This patent disclosure relates generally to heat exchangers and, more particularly, to heat exchangers incorporating end structures of elastomeric character sealingly enclosing a heat exchanger adapted to provide flow reversal transition zones along the length of a tube bundle.
Heat exchangers may be used for a variety of applications and may encompass a number of different forms. By way of example only, oil coolers for internal combustion engines often take the form of an elongate housing which surrounds a tube bundle of substantially discrete heat exchange tubes. The tubes are often packed in a generally hexagonal pattern such that each tube is surrounded by up to six other tubes. Of course, other patterns may also be utilized. The tube bundle is installed through heat conducting fins and/or flow-directing baffles, and may be supported by the baffles and the conducting fins that are arranged in the housing to create a serpentine flow path between an inlet to the housing and an outlet.
Exemplary prior heat exchange devices are illustrated and described in U.S. Pat. No. 7,243,711 to Amstutz et al. having an issue date of Jul. 17, 2007. Embodiments of heat exchangers disclosed in this reference have a construction adapted to provide highly efficient cooling. In particular, this reference discloses a heat exchanger having a housing which defines a heat exchanging cavity within which a tube bundle is positioned. The tube bundle is made of a plurality of tubes arranged in a defined pattern. A disclosed embodiment utilizes an arrangement of baffles to support the tube bundle. The tube bundle, baffles and the housing define a serpentine flow path between an inlet and an outlet. The serpentine flow path includes a plurality of segments that are generally perpendicular to the tubes. These segments are separated by flow direction changing windows. At the flow direction changing windows, the tube bundle is separated from the housing by a gap distance which is relatively large. At positions removed from the flow direction changing windows, the tube bundle is separated from the housing by a substantially smaller gap distance. The ends of the housing are plugged by conventional techniques such as end structures of a resilient material surrounding the tubes of the tube bundle and extending to the housing. This arrangement is adapted to seal the heat exchange chamber against leakage when subjected to internal operating pressures. However, as internal pressures and/or gap distances are increased, sealing may become more difficult. Accordingly, a construction which provides support to the end structure within zones between the tube bundle and the housing while maintaining a good sealing relation is desirable.
The disclosure describes, in one aspect, a heat exchanger. The heat exchanger includes a housing having an internal wall defining a portion of a heat exchanging cavity. A tube bundle including a plurality of tubes is disposed in the housing. At least one resilient end structure is disposed in compressed, plug-forming relation at least partially across the heat exchanging cavity in transverse relation to at least a portion of the tubes forming the tube bundle. The heat exchanger utilizes a serpentine flow path including a plurality of flow direction changing windows. The perimeter of the tube bundle is separated from the internal wall by a window distance at the flow direction changing windows. The resilient end structure includes at least one boundary segment extending between the internal wall and the perimeter of the tube bundle. The boundary segment includes at least a first zone formed from a first material characterized by a first compressive modulus of elasticity. The boundary segment also includes at least a second zone formed from a second material characterized by a second compressive modulus of elasticity. The second compressive modulus of elasticity is greater than said first compressive modulus of elasticity.
In another aspect, this disclosure describes a method of assembling a heat exchanger. The method includes providing a housing having an internal wall defining a portion of a heat exchanging cavity. The method further includes providing a tube bundle including a plurality of tubes and disposing the tube bundle within the housing. The housing is sealed with at least one resilient end structure disposed in compressed, plug-forming relation at least partially across the heat exchanging cavity in transverse relation to at least a portion of the tubes. The end structure includes at least one boundary segment disposed between the internal wall and the tube bundle. The boundary segment includes at least a first material of elastomeric character characterized by a first compressive modulus of elasticity in combination with at least a second material characterized by a second compressive modulus of elasticity. The second compressive modulus of elasticity is greater than the first compressive modulus of elasticity.
In another aspect, a containment unit is provided. The containment unit includes a structure including an opening. A sealing member is disposed within the opening. The sealing member includes an internal portion and at least one boundary segment. The boundary segment includes at least a first material of elastomeric character characterized by a first compressive modulus of elasticity in combination with at least a second material characterized by a second compressive modulus of elasticity. The second compressive modulus of elasticity is greater than said first compressive modulus of elasticity.
This disclosure relates to a heat exchanger having a tube bundle disposed within a housing with a resilient end structure disposed in compressed, plug-forming relation at least partially across the heat exchanging cavity. The resilient end structure includes one or more boundary segments extending between an internal wall of the housing and the perimeter of the tube bundle. The boundary segment includes a combination of materials having differing compression characteristics providing enhanced support to the boundary segments.
Reference will now be made to the drawings, wherein like reference numerals designate like elements in the various views.
In the exemplary construction, the heat exchanger 12 includes a structure or housing 14 with an inlet 16 and an outlet 18. Housing 14 may be made in any suitable manner using known materials. By way of example only, one suitable construction material may be cast aluminum which is machined to arrive at a final form. The housing 14 includes an inlet 16 and an outlet 18 for oil or other fluid to be cooled. A tube bundle 20 formed from a plurality of tubes 21 (
As best seen in
Referring jointly to
As shown, heat exchanger 12 incorporates an exemplary end structure 50 of compressible character for use in sealing the heat exchanging cavity 24. The end structure 50 is disposed in compressed, plug-forming relation across the interior of housing 14. The illustrated exemplary end structure 50 includes a matrix of resilient material disposed in surrounding relation to the tubes 21 at an interior portion 52 of end structure 50. The matrix of resilient material includes portions inboard of the perimeter set of tubes 26. By way of example only, and not limitation, resilient materials forming the matrix may include elastomers such as, chloroprene, silicone, EPDM (ethylene propylene diene monomer), FKM (FKM flouroelastomers), polyurethane, HNBR (hydrogenated nitrile rubber) or the like. The illustrated exemplary end structure 50 also includes a pair of boundary segments 56 disposed between the tube bundle 20 and the internal wall 22 of housing 14. As shown, the boundary segments 56 are substantially axially aligned with the cross-sectional dimension of flow direction changing windows 30 such that the size and shape of the boundary segments 56 correspond generally to the cross-sectional configuration of flow direction changing windows 30. However, other geometries may likewise be used if desired. In this regard, it is to be understood that while the illustrated end structure 50 includes a pair of boundary segments 56, it is likewise contemplated that end structure 50 may include any number of boundary segments of varying shapes and sizes arranged at different positions around the tube bundle 2D.
Regardless of the location or shape of the boundary segments 56, it is contemplated that one or more of such boundary segments 56 will be a composite structure including zones characterized by different stiffness levels. In particular, at least one of the boundary segments 56 includes one or more reduced modulus zones 60 formed from a material such as an elastomer or the like characterized by a first compressive modulus of elasticity. The boundary segment 56 also includes one or more enhanced modulus zones 62 formed from a material characterized by a second compressive modulus of elasticity which is greater than that of the material forming the reduced modulus zones 60. As will be understood by those of skill in the art, a material with a higher compressive modulus is more rigid and provides greater resistance to elastic deformation under compressive loading conditions. Thus, at a comparable compression level, the reduced modulus zones 60 are susceptible to greater elastic deformation than the enhanced modulus zones 62. The enhanced modulus zones 62 may be substantially incompressible or may have limited compressibility relative to the reduced modulus zones 60. The reduced modulus zones 60 and the enhanced modulus zones 62 may be arranged in substantially adjacent relation to one another at positions across the boundary segment 56.
By way of example only, in the arrangement illustrated in
It is also contemplated that any number of other arrangements may be utilized to provide a combination of substantially compressible zones and reduced compression zones across boundary segments of a heat exchanger end structure. By way of example only,
It has been found that the presence of enhanced modulus zones at positions across boundary segments of a resilient end structure assists in supporting the boundary segments. This added support aids in the ability to extend the distance between a tube bundle and the housing and/or to increase the pressure within the heat exchanging cavity. Without being limited to a particular theory, it is theorized that the presence of the enhanced modulus zones at positions across the boundary segments facilitates enhanced uniformity of stress distribution across the end structure. The compressive forces applied by the surrounding housing are thus directed throughout the end structure thereby avoiding low compression regions and thus providing improved stability to the overall structure.
It is also contemplated that multi-zone sealing elements consistent with this disclosure may find application in environments other than heat exchangers. In this regard, such devices may find application as sealing structures in any number of pressurized or unpressurized containment units. By way of example only, such containment units may include various storage tanks, chemical reaction vessels and the like which require a good sealing relation across a structure opening.
The industrial applicability of a heat exchanger or other unit consistent with the present disclosure will be readily appreciated from the foregoing discussion. In this regard, the present disclosure relating to a heat exchanger applies to virtually any heat exchanging environment utilizing a tube bundle within a housing and incorporating a resilient sealing member with segments of the sealing member extending outboard from a perimeter of the tube bundle. Heat exchangers consistent with the present disclosure may be used to cool fluids such as water, oil, air or the like. Such heat exchangers may find particular application in environments where heat transfer is carried out using a serpentine flow path through the heat exchanger.
In practice, a heat exchanger consistent with this disclosure may be utilized in environments such as industrial equipment, on highway vehicles and the like where space is limited and where substantial cooling efficiency is required. In such environments, the use of a serpentine flow path through a housing incorporating relatively large flow direction changing windows may provide enhanced cooling efficiency. A resilient end structure may be used to effectively seal the heat exchanging cavity against leakage. Incorporating and or dispersing materials having relatively high levels of compressive modulus of elasticity within boundary segments of the resilient end structure provides enhanced stability while maintaining a compressive perimeter sealing relationship between the resilient end structure and the housing.
In addition to use within a heat exchanger, sealing elements consistent with this disclosure may find industrial application in virtually any structure requiring secure sealing across a large opening. This may include use in any storage or reaction structure where secure sealing is required.
This application claims the benefit of U.S. Provisional Application No. 61/032,799, filed Feb. 29, 2008.
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