A condenser having a receiver for storing liquid refrigerant, the condenser having a heat exchanger block with at least one manifold and with a tube and fin block, wherein the tubes communicate with the at least one manifold for introducing and releasing refrigerant to or from the heat exchanger block. The receiver is located adjacent to one of the manifolds. The receiver has a tube with at least one open tube end and with at least one disc. The disc is located within the tube at the tube end in order to close the tube end and the disc is fluid tight connected with the tube end by cold metal transfer welding.

A refrigeration system includes a core comprising a stack of core plates. The core defines a condenser, an evaporator and a refrigerant reservoir. The condenser has a plurality of refrigerant flow passages and a plurality of first coolant flow passages in alternating arrangement. The evaporator has a plurality of refrigerant flow passages and a plurality of second coolant flow passages in alternating arrangement. The condenser has a refrigerant outlet in flow communication with the refrigerant inlet of the refrigerant reservoir, where the refrigerant side of at least one of said core plates includes a refrigerant communication passage providing flow communication between the refrigerant outlet of the condenser section and the refrigerant inlet of the reservoir section.

A liquid chiller system utilizing a refrigerant capable of possessing a liquid state and a gas/vapor state, the refrigerant being cycled through a closed loop assembly of a compressor, an eccentric condenser and an eccentric evaporator. The eccentric compressor has a lower integrated reservoir and the eccentric evaporator has an upper dedicated reservoir such that separate, dedicated separator or receiver vessels are not required. The eccentric condenser is positioned above the eccentric evaporator such that liquid refrigerant flows by gravity from the eccentric condenser to the eccentric evaporator.

A cooling device having a vaporizer for vaporizing a working liquid, wherein the working liquid is held on a vaporizer bottom; a compressor for compressing a vaporized working liquid, wherein the compressor is configured to convey the vaporized working liquid from the bottom to the top in a setup direction; a liquefier having an upper wall configured such that the vaporized and compressed working liquid is condensable at the upper wall and drips down from top to bottom; and an intermediate bottom configured to collect a dripped-down working liquid, wherein the intermediate bottom comprises at least one opening through which the dripped-down working liquid may reach the vaporizer bottom.

The invention relates to a condenser receiver adapted to receive and house a fluid used in a cold loop of an air-conditioning circuit. The condenser receiver comprises an outer wall and an inner wall which define an intermediate space, said inner wall defining an inner space for housing the fluid. The intermediate space comprises a static component adapted to store and release a given quantity of heat in order to allow a heat exchange between the static component and the fluid contained in the inner space.

The invention relates to a condenser receiver adapted to receive and house a fluid used in a cold loop of an air-conditioning system, said condenser receiver comprising an outer wall and an inner wall. The inner wall defines an inner space for housing a fluid, while the outer wall is provided on its outer surface with a plurality of ribs that increase the heat exchange between the fluid contained in the inner space and the ambient air outside the condenser receiver.

An HVAC refrigerant line connector for a condenser header tank. The connector includes a header tank mating surface having a concave shape configured to mate with a convex outer tank surface of the condenser header tank. An outer surface is opposite to the header tank mating surface. A first through bore is defined by the connector extending between the outer surface and the header tank mating surface. A first channel is defined by the header tank mating surface. The first channel is configured to receive header tank material staked into the first channel to hold the header tank mating surface against the convex outer tank surface prior to the connector being brazed to the header tank.

A refrigeration system includes a core comprising a stack of core plates. The core defines a condenser, an evaporator and a refrigerant reservoir. The condenser has a plurality of refrigerant flow passages and a plurality of first coolant flow passages in alternating arrangement. The evaporator has a plurality of refrigerant flow passages and a plurality of second coolant flow passages in alternating arrangement. The condenser has a refrigerant outlet in flow communication with the refrigerant inlet of the refrigerant reservoir, where the refrigerant side of at least one of said core plates includes a refrigerant communication passage providing flow communication between the refrigerant outlet of the condenser section and the refrigerant inlet of the reservoir section.

A liquid reservoir used in a heat exchanger, for example an automotive air conditioner, and a manufacturing method therefor. The liquid reservoir includes an inlet hole and an outlet hole. The outlet hole is provided with a filter element covering the outlet hole. A flow area at a location of the outlet hole covered by the filter element is greater than the cross-sectional area of other locations of the outlet hole. In this way, in the case that other structures of the inlet hole are not improved, a filtering area of the filter element is increased, thereby increasing a flow area of a refrigerant, reducing a flow resistance effect exerted by the filter element on the refrigerant, and reducing a workload of the heat exchanger.

The present invention relates to an outdoor heat exchanger, and more particularly, to a down flow type outdoor heat exchanger having channels of at least three paths in a heat pump system for vehicles, in which a flux distribution means protruded in a height direction is further formed in a lower tank in which the channel is changed from an upward direction to a downward direction or from a downward direction to an upward direction to block some area of a lower portion thereof so as to prevent a refrigerant from being non-uniformly distributed while a flux is concentrated toward a rear side of the channel due to a fluid inertia in an area in which the flow path is changed, thereby delaying frosting upon heating.