Abstract: An electronic expansion valve, the electronic expansion valve includes: a housing (10), wherein the housing (10) is provided with an accommodating cavity (11) and a valve cavity (12), the valve cavity (12) is used for communicating with a pipeline, the housing (10) includes a valve seat (14), and the valve cavity (12) is disposed in the valve seat (14); a valve core assembly (20), movably disposed in the housing (10); and a guide seat (30), wherein the guide seat (30) is located between the accommodating cavity (11) and the valve cavity (12), a balance channel (40) is provided between the guide seat (30) and the valve seat (14), one end of the balance channel (40) is in communication with the accommodating cavity (11), and the other end of the balance channel (40) is in communication with the valve cavity (12).

Abstract: A refrigerant cycle system includes: a primary-side cycle of a vapor compression type that circulates a first refrigerant; a secondary-side cycle of a vapor compression type that circulates a second refrigerant; and a cascade heat exchanger that exchanges heat between the first refrigerant and the second refrigerant. The secondary-side cycle includes a secondary-side heat exchanger that uses cold or heat obtained by the second refrigerant from the cascade heat exchanger. The secondary-side heat exchanger includes a flat multi-hole pipe.

Abstract: A fluid cooling system includes a boiling plate, a compressor, and a condenser. The boiling plate contacts a heat-generating electronic component. The boiling plate receives a liquid such that the liquid absorbs heat from the electronic component and evaporates into a vapor. The compressor is fluidly connected the boiling plate and receives the vapor of the boiling plate. The compressor increases the pressure of the vapor such that the temperature of the vapor increases, and such that a saturation temperature of the vapor increases. The condenser is fluidly connected to the compressor and the boiling plate. The condenser receives the vapor from the compressor and removes heat from the vapor such that the vapor condenses back into the liquid. The boiling plate receives the liquid from the condenser. The system can include a pump that circulates the liquid and the vapor between the boiling plate, the compressor, and the condenser.

Abstract: One or more temperature control units are distributed throughout an environment to provide localized heating and cooling. The temperature control units include a thermal storage system including one or more substances of high latent heat capacity, a heat distribution surface, a solid-state heat pump positioned between the thermal storage system and the heat distribution surface, an environmental sensing module including a proximity sensor, and unit control modules in communication with the solid-state heat pumps. The solid-state heat pumps are individually controllable so that heating and cooling can be provided simultaneously from separate heat pumps in the same temperature control unit, or separate temperature control units in the same environment.

Abstract: A cooling system comprises a main cooling arrangement thermally coupled to the heat generating component, and configured for collecting thermal energy of the heat generating component via a main heat transfer fluid, and a backup cooling arrangement thermally coupled to the main cooling arrangement and comprising at least one fluid path configured for conducting a backup heat transfer fluid. The cooling system comprises a thermal fuse disposed within at least a portion of the at least one fluid path, the thermal fuse changing from a solid state to a melted state and selectively enabling a flow of the backup heat transfer fluid in the at least one fluid path of the backup cooling arrangement in response to its temperature being above a temperature threshold, the backup heat transfer fluid being configured to, upon flowing in the at least one fluid path, collect thermal energy from the main cooling arrangement.

Abstract: A heat transmitting device is provided, including a main body and an integrating portion. The main body has at least one opening. The integrating portion is used to seal the opening, and has a first surface and a second surface opposite the first surface. A first welding pattern is formed on the first surface, a second welding pattern is formed on the second surface, and the position of the first welding pattern corresponds to that of the second welding pattern. The type of the first welding pattern and the type of the second welding pattern are asymmetric.

Abstract: A portable demolition device is based on that the volume of water increases after cooling and freezing. A silicone bag is used to inject controllable water into the designated gap position, and a compressor is used to cool the water through heat conduction until the water freezes. When the water freezes to ice, the ice enlarges the gap. Then another portable demolition device or a replaced silicone bag is used to further enlarge the gap with water until a demolition is complete. The invention has the following advantage: 1. Stable. Compared with other demolition tools, the invention can accurately control the position, direction and force to be demolition. 2. Large-scale demolition can be completed by using a plurality of the invention together, such as directional demolition of an entire building. 3. It is easier to control the direction and strength in large-scale demolition, so that the safety is greatly improved.

Abstract: An air conditioner includes a first unit and a second unit. The first unit is connected to the second unit by a connection power wire and a connection ground wire, the connection power wire feeding power from the first unit to the second unit, the connection ground wire connecting ground of the first unit to ground of the second unit. The first unit includes a capacitor connected between the connection power wire and ground of the first unit. The connection power wire and the connection ground wire extend through a hole of a magnetic piece.

Abstract: An exhaust gas treatment method by which mercury contained in exhaust gas can be separated and removed efficiently and inexpensively. The method includes cooling an exhaust gas containing mercury in metal vapor phase by spraying water or other methods to condense mercury in the exhaust gas from metal vapor phase into metal liquid and thus to separate and remove mercury from the exhaust gas. When the exhaust gas is cooled by spraying water, the sprayed water is collected and separated into separated water and a solid containing mercury that has condensed to metal liquid, and mercury is recovered from the solid. The metal mercury particles that have condensed to metal liquid are dispersed in cooling water. The metal mercury particles can thus be easily separated and recovered by using a suitable separation device.

Abstract: Methods and systems for liquefying natural gas using environmentally-friendly low combustibility refrigerants are provided. Methods of liquefaction include cooling a fluid in an LNG facility via indirect heat exchange with an environmentally-friendly low combustibility refrigerants that are propane, ethane and methane mixed with small amounts of fluorinated olefin, but still within close proximity to the boiling points of the pure refrigerants such that the mixed refrigerants can still be used in an optimized cascade process.

Abstract: Cooling units are provided. The cooling units include a base having a housing with control components and a cooling tower attached to the base having an inner flow path and an exterior surface. An air distribution system is attached to the cooling tower and includes an air distribution chamber defined between the first and second enclosures and a cover is disposed on an exterior surface of the second enclosure. A plurality of dispersing apertures are formed within the first enclosure to generate a curtain of cool air to be dispensed from the air distribution system. The control components are configured to convey air through the base, the cooling tower, and the air distribution system to dispense air through the cool air dispenser and the warm air dispenser.

Abstract: A system and method for cooling a gas using a mixed refrigerant includes a compressor system and a heat exchange system, where the compressor system may include an interstage separation device or drum with no liquid outlet, a liquid outlet in fluid communication with a pump that pumps liquid forward to a high pressure separation device or a liquid outlet through which liquid flows to the heat exchanger to be subcooled. In the last situation, the subcooled liquid is expanded and combined with an expanded cold temperature stream, which is a cooled and expanded stream from the vapor side of a cold vapor separation device, and subcooled and expanded streams from liquid sides of the high pressure separation device and the cold vapor separation device, or combined with a stream formed from the subcooled streams from the liquid sides of the high pressure separation device and the cold vapor separation device after mixing and expansion, to form a primary refrigeration stream.

Abstract: A refrigerant quality control system indicates quality information of a recovered refrigerant. The refrigerant quality control system includes a CPU and a storage. The CPU is configured to acquire first information related to a quality of the recovered refrigerant from a first information terminal possessed by a provider of the recovered refrigerant via a communication network. The storage stores the first information acquired by the CPU. The CPU is further configured to provide a second information terminal with second information based on the first information stored in the storage via the communication network. The second information terminal is possessed by an entity different from the provider.

Abstract: Provided is a heat storage unit having a simple configuration, capable of being attached to various objects, and capable of efficiently performing heat exchange. The heat storage unit has at least one inorganic fiber member configured by binding or entangling flexible inorganic fibers and having a desired shape; and a heat storage material in contact with the inorganic fibers.

Abstract: A freezing desalination method includes cooling salt water in a first chamber with a conductive interface having a thermoelectric cooler (TEC). The conductive interface separates the first chamber from the second chamber containing fresh water. The method further includes reversing a current supplied to the conductive interface by a power source, when ice forms on the conductive interface, thereby allowing the ice to detach from the conductive interface. The ice formed in the first chamber is moved to the second chamber with a moving mechanism thereby melting the ice in the second chamber.

Abstract: A fluid heat exchanger for cooling an electronic device can have a plurality of walls. The walls can define a corresponding plurality of microchannels. Each microchannel can extend from a first end to a second end. The plurality of microchannels can define at least two opposed outer microchannels and a centrally located microchannel positioned between the opposed outer microchannels. A fluid inlet passage can be configured to deliver a heat-exchange fluid to each microchannel between the corresponding first end and the corresponding second end of the respective microchannel. A fluid outlet passage can have an enlarged outlet region from the centrally located microchannel compared to a corresponding outlet region from one or both of the opposed outer microchannels. Related methods are disclosed.

Abstract: One variation of a cooling system includes: a cooling unit including a substrate defining a thermally-conductive material and a coating defining a porous, hydrophilic material. The substrate defines: a base; a heatsink structure extending from the base; and an open network of pores extending between surfaces of the substrate. The coating extends across surfaces of the substrate and lines the open network of pores within the substrate. The heatsink structure is configured to: communicate thermal energy from a first working fluid, flowing over the heatsink structure, into the heatsink structure, to cool the first working fluid; and release thermal energy and moisture, contained in pores of the coating, into a second working fluid flowing over the heatsink structure, to cool the second working fluid and the heatsink structure.

Abstract: A heat extraction assembly or apparatus includes a cooling cassette and a component coupled to a top surface of the cooling cassette. The cooling cassette may include an inlet, an outlet, and a cooling cavity disposed within the top surface of the cooling cassette. The cooling cavity may be in fluid communication with inlet and the outlet. The component may be coupled to the top surface of the cooling cassette proximate to the cooling cavity such that the component at least partially defines a boundary of the cooling cavity. Coolant flowing through the cooling cassette from the inlet to the outlet may directly contact the component at the cooling cavity in order to provide a cooling effect to regulate a temperature of the component.

Abstract: A plate fin heat exchanger assembly (S) for a cryogenic air separation unit, comprising: a heat exchanger having at least two cryogenic liquid inlets (B,C) at least two cryogenic liquid outlets (B,C), at least one nitrogen-rich stream inlet (D) at a first end of the heat exchanger and at least one nitrogen-rich stream outlet at a second end of the heat exchanger, the heat exchanger configured to receive a flow of at least one nitrogen-rich stream (WN,LPGAN) of the air separation unit at the at least one nitrogen-rich stream inlet and separate flows of at least two cryogenic liquids (LOX,LIN,LR) at the at least two cryogenic liquid inlets; wherein the inlet of the first of the cryogenic liquids is closer to the first end than the outlet of the second of the cryogenic liquids.

Abstract: A smart air conditioner for reduction in fine dust and harmful gas includes: an eternal chamber including a first side coupled to communicate with an interior and a second side communicating with an exterior; an internal chamber disposed to pass through an inside of the external chamber and including a first side coupled to communicate with an interior and a second side communicating with an exterior; an external chamber damper installed in the external chamber and controlling air flow; and an internal chamber damper installed in the internal chamber and controlling air flow.