A thermal expansion valve includes a power head and a valve body. The power head and the valve body are fixedly arranged. The power head includes a power head cover, a power head seat, and a membrane. The membrane includes a membrane recess and a corrugated portion. The membrane recess is located at the center position of the membrane. The corrugated portion is located at the peripheral position of the membrane recess. The membrane recess is recessed away from the power head cover. The valve body comprises a top portion. The top portion is provided with an opening. At least a part of the power head is extended into the opening. With an axial direction of the valve body as a projection direction, a projection of the power head towards the top portion falls on the top portion.

Disclosed is a separation system including: a chamber comprising: an inlet for receiving a two-phase fluid; a first outlet for draining liquid contained in the two-phase fluid; a second outlet for egress of gas contained in the two-phase fluid; a cylindrical body disposed in the chamber having a plurality of channels through which, during use, the two-phase fluid travels from the inlet to the second outlet, and wherein the liquid within the two-phase fluid coalesces on the walls of the plurality of channels as the two-phase fluid passes through the plurality of channels and the liquid drains through the first outlet.

Disclosed is a separation system including: a chamber comprising: an inlet for receiving a two-phase fluid; a first outlet for draining liquid contained in the two-phase fluid; a second outlet for egress of gas contained in the two-phase fluid; a cylindrical body disposed in the chamber having a plurality of channels through which, during use, the two-phase fluid travels from the inlet to the second outlet, and wherein the liquid within the two-phase fluid coalesces on the walls of the plurality of channels as the two-phase fluid passes through the plurality of channels and the liquid drains through the first outlet.

A thermal expansion valve includes a power head and a valve body. The power head and the valve body are fixedly arranged. The power head includes a power head cover, a power head seat, and a membrane. The membrane includes a membrane recess and a corrugated portion. The membrane recess is located at the center position of the membrane. The corrugated portion is located at the peripheral position of the membrane recess. The membrane recess is recessed away from the power head cover. The valve body comprises a top portion. The top portion is provided with an opening. At least a part of the power head is extended into the opening. With an axial direction of the valve body as a projection direction, a projection of the power head towards the top portion falls on the top portion.

Cooling systems include a cold sink having a number of heat load cooling paths and a heat load associated with each cooling path. An inlet is configured to supply a cooling fluid into the cold sink and an outlet is configured to receive the cooling fluid after passing through the plurality of heat load cooling paths of the cold sink. A pressure regulating element is arranged along each cooling path, each pressure regulating element arranged between the inlet and the heat load along each cooling path and configured to cause a pressure drop in the cooling fluid prior to passing the cooling fluid to each heat load. The pressure drop caused by each pressure regulating element is the same and is a pressure drop greater than a maximum pressure drop across each heat load of a system without such pressure regulating elements.

Cooling systems include a cold sink thermally coupled to a heat load, a separator configured to separate liquid and vapor portions of a working fluid, and a cooling cycle having a vapor loop and a liquid loop, the cooling cycle having the working fluid configured to pass through both the vapor loop and the liquid loop. The vapor loop includes the separator, a compressor, a condenser, and a valve. A vapor form of the working fluid flows from the separator into the compressor, and the working fluid then flows to the condenser, and then through the valve, and returned to the separator. The liquid loop includes the cold sink, the separator, and a pump. A liquid form of the working fluid flows from the separator into the pump and the working fluid is increased in pressure and supplied to the cold sink and then returned to the separator.

Cooling systems include a cold sink thermally coupled to a heat load, a separator configured to separate liquid and vapor portions of a working fluid, and a cooling cycle having a vapor loop and a liquid loop, the cooling cycle having the working fluid configured to pass through both the vapor loop and the liquid loop. The vapor loop includes the separator, a compressor, a condenser, and a valve. A vapor form of the working fluid flows from the separator into the compressor, and the working fluid then flows to the condenser, and then through the valve, and returned to the separator. The liquid loop includes the cold sink, the separator, and a pump. A liquid form of the working fluid flows from the separator into the pump and the working fluid is increased in pressure and supplied to the cold sink and then returned to the separator.

An air conditioning system for a vehicle includes a refrigerant circulating through a closed system including a condenser, a compressor, and an evaporator. A sorbent body, which may be a desiccant-entrained polymer, is disposed inside the compressor to remove moisture from the refrigerant passing therethrough.

In a particular embodiment, a cooling system contains a compressor configured to compress a refrigerant, a high side heat exchanger configured to remove heat from the refrigerant, and a load configured to cool a space using the refrigerant. The high side heat exchanger has a frame and one or more refrigerant tubes extending through the frame, wherein each refrigerant tube has at least one cavity configured to allow the refrigerant to flow through the refrigerant tube. The high side heat exchanger is configured to remove heat from the refrigerant as the refrigerant flows through the one or more refrigerant tubes. The high side heat exchanger also has one or more heat pipes contacting the frame that, collectively, bear at least 25% of the weight of the one or more refrigerant tubes, are coupled directly to the frame, and are configured to remove heat from the flowing refrigerant.

In a particular embodiment, a cooling system contains a compressor configured to compress a refrigerant, a high side heat exchanger configured to remove heat from the refrigerant, and a load configured to cool a space using the refrigerant. The high side heat exchanger has a frame and one or more refrigerant tubes extending through the frame, wherein each refrigerant tube has at least one cavity configured to allow the refrigerant to flow through the refrigerant tube. The high side heat exchanger is configured to remove heat from the refrigerant as the refrigerant flows through the one or more refrigerant tubes. The high side heat exchanger also has one or more heat pipes contacting the frame that, collectively, bear at least 25% of the weight of the one or more refrigerant tubes, are coupled directly to the frame, and are configured to remove heat from the flowing refrigerant.