A heat transfer device including a body bounding a cavity for receiving a heat transfer medium, an inlet, and an outlet for providing a fluid connection to the cavity is provided. Interconnecting elements are provided at each of the inlet and outlet for providing a fluid connection to the inlet and the outlet. At least one interconnecting element is configured to interconnect with, and provide relative movement between and a substantially consistent fluid connection with, an interconnecting element of an adjacent device, such as a similar heat transfer device, over a range of spacing between bodies of the devices.

The present disclosure provides a liquid-cooling type double-sided cooler, including a first cooling portion and a second cooling portion. In the liquid-cooling type double-sided cooler, another end of the first cooling portion is formed with a first communication hole that is configured to penetrate the first cooling liquid path and an outside of the first cooling portion, another end of the second cooling portion is formed with a second communication hole that is configured to penetrate the second cooling liquid path and an outside of the second cooling portion; and the first cooling portion and the second cooling portion are positioned such that the first communication hole and the second communication hole face each other, and the first cooling liquid path and the second cooling liquid path are connected with each other.

The present disclosure provides a liquid-cooling type double-sided cooler, including a first cooling portion and a second cooling portion. In the liquid-cooling type double-sided cooler, another end of the first cooling portion is formed with a first communication hole that is configured to penetrate the first cooling liquid path and an outside of the first cooling portion, another end of the second cooling portion is formed with a second communication hole that is configured to penetrate the second cooling liquid path and an outside of the second cooling portion; and the first cooling portion and the second cooling portion are positioned such that the first communication hole and the second communication hole face each other, and the first cooling liquid path and the second cooling liquid path are connected with each other.

A sectional radiator seal arrangement including a sectional radiator having a core and a bonnet, a nozzle defined by a cylindrical sidewall extending from and in fluid communication with the bonnet and the core, the nozzle configured for creating a seal with a radiator tank and a sleeve formed from a corrosion resistant material fitted about a portion of the cylindrical sidewall of the nozzle. A retaining compound can be provided between the sleeve and the radiator tank for preventing an ingress of coolant at the seal and into contact with either the nozzle or the bonnet. A method of reducing corrosion of the radiator seal also is provided.

The invention relates to a radiator attachment for attaching a radiator to a motor vehicle. In detail, the radiator attachment comprises a tank bottom, from which a spreading element, formed in a clamp-like manner, projects transversely, preferably perpendicularly, along an axial direction. The radiator attachment further comprises a detent body, extending along the axial direction and surrounding a body interior, from which detent body two inner detent elements project into the body interior. At least one outwardly projecting detent hook projects at a first of the two axial ends. Here, the spreading element of the tank bottom, received in the body interior, is engaged with the two inner detent elements. The radiator attachment further comprises a socket of an elastomer, in particular of a rubber, extending along the axial direction and lying externally against the detent body, which socket is engaged with the at least one detent hook.

The present invention relates to a strengthened radiator comprising a collector and a water tank, the water tank being provided with a wall (40) and a base (50), a plurality of plates (10) located inside the water tank, wherein each plate (10) comprises a plurality of extensions (20, 20, 20, 20) having a predetermined format; the base (50) of the wall (40) of the water tank being provided with a plurality of slots (30) having a format corresponding to that of the plurality of extensions (20, 20, 20, 20), wherein each extension of the plurality of extensions engages each slot of the corresponding plurality of slots.

A water-cooling radiator assembly with internal horizontal partition members and fluid disturbing members includes a liquid-receiving plate unit consisting of a first liquid-receiving plate having a first partition member provided therein to divide an inner space thereof into a first and a second liquid chamber communicable with at least one liquid inlet, and a second liquid-receiving plate having a second partition member provided therein to divide an inner space thereof into a fourth liquid chamber and a third liquid chamber communicable with at least one liquid outlet; a first flow disturbing member selectively arranged in any one of the first, second, third and fourth liquid chambers; and a communicating pipe unit including a first, a second and a third communicating pipe to communicate the second with the fourth liquid chamber, the fourth with the first liquid chamber, and the first with the third liquid chamber, respectively.

A heat exchanger including (a) a fluid conductor including a heat exchange tubing including a first end and a lumen; and (b) a first connecting tubing including an outer surface, a lumen and a first sealing ring disposed about the outer surface of the first connecting tubing, wherein the first connecting tubing is configured for insertion into the lumen of the heat exchange tubing at the first end such that the first sealing ring comes in sealing engagement with the first connecting tubing and the heat exchange tubing while allowing relative movement between the heat exchange tubing and the first connecting tubing and a fluid flow is confined within a lumen formed of the lumen of the first connecting tubing and the lumen of the heat exchange tubing.

The present disclosure provides a liquid-cooling type double-sided cooler, including a first cooling portion and a second cooling portion. In the liquid-cooling type double-sided cooler, another end of the first cooling portion is formed with a first communication hole that is configured to penetrate the first cooling liquid path and an outside of the first cooling portion, another end of the second cooling portion is formed with a second communication hole that is configured to penetrate the second cooling liquid path and an outside of the second cooling portion; and the first cooling portion and the second cooling portion are positioned such that the first communication hole and the second communication hole face each other, and the first cooling liquid path and the second cooling liquid path are connected with each other.

Disclosed is a method for producing a plate-shaped heat exchanger for batteries or converters for generating electricity, to a plate-shaped heat exchanger for batteries or converters for generating electricity, and to an assembly of plate-shaped heat exchangers and converter or battery cells. A plate-shaped heat exchanger includes two frame parts, which peripherally surround one profiled heat-conducting element each, wherein the profiles of the profiled heat-conducting elements form channels in the connected state of the frame parts, through which channels a fluid can be conducted. In the connected state, the frame parts form at least two supply channels for feeding and leading away of fluid, from which supply channels openings extend to the channels of the profiled heat-conducting elements. The frame parts have at least one connection for the feeding and leading away of fluid for each supply channel, which connection can be connected to a connection of a frame part of a further heat exchanger.