A heat exchanger tank that includes external ribs that provide reinforcement to structure of the heat exchanger tank is disclosed. In addition, at least one reinforcement element may engage with an external tank portion and may be tensioned by press fitting the at least one reinforcement element on the external tank portion such that limbs of the at least one reinforcement element are separated by the external tank portion between the external ribs. The at least one reinforcement element may further be maintained in the tensioned configuration by using at least one retention means.

Heat exchanger (2, 3) for a refrigerant circulation circuit comprising at least one connection flange (5, 6) fixed to a lateral surface of said heat exchanger (2, 3), characterized in that the connection flange (5, 6) comprises a circulation channel within its structure and a transverse mechanical fixing zone (21, 22) able to cooperate with another transverse mechanical fixing zone (21, 22) of another connection flange (5, 6) of another heat exchanger (2, 3).

The invention also claims a heat exchange system for a vehicle comprising two such heat exchangers (2, 3) and the respective connection flanges (5, 6) of which are able to cooperate with one another.

A heat exchanger for flammable refrigerants has a housing in which refrigerant lines are situated. The housing is provided with fins on the inside of a closed side face, and at least a portion of the outside of the closed side face can be brought into operative connection with a passenger compartment of a vehicle. The housing is designed as a module which can be partitioned off from the passenger compartment in a gas-tight manner, where only permanently sealed sections of the refrigerant lines are situated in the interior of the housing, the connection points of which refrigerant lines are each situated completely outside the housing. The housing has sealing frame and/or sealing plates such that the connections of the refrigerant lines are sealed off from the passenger compartment and are ventilated outward to the surroundings.

A heat exchanger (1) includes a heat exchanging body (20) disposed within an outer box (10). A supply pipe (21) and a discharge pipe (22) in fluid communication with the heat exchanging body (20) respectively extend through first and second insertion holes (31, 32) in the outer box (10). Elastic seal members (40; 240) are respectively provided around the supply pipe (21) and the discharge pipe (22) and between a first sidewall (11) of the outer box (10) and the heat exchanging body (20). At least one biasing member (50; 250) exerts a lateral biasing force (F1; F2) on the elastic seal members (40; 240), thereby maintaining the elastic seal members (40; 240) in a state of compressive deformation and contacting the outer box (10) and the heat exchanging body (20) in an air-tight manner to block potential leakage paths (LP1; LP2) via the insertion holes (31, 32).

A heat exchanger assembly includes a heat exchanger panel disposed at an inclined orientation. A fan assembly is disposed vertically above the heat exchanger panel and includes a fan impeller connected to a fan mount. The fan impeller is sized and positioned such that part of the fan impeller rotates vertically above the upper end of the heat exchanger panel. A casing has a plurality of inner walls for guiding air from the heat exchanger panel toward the fan assembly. The inner walls include a sloped wall. A distance between an upper end of the sloped wall and a fan rotation axis is greater than a distance between a lower end of the sloped wall and the fan rotation axis. The sloped wall is adjacent to the upper end of the heat exchanger panel such that the part of the fan impeller rotates vertically above the sloped wall.

A heat exchanger module adapted for being mounted directly to the outer surface of the housing of an automobile system component, such as a transmission or engine housing, is provided. The heat exchanger module has a heat exchanger fixedly attached to an adapter module. The adapter module contains one of more fluid transfer channels and includes a portion that extends outwardly beyond the footprint of the heat exchanger. The adapter module is comprised of a first embossed plate that is sealed with a second plate, which may also be embossed. The embossments provide fluid transfer channels and also perform as structural ribs to enhance the rigidity of the adapter module.

A heat exchanger for abating compounds produced in semiconductor processes. When hot effluent flows into the heat exchanger, a coolant can be flowed to walls of a fluid heat exchanging surface within the heat exchanger. The heat exchanging surface can include a plurality of channel regions which creates a multi stage cross flow path for the hot effluent to flow down the heat exchanger. This flow path forces the hot effluent to hit the cold walls of the fluid heat exchanging surface, significantly cooling the effluent and preventing it from flowing directly into the vacuum pumps and causing heat damage. Embodiments described herein also relate to methods of forming a heat exchanger. The heat exchanger can be created by sequentially depositing layers of thermally conductive material on surfaces using 3-D printing, creating a much smaller footprint and reducing costs.

The disclosure relates to a heat dissipation system including cabinet, coolant distribution units and adapting device. The adapting device includes casing and switch valves. The casing has first liquid inlets, first liquid outlets, second liquid inlet and second liquid outlet. The first liquid inlets are connected to distribution outlets of coolant distribution units, first liquid outlets are connected to distribution inlets of coolant distribution units, second liquid inlet is connected to cabinet, and second liquid outlet is connected to cabinet. The switch valves are connected to first liquid inlets, first liquid outlets, second liquid inlet and second liquid outlet so as to change a connection among first liquid inlets, first liquid outlets, second liquid inlet and second liquid outlet to change a connection between coolant distribution units.

A reinforced polymer-based compound comprises a base material, and at least one of a reactive flame-retardant material, an additive flame retardant material, an intumescent material coating, an antimicrobial agent, an ultraviolet light stabilizer and a ceramic coating, wherein the reinforced polymer-based compound is configured to withstand a first temperature range.

A method of forming a membrane panel configured to be secured within an energy exchange assembly may include forming an outer frame defining a central opening, and integrating a membrane sheet with the outer frame. The membrane sheet spans across the central opening, and is configured to transfer one or both of sensible energy or latent energy therethrough. The integrating operation may include injection-molding the outer frame to edge portions of the membrane sheet. Alternatively, the integrating operation may include laser-bonding, ultrasonically bonding, heat-sealing, or the like, the membrane sheet to the outer frame.