Provided is a heat exchange device that facilitate assembling of a plurality of heat exchangers. The heat exchange device having a first heat exchanger and a second heat exchanger arranged adjacent to each other so that surfaces of the heat exchangers face each other. A first mounting plate fixed to the side surface of the first heat exchanger, and a second mounting plate fixed to the side surface of the second heat exchanger are fastened and fixed to each other so as to face each other. The first mounting plate has a space of a size such that the second mounting plate can be fixed to the first mounting plate so as to face each other. Insertion holes are formed in the space so as to receive therein tube ends of refrigerant tubes in a plurality of stages, the tube ends laterally projecting from the second mounting plate.

A heat exchange system includes a first heat exchanger that radiates heat of at least a cooling cycle, a cooler circuit in which a coolant for a heat-emitting device flows, a plurality of heat exchangers that are connected to the cooler circuit and radiate heat of the coolant, and a blower that sends air to the first heat exchanger and the plurality of heat exchangers to cool. The plurality of heat exchangers are arranged in a blowing direction of the blower, and separately radiate heat of the cooler circuit. The heat exchanger, which is disposed on the windward side, of the plurality of heat exchangers is thermally connected to the first heat exchanger, and the heat exchanger disposed on the windward side radiates heat by itself and also radiates heat through the first heat exchanger.

A microchannel type heat exchanger is provided. The heat exchanger may include a first heat exchanger and a second heat exchanger, in which a plurality of flat tube may be provided. The heat exchanger may include a first path defined in a first portion of the plurality of flat tubes provided in the first heat exchanger, the first path being configured such that a refrigerant flows in a first direction, a second path defined in a second portion of the plurality of flat tubes provided in the first heat exchanger, the first path being configured such that the refrigerant, supplied from the first path, flows in a second direction opposite to the first direction, a third path defined in a remaining portion of the plurality of flat tubes provided in the first heat exchanger and a portion of the plurality of flat tubes provided in the second heat exchanger, the third path being configured such that the refrigerant, supplied from the second path, flows in a third direction opposite to the second direction, and a fourth path defined in a remaining portion of the plurality of flat tubes provided in the second heat exchanger, the fourth path being configured such that the refrigerant, supplied from the third path, flows in a fourth direction opposite to the third direction.

A multi-step method is disclosed for exchanging heat in a vapor compression heat transfer system having a working fluid circulating therethrough. The method includes the step of circulating a working fluid comprising a fluoroolefin to an inlet of a first tube of an internal heat exchanger, through the internal heat exchanger and to an outlet thereof. Also disclosed are vapor compression heat transfer systems for exchanging heat. The systems include an evaporator, a compressor, a dual-row condenser and an intermediate heat exchanger having a first tube and a second tube. A disclosed system involves a dual-row condenser connected to the first and second intermediate heat exchanger tubes. Another disclosed system involves a dual-row evaporator connected to the first and second intermediate heat exchanger tubes.

A multi-step method is disclosed for exchanging heat in a vapor compression heat transfer system having a working fluid circulating therethrough. The method includes the step of circulating a working fluid comprising a fluoroolefin to an inlet of a first tube of an internal heat exchanger, through the internal heat exchanger and to an outlet thereof. Also disclosed are vapor compression heat transfer systems for exchanging heat. The systems include an evaporator, a compressor, a dual-row condenser and an intermediate heat exchanger having a first tube and a second tube. A disclosed system involves a dual-row condenser connected to the first and second intermediate heat exchanger tubes. Another disclosed system involves a dual-row evaporator connected to the first and second intermediate heat exchanger tubes.

A heat exchanger includes a leeward heat exchange unit disposed downstream in an air flow direction, a windward heat exchange unit, and a common header. The leeward heat exchange unit includes a first header, the windward heat exchange unit includes a second header, and, when the leeward heat exchange unit and the windward heat exchange unit each function as a condenser, the leeward heat exchange unit and the windward heat exchange unit include a first region in which refrigerant flowing into the first header flows against the air flow direction and flows into the second header, a second region in which the refrigerant flows parallel to the air flow direction and flows into the first header, and a third region in which the refrigerant flows against the air flow direction and flows into the second header.

A radiator arrangement for a motor vehicle the motor vehicle is driven by an internal combustion engine or at least partially electrically, with a first heat exchanger that is connected to a coolant circuit of the motor vehicle; and with a second heat exchanger that is connected to a refrigerant circuit of the motor vehicle. With respect to a main direction of an air flow through the radiator arrangement, the first heat exchanger is arranged in front of the second heat exchanger, and a first base area of the first heat exchanger that is exposed to the air flow is smaller than a second base area of the second heat exchanger that is exposed to the air flow. The first base area is dimensioned such that it overlaps the second base area only in an inlet-side region with respect to the refrigerant flow in the second heat exchanger.

A cooling assembly configured to provide a heat exchange between the fluids comprising: at least one first heat exchanger comprising a pair of first manifolds comprising an axis of elongation of the first manifolds, and a plurality of first tubes stacked between the first manifolds, each first tube comprising an axis of elongation of the first tubes which is substantially perpendicular to axis of elongation of the first manifolds. The axes form the general plane of the first heat exchanger, at least one second heat exchanger comprising a pair of second manifolds comprising an axis of elongation of the second manifolds, and a plurality of second tubes stacked between the second manifolds, each second tube comprising an axis of elongation of the second tubes which is substantially perpendicular to axis of elongation of the second manifolds.