A fluid management device and a thermal management system are provided. The fluid management device includes a fluid management module, a connecting member and a fluid management component, wherein the fluid management module is fixedly or limitedly connected to the connecting member; at least part of the fluid management component is located in a mounting hole; the fluid management device has a communicating channel, at least part of which is located in the connecting member; the communicating channel includes a first communicating channel being in communication with a first valve cavity of a first fluid management module, and a second communicating channel including a first sub-channel, a second sub-channel being in communication with a second valve cavity of a second fluid management module, and a third sub-channel. The opening degree of the second communicating channel can be adjusted by the fluid management component.

A refrigeration cycle apparatus is a refrigeration cycle apparatus in which refrigerant circulates in an order of a compressor, an oil separator, a condenser, an expansion valve, an evaporator, and an accumulator. The refrigeration cycle apparatus includes: an oil returning path extending from the oil separator to the compressor; a first electromagnetic valve provided on the oil returning path; an oil returning path extending from the accumulator to the compressor; a second electromagnetic valve provided on the oil returning path; and a controller configured to control a degree of opening of the first electromagnetic valve and a degree of opening of the second electromagnetic valve.

A thermal management loop system may include an accumulator, an evaporator in fluid receiving communication with the accumulator, a condenser in fluid receiving communication with the evaporator, and a rotary separator in fluid receiving communication with the condenser. Gas exiting the rotary separator may recirculate back to the condenser and liquid exiting the rotary separator may flow to the accumulator. The thermal management loop system may be a dual-mode system and thus may be operable in a powered-pump mode or a passive-capillary mode.

A passive liquid collecting device includes a reservoir including a reservoir exit line and at least one rigid structure disposed within the reservoir configured to collect a liquid and direct the liquid to the reservoir exit line. A first porous capillary media is supported by the at least one rigid structure and a vapor-liquid separator in contact with at least one of the at least one rigid structure and the first porous capillary media. The vapor-liquid separator includes a guide member extending along a guide member axis having a guide inlet and a guide outlet connected by a spiral conduit. A second porous capillary media is located radially outward from the spiral conduit on an exterior surface of the guide member. A thermal control loop is also disclosed.

A thermal management loop system may include an accumulator, an evaporator in fluid receiving communication with the accumulator, a condenser in fluid receiving communication with the evaporator, and a rotary separator in fluid receiving communication with the condenser. Gas exiting the rotary separator may recirculate back to the condenser and liquid exiting the rotary separator may flow to the accumulator. The thermal management loop system may be a dual-mode system and thus may be operable in a powered-pump mode or a passive-capillary mode.

An oil separator is provided. The oil separator includes a housing providing an oil separation space therein. An inlet introducing oil/gas mixture into the oil separation space is provided within an upper portion of the housing. An outlet discharging oil is provided within the lower portion of the housing. A gas discharge conduit is connected to the oil separation space. A portion of a surface exposed in the oil separation space is provided with a nanorod layer.

A heat exchanger includes a fluid distribution manifold, a fluid collection manifold, and a plurality of tubes extending there between. A separator within the fluid distribution manifold includes a first fluid conduit and a second fluid conduit. The first fluid conduit extends through an inlet end and over at least a portion of the length of the fluid distribution manifold. A plurality of openings in the first fluid conduit fluidly couples the first fluid conduit to at least a first portion of the plurality of tubes. A first end of a second fluid conduit is arranged generally centrally within and parallel to the first fluid conduit. Refrigerant vapor is configured to flow through the second fluid conduit. Liquid refrigerant is configured to flow between the first fluid conduit and the second fluid conduit to at least the first portion of the plurality of tubes.

A refrigeration appliance includes first and second temperature zones and a refrigerant circuit having first and second parallel branches. The first branch has a controllable first restriction point and a first heat exchanger for setting a temperature of the first temperature zone, and the second branch has a second restriction point and a second heat exchanger for setting a temperature of the second temperature zone. A branching point, at which the refrigerant circuit splits into the two branches, is configured as a separator for separating gas and liquid and the second branch is connected to a liquid outlet of the separator.

A method for generating electricity and cold and a device for realizing same, consists in a closed absorption cycle in which a working body is a mixture of a low-boiling (refrigerant) component and a high-boiling (absorbent) component. The method involves evaporating a strong solution in a steam generator, thus forming a refrigerant vapor and a weak solution, expanding the refrigerant vapor in a turbine, thus producing work, and, after the turbine, absorbing spent vapor in an absorber, forming a strong solution. A distinguishing feature of the method consists in changing the concentration of a strong solution using two stages, including not only evaporation but also filtration. The proposed method and device allow for significantly increasing the efficiency of systems for generating electricity relative to analogous known methods.

A refrigerant processing device includes a main body, and a pipe and a narrow tube that feed a refrigerant into and out of the main body. The main body has a cylindrical body part, and upper and lower end wall parts that close both ends of the cylindrical body part. The pipe passes through the lower end wall part, and extends along a central axis of the cylindrical body part. The narrow tube passes through the upper end wall part. A first spiral groove extending in a spiral shape with respect to the central axis is formed on an inner circumferential surface of the cylindrical body part. A second spiral groove extending in a spiral shape with respect to the central axis and a linear groove extending in a direction of the central axis are formed on an outer circumferential surface of the pipe.