerant and the conditioning air. The first heat exchanging arrangement and the second heat exchanging arrangement are integrated together and are arranged to enable heat exchange of the conditioning air with both of the high pressure refrigerant and the low pressure refrigerant.

Abstract: Process for removing heat from at least two reactors forming at least part of a polymerization reactor system for a multimodal polymerization in which the reactors are linked in series and all produce at least one component of the same polymer. The process includes cooling a stream of fluid in one or more heat exchangers and passing part of it to the cooling system of a first reactor and part of it to the cooling system of a second reactor, so as to remove the heat from said reactors, and passing back through the heat exchangers a return flow having a portion of the combined exit flows of the cooling fluids used to remove the heat from each of the reactors. The heat exchangers provide at least 90% of the cooling requirement for the reactors, and a portion of the combined exit flows from the reactors bypasses at least one of the heat exchangers and is passed directly to the cooling system of one or more of the reactors. The cooling circuit is powered by no more than one pump at any one time.

Abstract: A refrigerator-oven combination for an aircraft galley food service system includes a housing with a thermally insulated compartment, a heating device for heating the compartment in a heating mode, and a refrigeration device for cooling the compartment in a refrigeration mode.

Abstract: An air conditioning system includes an air-conditioner casing, an air blower, a cooling heat exchanger, a heating heat exchanger, and a bypass passage. An electric motor of the blower has a rotating shaft that extends along a rotating shaft axis. An impeller of the blower suctions air from one side of the impeller along the rotating shaft axis to blow air in a radial direction of the impeller. The bypass passage causes cold air to bypass the heating heat exchanger. The air blower is located downstream of the cooling heat exchanger and the heating heat exchanger in a flow direction of air. The cooling heat exchanger and the heating heat exchanger are arranged in parallel with each other. The air blower is positioned on an imaginary extension of the heating heat exchanger. The rotating shaft is disposed in parallel with the heating heat exchanger.

Abstract: The present invention provides a vacuum heating/cooling apparatus capable of rapidly heating and also rapidly cooling only a substrate while a high vacuum degree is maintained after film-formation processing. The vacuum heating/cooling apparatus according to an embodiment of the present invention includes a vacuum chamber (1), a halogen lamp (2) which emits heating light, a quartz window (3) for allowing the heating light to enter the vacuum chamber (1), a substrate supporting base (9) having a cooling function, and a lift pin (13) which causes the substrate (5) to stand still at a heating position P3 and a cooling position P1 and moves the substrate (5) between the heating position P3 and the cooling position P1.

Abstract: A first circulation channel connects a first heat demand part and first supply heat exchanger with its forward route and return route. Supply and discharge channels are connected to a first heat accumulation tank, which accommodates a second heat medium heated in the first supply heat exchanger and supplied via the supply channel. A heat accumulation switching valve changes over communication of the second heat medium serving as hot heat or cold heat flowing from the first supply heat exchanger and supplied to the first heat demand part without branching to the supply channel or branching to the supply channel and supplied to the first heat accumulation tank. A heat-accumulating hot-water-supplying air conditioner operates at a first temperature when the second heat medium from the first supply heat exchanger branches to the supply channel, and at a second lower temperature when the second heat medium does not branch to the supply channel.

Abstract: The present invention generally provides a cluster tool for processing a substrate. In one embodiment, the cluster tool comprises at least one processing rack, which comprises a first plurality of substrate processing chambers that are positioned adjacent to each other and aligned in a first direction, a second plurality of substrate processing chambers that are positioned adjacent to each other and adjacent to at least one of the first plurality of substrate processing chambers, the second plurality of substrate processing chambers being positioned in a second direction relative to the first direction, a first shuttle robot movable in the first direction for moving substrates between each of the first plurality of substrate processing chambers, and a second shuttle robot movable in the second direction for moving substrates between each of the second plurality of substrate processing chambers.

Abstract: A heat treating apparatus utilizes a straightening plate provided in its central part with a gas exhaust opening and disposed under a heating plate. A temperature-reducing purge ring is disposed between the face plate and the straightening plate, and is provided in its inner circumference with plural gas jetting holes. A thin gap is formed between the temperature-reducing purge ring and the face plate. When a cooling gas is jetted radially inward through the gas jetting holes, a vacuum is created between the lower surface of the face plate and the upper surface of the temperature-reducing purge ring. Air is sucked into the space between the face plate and the straightening plate and flows together with the cooling gas to rapidly cool the face plate.

Abstract: A heating and air conditioning apparatus has an enclosure that defines an interior volume containing a compressor, a condenser coil, an expansion valve, an evaporator coil, a hot water coil, an evaporator fan, and a condenser fan. The compressor, the condenser coil, the expansion valve, and the evaporator coil are in communication with each other. The enclosure also has first and second input air openings and first and second output air openings. The evaporator fan draws air through the first input air opening and then through the evaporator coil and the hot water coil, and thereafter forces such air out of the enclosure through the first air outlet opening. The condenser fan draws air through the second input air opening and then through the condenser coil, and thereafter forces such air out of the enclosure through the second air outlet opening.

Abstract: Heat exchangers include a housing having an inlet and an outlet and forming a portion of a transition chamber. A heating member may form another portion of the transition chamber. The heating member includes a first end having a first opening and a second end having a second opening larger than the first opening. Methods of conveying a fluid include supplying a first fluid into a transition chamber of a heat exchanger, supplying a second fluid into the transition chamber, and altering a state of a portion of the first fluid with the second fluid. Methods of sublimating solid particles include conveying a first fluid comprising a material in a solid state into a transition chamber, heating the material to a gaseous state by directing a second fluid through a heating member and mixing the first fluid and the second fluid.

Abstract: A refrigerator with a liquid conditioning system providing a variety of levels and types of conditioned liquid streams for outputting to a refrigerator dispenser is disclosed. A liquid conditioning circuit having means for outputting ambient, cold, heated, filtered, and carbonated liquid streams for use in combination with a refrigerator is also disclosed. A finished beverage made from a conditioned liquid stream or combination of conditioned liquid streams is enhanced with one or more liquid enhancements components provided by a liquid enhancement system.

Abstract: A compact gas dryer (100) comprises a primary heat exchanger (200) exchanging heat between hot, incoming, contaminated gaseous medium and outgoing dry, cool gaseous 5 medium, a secondary heat exchanger (300) exchanging heat between incoming cold gaseous medium from the primary heat exchanger (200) and a refrigerant, and a condense trap (400) trapping condensable matter in the cooled gaseous medium exiting the secondary heat exchanger (300). 10 Afterwards, the dry, cool gaseous medium exchanges heat with the incoming contaminated gaseous medium in the primary heat exchanger. The primary heat exchanger (200), the secondary heat exchanger (300) and the condense trap (400) are combined into a single unit (100).

Abstract: A heat exchanger includes a plurality of plates in stacked relation forming a plurality of fluid channels therebetween. Ports formed in each of the plates are arranged and substantially align to form an inlet manifold and an outlet manifold for receiving a working fluid therein, wherein the inlet manifold is in fluid communication with an inlet conduit and the outlet manifold is in fluid communication with an outlet conduit. A temperature manipulation element is disposed in at least one of the inlet conduit and the outlet conduit to manipulate a temperature of the working fluid flowing therethrough.

Abstract: A device and method are disclosed for producing heated and/or cooled compressed air. The device may include a conventional air compressor, one or more filter stages to dry and purify the compressed air, a heat exchanger assembly including a heat exchanger enclosure with a heat exchange coil surrounded by ice or hot water for cooling or heating the compressed air, and an air distribution manifold to supply the temperature-controlled and filtered air to users. In a preferred embodiment, ice is used to cool the compressed air, and the cooled compressed air is supplied to protective gear worn by athletes to cool the athletes during rest periods.

Abstract: A space efficient system especially suited for use as an entirely self-contained stand-alone unit usable in any of multiple contexts where heating or cooling of a defined-volume or enclosure is required. Hot or cold sides of the thermoelectric assemblies face toward one another into a central airflow that enters and exits a housing through a top or bottom of the housing that faces into the enclosure, and the opposite sides of the thermoelectric modules face into channels on opposite sides of the central airflow. The channels can be connected to intake and exhaust air through a common end of the housing, or be separated to individually intake and exhaust air at opposing ends of the housing. Fastener-free mounting of components between insulation shells that cooperate with the thermoelectric assemblies to define the channel boundaries results in tool-free configurability of components for servicing, maintaining, reconfiguring, scaling or customizing of the system.

Abstract: A process for producing (meth)acrylic acid, comprising a crystallizing step of supplying a cooling medium from a refrigerator to a crystallizer and returning the cooling medium from the crystallizer to the refrigerator, thereby obtaining a (meth)acrylic acid crystal from a (meth)acrylic acid-containing solution; and a melting step of supplying a heating medium from a refrigerator to the crystallizer and returning the heating medium from the crystallizer to the refrigerator, thereby melting the (meth)acrylic acid crystal; wherein the crystallizing step and the melting step are respectively performed at least once, thereby producing purified (meth)acrylic acid from a crude (meth)acrylic acid solution; temperature of the cooling medium discharged from the refrigerator is maintained constant at temperature T1; temperature of the cooling medium to be returned to the refrigerator is maintained constant at temperature T2; the temperature T2 is adjusted depending on a production amount of the purified (meth)acrylic a

Abstract: A heat transfer system includes a heat source, a heat sink, and a thermotransfer structure that is operable to transfer heat between the heat source and the heat sink. The thermotransfer structure includes a thermally conductive element and a thermal storage element adjacent the thermally conductive element.

Abstract: An inlet header (22) of a microchannel heat pump heat exchanger has a tube (34) disposed therein and extending substantially the length of the inlet header (22), with the tube (34) having a plurality of openings (36) therein. During cooling mode operation, refrigerant is caused to flow into an open end of the tube (34) and along its length to thereby flow from the plurality of openings (36) into the inlet header (22) prior to entering the microchannels (24) to thereby provide a uniform flow of two-phase refrigerant thereto. A bi-flow expansion device (41) placed at the inlet end of the tube (34) allows for the expansion of liquid refrigerant into the tube (34) during periods in which the heat exchanger operates as an evaporator and allows the refrigerant to flow directly from the header (22) and around the tube (34) during periods in which the heat exchanger operates as a condenser coil.

Abstract: A heat transfer fluid can be cooled using the atmospheric thermal lapse rate. The heat transfer fluid can be ascended to a predetermined altitude above ground level where a temperature of the atmosphere is less than a temperature at the ground level. The heat transfer fluid can be cooled to a predetermined temperature by heat exchange between the heat transfer fluid and the atmosphere. The heat transfer fluid can then be descended to ground level while inhibiting heat transfer with the atmosphere tending to warm the cooled fluid.

Abstract: The invention discloses an ice composite body with a layer of water close to its freezing point within the body's armor shell at its base, with a pressurizing system for the water which maintains an upward pressure on the ice core at the set level needed to structurally support any burden resting on the top part of the shell, the top part of the shell & the ice core. The ice core has a separate non structural layer at its lowest level & a separate system of melting & freezing this layer of the ice core for thermal conditioning purposes, while using the pressurizing system to maintain hydrostatic and litho-static balance & thus maintain structural integrity. The pressurization system results in a more reliable structural support system for the top part of the shell particularly for dealing with thermal cycling & in warmer climates.

Abstract: A fan apparency arrangement for an appliance having a fan for moving air in an interior of the appliance, including a pipe disposed in the airflow path of the fan and having first and second ends; a heater disposed in the pipe, the heater being energized when the fan is turned on; and a thermal switch disposed in the pipe, the thermal switch being closer to the first end than the heater. The fan is operative in normal operation to move air in the pipe in a direction from the first end to the second end. The pipe is disposed so that when the fan fails to move air in the pipe after turned on, air heated up by the heater passes the thermal switch in a direction from the second end to the first end so that the thermal switch is activated to signal malfunction of the fan.

Abstract: A process chamber and a method for controlling the temperature of a substrate positioned on a substrate support assembly within the process chamber are provided. The substrate support assembly includes a thermally conductive body, a substrate support surface on the surface of the thermally conductive body and adapted to support a large area substrate thereon, one or more heating elements embedded within the thermally conductive body, and two or more cooling channels embedded within the thermally conductive body to be coplanar with the one or more heating elements. The cooling channels may be branched into two or more equal-length cooling passages being extended from a single point inlet and into a single point outlet to provide equal resistance cooling.

Abstract: A mounting apparatus includes a surface plate; a temperature control unit integrated with the surface plate; and a bottom plate integrated with the temperature control unit via a heat insulation ring, wherein a temperature of a target object held on the surface plate is capable of being controlled and the surface plate is formed of ceramic. The surface plate and the temperature control unit are coupled to each other by a first coupling member at each portion thereof except for each peripheral portion thereof such that the peripheral portion of the surface plate being not coupled thereto. The peripheral portion of the temperature control unit is coupled to the heat insulation ring by a second coupling member.

Abstract: Provided are methods, devices and systems for controlled removal of thermal energy from a fluid within a thermally conducting metal conduit. The system allows for the in situ formation of a reversible plug that can stop the flow of fluid through the conduit, particularly without inducing thermally induced stress fractures or breaches in the conduit. The devices and systems include a thermal transfer device that can be adapted to be in thermal communication with a thermal conducting metal conduit containing a fluid, particularly a flowing fluid. The devices and systems allows for controlled re-heating of the conduit without inducing thermally induced stress fractures or breaches in the conduit to restore fluid flow through the conduit.

Abstract: A heat exchange method and system for heat transfer includes a plate fin and tube or finned tube heat exchanger that reduces the plume of a stream that is being rejected to atmosphere by reducing the water dew point of the stream.

Abstract: A power generation system (11) and method of operating such a system (11) including a steam turbine (14). In one embodiment a HRSG (20) includes an evaporator (127) coupled to receive condensate from the steam turbine (14), and a superheater (132) coupled to receive output from the evaporator (127). The HRSG (20) generates steam with thermal energy received from a combustion turbine (28). A flash tank (9) receives water heated in the HRSG (20), outputs a first portion of the water as steam, and outputs a second portion of the water as liquid. A flow line (134) passes steam (51) from the flash tank (9) to a combustion chamber (26) in the combustion turbine (28) to provide power augmentation.

Abstract: A vacuum cooking apparatus for household use, comprising, on a supporting structure which has a column-like extension, at least one unit for packaging in pouches in vacuum food products to be cooked, at least one unit for cooking the food products arranged in pouches and at least one unit for quick refrigeration of the food products arranged in pouches and cooked, the at least one unit for packaging food products in pouches in vacuum comprising a vacuum packaging machine which is mounted on a drawer-like element which is supported so that it can slide by the supporting structure in order to pass from a retracted position, in which the vacuum packaging machine is arranged within the outer peripheral contour of the supporting structure, to an extracted position, in which the vacuum packaging machine is positioned at least partially outside the supporting structure, and vice versa.

Abstract: A modular heating and cooling unit comprising an independent set of headers for each of the heating a cooling loads and the source. A bank of these modular units provides a system that is capable of incremental simultaneous heating and cooling and redundancy. Valves in the internal piping of the unit eliminate the need for valves in the headers between units. This substantially reduces the overall footprint of the unit. Because of the parallel flow between the heat exchangers and the heating and cooling load, the modules can be operated in cooling mode and heating mode in any order.

Abstract: A liquid condensation system heats a liquid raw material under a decompressed circumstance and evaporates a volatile component from a liquid surface to condense the liquid raw material. Therefore, the liquid condensation system includes: liquid condensers, each of which condenses the liquid raw material; a vacuum pump that is in communication with the liquid condensers; and a warm water circulation system as a heating source that heats the liquid raw material in the liquid condensers. The volatile component evaporated in the liquid condensers is led to the outside of the liquid condensers through vapor lines. The condensed liquid that is not evaporated in the liquid condensers is led to the outside of the liquid condensers through condensed-liquid lines. Condensed-liquid-line adjusting valves are interposed on the condensed-liquid lines, and heaters are attached to the condensed-liquid lines. A control unit controls the heaters and the condensed-liquid-line adjusting valves.

Abstract: The present subject matter discloses a fluid cooled reformer for gas turbine systems and a method for cooling both a fuel reformer and a heated reformate stream produced by such fuel reformer. The fluid cooled reformer may include a pressure vessel and a reactor assembly disposed within the pressure vessel. The reactor assembly may include a reactor and may be configured to receive and reform an oxygen/fuel mixture to produce a heated reformate stream. Additionally, the fluid cooled reformer may include an inlet configured to direct a fluid stream into the pressure vessel. At least a portion of the fluid stream may be used to cool the reactor assembly. A reformate cooling section may be disposed downstream of the reactor of the reactor assembly and may be configured to cool the heated reformate stream.