Heat exchanging module (1) comprising at least a heat exchanger (2) between two fluids and a housing (6), said housing (6) having at least an inner frame (20) and an outer frame (60), the inner frame (20) being arranged for holding the heat exchanger (2), the outer frame (60) being arranged for holding the inner frame (20), characterized in that the inner frame (20) and the outer frame (60) are separated by a non-null distance (100) configured to form a thermal isolation between the heat exchanger (2) and a surrounding environment of the housing (6).

A radiator assembly includes a frame and a radiator mounted to the frame proximate a front of frame and defining a radiator plane extending along a front surface of the radiator. Each of a plurality of fans is mounted to the frame rearwardly of the radiator, with each fan defining a fan rotation axis that extends outwardly and rearwardly away from the frame.

A heat exchanger including a mounting portion for fixing to further structures. The mounting portion has an elastic element with a core and a plurality of contact arms attached to the core and protruding away from the core in the same protrusion plane. Protrusion path of each contact arm is at least partially curved.

A device for transferring heat from a device component to an environment includes a heat plate connected to a spring. A first fastener attaches the spring to the heat plate at a first location. A second fastener, such as a rivet, attaches the spring to the heat plate at each of a second and a third location. The second fastener includes a tab on and extending above the heat plate and corresponding tab slot on the spring. The spring is riveted to the heat plate at the first location and a second spring member accepts the tab at each of the second location and the third location. Ribs on a top surface of spring facilitate thermal coupling of the spring to the component when the device is assembled. One or more spring curvatures facilitate vertical deflection and horizontal extension of the spring during device assembly.

A heat exchanger includes an inlet tank (10a) connected to and in fluid communication with an inlet pipe (12a) for ingress of a coolant therein, an outlet tank (10b) connected to and in fluid communication with an outlet pipe (12b) for egress of coolant there from. The heat exchanger further includes heat exchange tubes (20) and a tubular element (30) to configure fluid communication between the inlet tank (10a) and the outlet tank (10b). A first side of the outlet tank (10b) is complimentary to and connected to the outlet pipe (12b) and an opposite second side of the outlet tank (10b) is complimentary to and aligned with the tubular element (30). The tubular element (30) and the outlet pipe (12b) are of different cross sections, wherein shape of the outlet tank (10b) transforms smoothly between those cross sections along fluid path.

An embodiment of a heat exchanger assembly includes a first manifold adapted for receiving a first medium, a core adapted for receiving and placing a plurality of mediums, including the first medium, in at least one heat exchange relationship, and a core meeting the first manifold at a first core/manifold interface; The mounting structure supports a heat exchanger, and is metallurgically joined to at least one heat exchanger assembly component at a first joint integrally formed with the mounting structure.

A header for a heat exchanger includes a first and a second cylindrical fluid manifold extending in parallel. Each of the first and second manifolds have tube slots that extend through an arcuate wall section of the manifold. A thickened wall section of the header having a generally triangular wall section is bounded by the first and second fluid manifolds and by a planar outer surface of the header. An aperture extends through the thickened wall section to provide a fluid communication pathway between the first and second cylindrical fluid manifolds.

A shroud assembly can include a support frame with a locking slot and a hinge slot, and a shroud with a first pin and a second pin. The locking slot can receive the first pin to secure the shroud in a closed configuration. The hinge slot can receive the second pin to support the shroud in the closed configuration, in an open configuration, and during hinging of the shroud between the closed and open configurations. A tab can engage a notch to support the shroud at a predetermined angle relative to the support frame when the shroud is in the open configuration.

A system and method for attaching two automotive cooling modules together is provided. A first cooling module has a tab extending outwardly therefrom, the tab having an aperture extending therethrough. A second cooling module has a backwall and one or more flexible prongs extending in a first direction from the backwall and through the aperture of the tab in a snap-fit attachment. The tab is spaced from the backwall when the one or more prongs are attached to the tab. The second cooling module also has a boss extending in a second direction from the backwall, wherein the boss has a receptacle aligned with the aperture of the tab. In the event of damage to the one or more prongs, the one or more prongs can be removed, and a fastener can be fastened through the aperture of the tab and into the boss.

A heat exchanger includes first and second fluid circuits. The first fluid circuit is formed by a first set of fins, a first inlet header, and a first outlet header. The first set of fins extend radially and are coaxial with each other. The first inlet header is fluidly connected to and is disposed on an upstream end of the first fins. The first outlet header is fluidly connected to and is disposed on a downstream end of the first fins. The second fluid circuit is formed by a second set of fins, a second inlet header, and a second outlet header. The second fins extend radially and are coaxial with each other. An annular shape of the second inlet header conforms to the circular shape of the first inlet header. An annular shape of the second outlet header conforms to the circular shape of the first outlet header.