An oil separator to separate oil from oil and refrigerant mixture. The oil separator includes inlets to allow entry of the oil and refrigerant mixture into the oil separator. The mixture flows and strikes on center of the one or more walls of the oil separator. The mixture then flows towards demister pads for filtration. The oil is separated from the mixture and exits the oil separator from the oil outlet. The refrigerant separated from the mixture escapes through the refrigerant outlet.

According to various embodiments of the invention, a heat exchanger can have at least one duct for conveying a coolant, wherein the at least one duct has a first section and a second section, the first section being arranged in the at least one duct upstream relative to the second section, in relation to a flow direction of the coolant, the second section having a cross section area that is larger than a cross section area of the first section, such that a sublimation of the coolant in the second section is made possible.

A linear compressor includes: a shell including an intake pipe configured to suction a refrigerant, a piston configured to reciprocate in an axial direction and including a piston body, and an intake muffler coupled to the piston and configured to flow the refrigerant into the piston body and reduce a noise from the refrigerant. The intake muffler includes a first muffler disposed inside the piston body, a second muffler disposed at a rear side of the first muffler and in fluid communication with the first muffler, and a third muffler including a third muffler body having a cylindrical shape with an empty interior and configured to accommodate a portion of a rear end of the first muffler and the second muffler in the third muffler body. The third muffler body includes a streamlined portion having diameters reduced toward a rear side of the third muffler body in the axial direction.

A refrigeration cycle apparatus 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.

An accumulator (28), optionally in combination with an internal heat exchanger in a shared housing (24), comprising a cyclone (12) for separation of the gas and liquid phase of a refrigerant, and characterised in that the cyclone (12) comprises two separate, curved flow paths (14, 16), one of which (14) leads from an inlet (18) on the cover side whose direction of flow is closer to the axial than the radial direction of the cyclone (12) into the accumulator and radially outwards, and the other of which (16, 52) leads outwards from an end facing away from the cover (20).

The separation efficiency for bubbles contained in liquid is improved. A bubble separator 20 that separates bubbles in liquid is provided. The bubble separator 20 comprises: a swirl flow formation part 22 extending in a nearly horizontal direction, and including an internal space having a columnar shape; an flow inlet 24 disposed at one end of the swirl flow formation part 22, and being open so as to cause the liquid to flow in the flow inlet 24 in a tangential direction of an inner peripheral surface of the swirl flow formation part 22 and so as to form a swirl flow on the inner peripheral surface; an flow outlet 26 disposed at another end of the swirl flow formation part 22, and being open so as to cause the liquid to flow out of the flow outlet 26 in a tangential direction from the inner peripheral surface; gas discharge ports 30, 32 to discharge gas separated from the liquid in the swirl flow formation part 22, outside of the swirl flow formation part; and a single or a plurality of liquid drop nozzles 50a to 50c provided on a wall surface of the swirl flow formation part 22. A fluid circuit for an automobile that includes the bubble separator 20 is also provided.

An oil separator to separate oil from oil and refrigerant mixture. The oil separator includes inlets to allow entry of the oil and refrigerant mixture into the oil separator. The mixture flows and strikes on center of the one or more walls of the oil separator. The mixture then flows towards demister pads for filtration. The oil is separated from the mixture and exits the oil separator from the oil outlet. The refrigerant separated from the mixture escapes through the refrigerant outlet.

The invention concerns a receiver/drier (6) adapted to have pass through it a refrigerant fluid (FR) of a refrigerant fluid (FR) circuit (1) for a vehicle, in particular a motor vehicle. The receiver/drier (6) comprises a closed housing (10) provided with a fluid inlet (14) for admission of the refrigerant fluid (FR) to the interior of the housing (10) and with a fluid outlet (15) for evacuation of the refrigerant fluid (FR) from the housing (10). The housing (10) accommodates at least one desiccant (16) and at least one particle filter (17a, 17b, 17c). The receiver/drier (6) is provided with a phase separation device (18) between a liquid phase and a gas phase of the refrigerant fluid (FR) admitted to the interior of the housing (10).

A packaged, pumped liquid, evaporative-condensing recirculating ammonia refrigeration system with charges of 10 lbs or less of refrigerant per ton of refrigeration capacity. The compressor and related components are situated inside the plenum of a standard evaporative condenser unit, and the evaporator is close coupled to the evaporative condenser. Single or dual phase cyclonic separators may also be housed in the plenum of the evaporative condenser.

Provided are a separator with improved oil separation efficiency, and a refrigeration cycle apparatus including the separator. The separator includes an inflow pipe portion, an oil storage portion, an oil return pipe portion, and an outflow pipe portion. The inflow pipe portion includes a swirling portion that defines a flow direction of refrigerant so as to swirl the refrigerant. The oil storage portion is connected to the inflow pipe portion. The oil return pipe portion is connected to a vertically lower side of the oil storage portion. The outflow pipe portion includes an opening end that faces the swirling portion. The outflow pipe portion extends from a region that faces the swirling portion to the outside of the oil storage portion. The opening end is configured such that the refrigerant discharged from the swirling portion can directly flow thereinto.