The present invention relates to a heat exchanger (1) comprising at least, one fluid F passage tube (7) and at least one manifold (5) provided with a cover (11) closing, after assembly, a longitudinal opening (10) of a collector plate (9) cooperating with said cover (11) to form the manifold, said tube (7) being designed to form a connecting element for the exchanger and comprising an end partially crimped between said cover (11) and said collector plate (9) at a passage orifice (17) for said fluid F in the manifold.

A cooling system for a wind tunnel is disclosed. The heat exchanger of the present disclosure is formed as a turning vane in an airflow duct of a re-circulating wind tunnels. The individual vanes are formed from extruded aluminum with coolant fluid channels running continually down the length of the vane. One or more channels can be used, depending on the application of vane and the cooling capacity needed. The exterior of the vanes are formed in an airfoil shape to efficiently turn the air flow the desired amount in a manner well known in the art. The turning vanes are connected to a fluid supply with single piece connectors that removably attach to the turning vanes. In the depicted embodiment the connectors are attached with screws. In the depicted embodiment the connectors are formed as a single piece in a two-piece injection mold.

A radiator includes a main body, two connecting members and two taps. The two connecting members are disposed on opposite sides of the main body. Each of the two taps is rotatably connected to one of the two connecting members, such that the two taps are rotatably disposed on opposite sides of the main body.

A heat exchanger includes a header and an annular core fluidly connected to the header. The annular core includes an inner diameter, an outer diameter, first flow channels arranged in a first set of layers, and second flow channels arranged in a second set of layers and interleaved with the first flow channels. Each of the first flow channels includes a first inlet, a first outlet, and a first axial region extending between the first inlet and the first outlet. Each of the second flow channels includes a second inlet, a second outlet, and a second axial region extending between the second inlet and the second outlet.

A battery cell heat exchanger having a pair of plates that together define a fluid passage having a first channel permitting fluid flow from a first end of the plate pair towards a second end of the plate pair, and a second channel permitting fluid flow from the second end towards the first end of the plate pair. The plate pair together defining a first conduit at the first end of the plate pair, the first conduit being in fluid communication with the first channel. One of the pair of plates having an aperture permitting fluid flow from the second channel to a duct, the duct coupled to the one of the pair of plates having the aperture and having a second conduit in fluid communication with the aperture; where the first conduit and the second conduit lie in the plane defined by the pair of plates.

A heat exchanger for battery thermal management applications is disclosed. The heat exchanger has at least one internal, two-pass flow passage, the at least one internal, two-pass flow passage having an inlet end and an outlet end and at least a first flow passage portion and at least a second flow passage portion interconnected by a generally U-shaped turn portion. An inlet manifold is in fluid communication with the inlet end of the internal flow passage for delivering an incoming fluid stream to the heat exchanger while an outlet manifold is in fluid communication with the outlet end of the internal flow passage for discharging an outgoing fluid stream from the heat exchanger. A bypass passage fluidly interconnects the incoming fluid stream and the outgoing fluid stream.

Provided are an integrated connector and a heat exchanger including the same, which may prevent assembly defects and leaks of a heat exchanger because the connector may be manufactured with precise dimensions, and is easy to manufacture, by integrally forming the connector that connects and firmly couples a header tank and a gas-liquid separator so that a heat exchanger medium communicates in the heat exchanger such as a condenser, in which the integrated connector is formed by molding a first pipe portion inserted into a hole of the header tank, a first flange portion in surface contact with an outer surface of the header tank, a second pipe portion inserted into a hole of the gas-liquid separator, and a second flange portion in surface contact with an outer surface of the gas-liquid separator so as to be connected to one another and have an interior communicating with one another.

A cold plate apparatus includes walls that surround an active volume adjacent to an inlet plenum; the walls include an inlet opening at one end of a top side of the inlet plenum and a plenum opening between the inlet plenum and the active volume. Also included is a blocker that partially separates the inlet plenum from the active volume. The blocker is structurally configured to preferentially redirect flow from the inlet plenum into the active volume.

A heat exchanger includes a first row of flat tubes, a second row of flat tubes, a first header causing first ends of the flat tubes in the first row in a first direction to communicate with each other, a second header causing first ends of the flat tubes in the second row in the first direction to communicate with each other, and a third header that causes the second ends to communicate with each other and connects the first and second rows to cause refrigerant to flow between the first header and the second header. The flat tubes are arranged outside a space between the segments of the third header. A stress-absorbing part is provided in at least a bending target portion of one of the first header and the second header subjected to larger stress from the bending than the other one of the first header and the second header.

A method provides a sealed connection of a connector to a heat exchanger of the coaxial tubular type is particularly suitable for a motor vehicle air-conditioning circuit. The method includes the steps of mounting a free end of an external tube of the exchanger in or on the connector. The external tube is directly secured with the connector, and an internal tube is inserted in the external tube until a free end of the internal tube is mounted in or on the connector. This mounting ensuring a sealing between the internal tube and the connector. The method further includes directly securing the internal and external tubes against one another to avoid relative displacements.