The present invention relates to an engine coolant cooling system for a vehicle, and provides an engine coolant cooling system for a vehicle, which can increase the heat-dissipation performance of a radiator if necessary without increasing the size of the radiator, securing the cooling performance of the coolant.

An apparatus is provided herein. The apparatus includes a support member, a supply channel, a return channel, a supply port to provide a fluid to the supply channel, a return port to receive the fluid from the return channel, at least two port fittings, a first sleeve, and a second sleeve. The first sleeve is connectable to one of the at least two port fittings and forms a fluid tight seal between the first sleeve and the supply channel. The second sleeve is connectable to the other of the at least two port fittings and forms a fluid tight seal between the second sleeve and the return channel.

A heat exchanger exchanges heat between refrigerant flowing inside and air flowing outside. The heat exchanger includes: an upstream-side flat tube; downstream-side flat tubes on a downstream side of the upstream-side flat tube in a direction of air flow; and a space formation member that defines a distribution space in which the refrigerant coming out of the upstream-side flat tube is distributed to the downstream-side flat tubes.

A heat exchanger (10) comprises: a first sub-heat exchanger (100), which has a first manifold (110), a second manifold (120), and at least two heat exchange tubes (130); and a second sub-heat exchanger (200), which has a third manifold (210), a fourth manifold (220), and at least one heat exchange tube (230), at least one of the heat exchange tubes (130) in the first sub-heat exchanger (100) being part of a flow path of the second sub-heat exchanger (200).

An outdoor heat exchanger includes a plurality of flat multi-hole tubes, a return header, a plurality of heat transfer fins, and a partition including a concave-convex portion on the leeward side. A space inside the return header to which the flat multi-hole tubes are connected is formed so as to cause a larger amount of refrigerant to flow on the upstream side than on the downstream side in an airflow direction.

A heat exchanger includes a plurality of conduits that extend between a first endplate and a second endplate. A first manifold is coupled to the first endplate to couple the first manifold to first ends of the plurality of conduits. An inlet is coupled to the first manifold to direct a first fluid into the first manifold and at least one baffle is disposed within the first manifold to form a first cavity and a second cavity. The at least one baffle of the first manifold is configured to direct the first fluid from the inlet to a first conduit of the plurality of conduits. A second manifold is coupled to the second endplate to couple the second manifold to second ends of the plurality of conduits and at least one baffle is disposed within the second manifold to form a fourth cavity and a fifth cavity.

A thermostatic garment being heated and cooled by a power supply and includes a thermostatic garment body. A first heat exchange water pipe network and a second heat exchange water pipe network are arranged on the thermostatic garment body in a laying manner. A thermoelectric cooler, an electric heating sheet, a controller, a power supply, a first water pump, a second water pump, a first heat conducting water tank, and a second heat conducting water tank are arranged outside the thermostatic garment body. The first heat conducting water tank is provided with a first temperature sensor, and the first temperature sensor is electrically connected to an input end of the controller. Output ends of the controller is further electrically connected to the thermoelectric cooler, the electric heating sheet and the water pump respectively. The electric heating sheet is connected to the first heat conducting water tank.

A distributer includes a housing having a surface portion and through holes extending through the surface portion, a plurality of plates stacked with each other in the housing, the plurality of plates including a first plate that is an outermost one of the plurality of plates and has a first opening extending through the first plate, and a second plate that is the other outermost one of the plurality of plates and has a plurality of second openings extending through the second plate, a branching flow path connecting the first opening and the plurality of second openings, a plurality of connection pipes each extending through a corresponding one of the through holes in the surface portion of the housing, and a partition plate disposed between the surface portion and the second plate, and abutting on both the surface portion and the second plate.

A heat exchanger includes a plurality of conduits that extend between a first endplate and a second endplate. A first manifold is coupled to the first endplate to couple the first manifold to first ends of the plurality of conduits. An inlet is coupled to the first manifold to direct a first fluid into the first manifold and at least one baffle is disposed within the first manifold to form a first cavity and a second cavity. The at least one baffle of the first manifold is configured to direct the first fluid from the inlet to a first conduit of the plurality of conduits. A second manifold is coupled to the second endplate to couple the second manifold to second ends of the plurality of conduits and at least one baffle is disposed within the second manifold to form a fourth cavity and a fifth cavity.

A heat exchanger for an air conditioner includes a plurality of flat heat transfer tubes through which a refrigerant flows; first and second headers disposed on opposite ends of the plurality of flat heat transfer tubes; at least one baffle disposed in at least one of the first and second headers and to partition an inner space of the at least one header; and a refrigerant flow control device disposed on the at least one baffle, to allow the refrigerant to selectively pass through the at least one baffle. The refrigerant flow control device is configured to prevent refrigerant from passing through the refrigerant flow control device when the refrigerant flows in one direction in the header, and to allow the refrigerant to pass through the refrigerant flow control device when the refrigerant flows in a direction opposite to the one direction in the header.