A double pipe includes an outer pipe, an inner pipe, a fin member and a sealing part. The outer pipe has a plurality of outer crimping parts projecting to an inner diameter side and aligned in at least one of a lengthwise direction and a circumference direction. The inner pipe is arranged on an interior of the outer pipe with a flow path gap being defined between the outer pipe and the inner pipe. The inner pipe has a plurality of inner crimping parts aligned in the at least one of the lengthwise direction and the circumference direction and overlapping the outer crimping parts. The fin member is arranged on the interior of the inner pipe and held by the inner crimping parts. The sealing part seals between the outer pipe and the inner pipe.

A method of affixing a gasket to a flange of a heat exchanger core includes aligning the gasket with the flange of the heat exchanger core. The gasket includes a tab extending outward from the gasket. The flange of the heat exchanger core is contacted with the gasket. The gasket is secured to the flange by bending the tab of the gasket around an outer edge of the flange and such that relative motion between the gasket and the flange is prevented by the tab.

Shell and tube heat exchanger for exchanging heat between a first and second fluid, that comprises a housing in which tubes extend, whereby baffles are affixed in the housing that are provided with passages, whereby the tubes extend through the said passages, whereby the baffles are connected to one another at a distance from one another by means of one or more fastening elements that are affixed in first recesses in the baffles, whereby one or more connections between a baffle and a fastening element are formed by means of one or more lips that are made at an edge of a first recess, whereby the one or more lips form part of the baffle and are bent over, out of the plane defined by the baffle.

This disclosure details exemplary battery pack designs for use in electrified vehicles or other electrified components. An exemplary battery pack may include a heat exchanger plate assembly having a metallic plate and a polymeric plate that are joined together to establish a coolant circuit therebetween. The metallic plate or the polymeric plate may include a protrusion that extends through an opening of the other of the metallic plate or the polymeric plate. The protrusion may either be crimped or heat staked to a surface surrounding the opening in order to join together the metallic plate and the polymeric plate of the heat exchanger plate assembly.

The present invention relates to a heat exchanger (1) comprising: a heat exchange core bundle (3) in which a first heat-transfer fluid circulates, at least one inlet tank (5a) or outlet tank (5b) for a second heat-transfer fluid, at least one collector (7) arranged on the periphery of the heat exchange core bundle (3) and comprising a lateral wall (75) of which at least two portions (77) are folded over so as to fix the tank (5a, 5b) by crimping against the heat exchange core bundle (3),
the lateral wall (75) following the contour of at least one corner of the heat exchange core bundle (7), said lateral wall (75) comprising, on each side of the corner, a folded-over portion (77) and comprising in the region of said corner a non-folded-over portion (79), the folded-over portions (77) being connected continuously to the non-folded over portion (79).

A tank assembly for a heat exchanger includes a tank having a heat exchange end defining an opening and a reinforcement structure. The reinforcement structure has a shape substantially corresponding to a shape of an outer perimeter of the tank and disposed about the outer perimeter of the tank. The reinforcement structure is a sacrificial anode.

A heat exchanger has a core plate connected to a tank member by clamping claws. The tank member has a waved outer surface including outer ridge portions and outer valley portions which are disposed alternately. The tank member also has a waved inner surface including inner ridge portions and inner valley portions which are disposed alternately. The outer valley portions are capable of receiving the claws. The inner ridge portion is positioned inside the outer valley portion in a width direction. The inner ridge portion is positioned between the adjacent tubes and/or between extensions of the tubes in a height direction. An inner width of the tank member regulated by the inner ridge portions is narrower than a width of the tube.

An end tab for a heat exchanger frame includes a plate, an end, an expansion portion, and a bent portion. The plate has a first width, and the end has a second width larger than the first width. The expansion portion increases the width from the first width to the second width. The bent portion connects the plate and the end and includes at least one window.

The present invention relates to a heat exchanger (1) comprising: a tube bundle (2) comprising a plurality of tubes (2) placed parallel to one another, said tube bundle (2) comprising fins (6) placed between the tubes (2); two collectors (3), one collector (3) being placed on both sides of the tube bundle (2), each collector (3) comprising a collector plate (4), said collector plate (4) comprising orifices inside which the ends of the tubes (2) are introduced, and a rim (41) forming a groove (42) which is designed to receive a cover (8); and at least one reinforcement plate (10) placed between a collector plate (4) and the fins (6), parallel to the collector plate (4) and brazed against at least part of the tubes (2) of the tube bundle (2) and said collector plate (4),
the at least one reinforcement plate (10) comprising a lateral wall (101) which projects in the direction of the collector plate (4), and covers the rim (41) of the collector plate (4) at least partially, said lateral wall (101) being brazed against said rim (41) of the collector plate (4) in order to secure the reinforcement plate (10) on the collector plate (4).

A liquid to refrigerant heat exchanger includes an enclosed coolant volume that is at least partially defined by a plastic housing and by a metal closure plate. The metal closure plate can be part of a brazed assembly containing a continuous refrigerant flow path. The refrigerant flow path is disposed within the coolant volume, where heat can be transferred between the refrigerant within the refrigerant flow path and the liquid within the coolant volume. The plastic housing can at least partially surround the refrigerant flow path to at least partially bound a liquid flow path along a portion of the coolant volume. An inlet diffuser and an outlet diffuser can be mounted to the housing to direct the liquid through the housing. The plastic housing is sealingly joined to the closure plate along an outer periphery of the closure plate.