A heat management assembly includes a valve component and a heat exchange core body. The heat exchange core body and the valve component are fixedly connected by welding. The valve component further includes a sensor. The sensor is electrically connected to a circuit board. The sensor at least partially extends into a third flow channel. The sensor can measure the temperature and/or pressure of a working medium in the third flow channel. The heat exchange core body at least includes a positioning portion. A valve at least includes a matching portion. The positioning portion and the matching portion are provided to correspondingly match each other. The sensor, the valve component, and the heat exchange core body are integrally assembled to facilitate relative reduction of connections of pipelines and sensor lines, thereby facilitating structure simplification and facilitating mounting.

Tool-less apparatus and methods are provided for sealing flow of cooling air from the outlet of a cooling fan blower to the inlet of a heat exchanger within a chassis enclosure of an information handling system. The disclosed apparatus and methods may be implemented in a tool-less manner by employing tool-less chassis mounting features that mate with tool-less cooling fan mounting features to mechanically align and secure an air outlet of a cooling fan blower in sealing relationship with an air inlet of a heat exchanger within a chassis enclosure of an information handling system by properly aligning the axes of a cooling fan in relation to the inlet of the heat exchanger so that in on embodiment no gap exists between the cooling air outlet of the cooling fan and the cooing air inlet of the heat exchanger.

A tube stiffener for insertion into a plurality of radiator tubes includes a plurality of inserts and first and second connection strips. Each insert is configured to extend into at least one of the plurality of radiator tubes to strengthen the plurality of radiator tubes. The plurality of inserts include a first end and a second end and a tab projecting from each of the first end and the second end. The first connection strip is fixed to the tab on the first end and the second connection strip is fixed to the tab on the second end. Each of the connection strips connects the plurality of inserts to each other.

A heat exchanger for a motor vehicle includes a seal and a core. The core includes a first groove formed in a first side and a second groove formed in an opposing second side. The first groove and the second groove are each configured to receive a portion of the seal to secure the seal to the core. The seal includes a cross member and a pair of uprights extending from opposing ends of the cross member, wherein the cross member and the uprights each include a sealing element. The uprights further include a rail extending from the upright and configured to be received in the groove of the core. The core further includes an integrated shear panel formed at opposing ends thereof.

A mount for connecting a heat sink to a PCB may include a threaded post extending along an axis, a first barrel adjacent to the post along an axis and having a larger axial cross-section than the post, and a threaded second barrel defining an opposite end of the mount from the post and having a larger axial cross-section than the first barrel.

Lining to be positioned in a frame plate of heat exchanger comprising a stack of heat transfer plates, where the lining comprises a tubular part with a first end formed with a first flange and second flange positioned at a distance to the second end, where the second flange is adapted to form a platform to accommodate a sealing element is positioned on the platform of the second flange and this confined between the edge of the recess, the second flange and the outer section and the neighbouring heat transfer plate in the stack of heat transfer plates.

A heat exchanger module includes a first heat exchanging body including at least one first through hole and a second heat exchanging body including at least one second through hole. The second heat exchanging body is configured to be coupled to the first heat exchanging body, and an accommodation hole is provided between the first heat exchanging body and the second heat exchanging body by the first heat exchanging body and the second heat exchanging body being coupled together.

The present invention relates to a heat exchanger (1) comprising an inlet duct (31) and an outlet duct (32) for a heat transfer fluid, onto which ducts a supply pipe (21) and a discharge pipe (22) for the heat transfer fluid are respectively intended to be inserted.

According to the invention, the inlet duct (31) and the outlet duct (32) each have, on their outer surface, means for sealing and retaining the corresponding pipe (21, 22), and a collar (34) forming a stop for limiting the insertion of the pipe (21, 22) onto the corresponding duct (31, 32).

Lining to be positioned in a frame plate of heat exchanger comprising a stack of heat transfer plates, where the lining comprises a tubular part with a first end formed with a first flange and second flange positioned at a distance to the second end, where the second flange is adapted to form a platform to accommodate a sealing element is positioned on the platform of the second flange and this confined between the edge of the recess, the second flange and the outer section and the neighbouring heat transfer plate in the stack of heat transfer plates.

A carrying module configured to carry a functional assembly includes a main casing, a cover, a stop assembly, and an assist assembly. The cover is detachably assembled to the main casing. The stop assembly is disposed on the main casing and has a stop portion. The stop portion is adapted to stop the cover on an assembling path of the cover. The assist assembly is disposed on the main casing and contacts the stop assembly, such that the stop portion is away from the assembling path of the cover. In addition, an electronic device including the carrying module is also provided.