Patent Grant
8387686
The present disclosure relates generally to automotive heat exchangers and, more particularly, to brazed heat exchangers.
Various types of heat exchangers are used in automotive applications. For example, WO 03093751, published on Nov. 13, 2003, assigned to Behr, relates to a radiator with an internal fin section, and a short section of tube inside a primary tube. In various evaporator applications, such as, for example, in WO 2004/005831, evaporators are provided with a fin that fits against the tube radius for the full length of the tube. U.S. Pat. No. 5,105,540 issued on Apr. 21, 1992 to Ford Motor Company shows a tube with an internal liner stock for increasing interior fluid turbulation. U.S. Pat. No. 4,501,321 issued on Feb. 26, 1985 to Blackstone Corporation shows a two piece tube with an overlap occurring at the minor dimension. U.S. Pat. No. 4,813,112, issued on Mar. 21, 1989 to Societe Anonyme des Usines Chausson shows a reinforcement plate on an ambient side of a header to locally reinforce a tube-to-header joint. U.S. Pat. No. 4,805,693 issued on Feb. 21, 1989 to Modine Manufacturing shows a two-piece tube with an overlap occurring at the diameter of the tube. The above references are herein incorporated by reference.
In recent years, the temperatures and pressures of so-called ‘turbo-charged’ air has significantly increased resulting in failure of heat exchangers, such as those of prior art charge air coolers (CACs), and after coolers due to thermal stresses. In such temperature/pressure conditions, a major disadvantage of prior art designs includes common failures, such as fatigue fracture, of both the tube and the internal fin.
In prior art designs, specific fractures, such as transverse fractures, may occur, for example, at tube locations, and, in particular, at the inlet header of the heat exchanger. Also, internal fin fracture may occur and lead to contamination in heat exchangers such as the charge air in coolers.
Higher temperatures and pressures for CACs are being specified by customers. Even with material changes, increased thickness of materials will be needed to meet these new requirements. Increasing material thickness further drives up costs. One solution is to increase the robustness of the tube by increasing the thickness of the tube and the internal fin. Another solution is to use high strength alloys. Although effective in improving durability, these changes require significant tooling, process change(s), material cost(s), and overall cost(s) to produce a durable charge air cooler.
There exists a need for a heat exchanger assembly with localized strength which is cost effective and improves durability with increasing pressure/temperature applications.
The present disclosure provides a heat exchanger assembly especially comprising a heat exchanger such as an after cooler or charge air cooler for automotive applications. A tube strengthener is provided to allow for a more thermally resistant or ‘robust’ after cooler or charged air cooler. Specifically, aspects of the present disclosure provide for an increase in resistance to thermal and pressure stresses in the heat exchanger or the heat exchanger assembly and, especially, in and near specific areas in which thermal fatigue failures may occur (e.g., an area of a tube and an internal fin at or next to a header in the heat exchanger assembly). The tube strengthener can be used at any location in the heat exchanger or heat exchanger assembly that needs additional strength.
The present disclosure in various embodiments provides an improved thermal/pressure resistant heat exchanger for a heat exchanger assembly (e.g., the heat exchanger having an increased thermal durability yielding an increased functional life of the heat exchanger assembly) in high pressure and/or high temperature environments found in after coolers and, especially, in charge air coolers.
a is a schematic top view of internal fin with a tube strengthener in one end of a tube, in accordance with an aspect of the present disclosure.
b is a cross sectional schematic side view of a tube strengthener in both ends of a tube, in accordance with an aspect of the present disclosure.
a-c is a cross sectional schematic end view of a tube strengthener-end contact in an oval shaped tube, in accordance with an aspect of the present disclosure.
a-c is a cross sectional schematic end view of a tube strengthener-end contact in a domed end shaped tube, in accordance with an aspect of the present disclosure.
a-d is a cross sectional schematic end view of a tube strengthener-end contact in a rectangular shaped tube, in accordance with an aspect of the present disclosure.
a-d are cross sectional schematic views of a tube strengthener-structural in an oval tube, in accordance with an aspect of the present disclosure.
a-c are cross sectional schematic views of a tube strengthener-structural in a rectangular tube, in accordance with an aspect of the present disclosure.
a-c are cross sectional schematic views of a tube strengthener-structural in a domed tube, in accordance with an aspect of the present disclosure.
a-b is a cross sectional schematic of end view of a tube strengthener-extruded in an oval tube, in accordance with an aspect of the present disclosure.
a-b is a cross sectional end view of a tube strengthener-extruded in a rectangular tube, in accordance with an aspect of the present disclosure.
a-b is a cross sectional schematic view of a internal fin with end views of a tube strengthener-extruded in a domed tube, in accordance with an aspect of the present disclosure.
A strengthened tube wall as in embodiments of the present disclosure for after cooler and CAC heat exchanger assemblies has greatly reduced or even insignificant and/or largely inconsequential effects on heat transfer and internal restriction, as opposed to prior art CAC heat exchanger assemblies without such tube strengtheners.
Preferred aspects of the present disclosure provide improved thermal durability without a major design change from presently used heat exchanger designs that affect the complete heat exchanger. These aspects affect a localized portion of the heat exchanger and may be applied to current designs using minor modifications to current manufacturing processes. Cost reduction opportunities exist by allowing for use of thinner and less expensive alloys on both the tubes and the internal fins, as well as providing for a more competitive method of achieving increasing design requirements with current technologies. In particular, the use of the tube strengthener allows design elements at a specific location or locations in the cross section of a tube with one variation providing differing thickness(es) in one or more of the structural elements.
As referred to herein, a “tube strengthener” is a complete modified inner or internal fin or a piece, part, or section of a modified inner or internal fin, that may be used to provide strength to an area of stress or stress in the tube, while retaining some heat transfer properties. The inner or internal fin is typically placed inside the heat exchanger tube prior to brazing the heat exchanger assembly. The inner or internal fin (hereafter “internal fin”) when brazed to an interior wall of the heat exchanger tube forms a structure resistant to the required operating temperatures/pressures of the heat exchanger, as well as additional heat transfer surfaces. The tube strengthener is designed to be applied to localized areas in the heat exchanger where temperature/pressure stress resistance is greater than that provided by the internal fin in order to meet durability requirements while retaining some heat transfer properties.
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The present disclosure, in its various aspects, is likely to reduce the likelihood of internal fin fracture during heat exchanger operation(s), and is likely to decrease the overall rate of potential fracture and propagation of such fractures through heat exchanger assemblies tubes and, particularly, after cooler and CAC heat exchanger assembly tube walls.
In one aspect of the present disclosure, at least one tube strengthener, which hereafter is known as the tube strengthener-end contact, is provided. As referred to herein, the “tube strengthener-end contact” is a modified or formed fin with a thickness equal to or greater than the internal fin which it substitutes, which preferably replaces or is located in the area where normally is located an outermost internal fin in the tube of the heat exchanger, which fin or part of fin is especially formed to contact the internal surface of the minor tube dimension being brazed to the minor tube dimension and retaining some heat transfer properties while improving temperature/pressure durability at a specific location in the heat exchanger. By design, the features of the tube strengthener-end contact allow for contact with an inner surface or surfaces of the heat exchanger tube at an identified or determined location or locations of highest stress, normally the minor dimension, the stress areas affected by providing additional thickness of material directly at and adjacent to the location of greatest stress.
In aspects of the present disclosure, by using the tube strengthener-end contact comprising a modified formed internal fin, durability of the heat exchanger is increased by brazing the tube strengthener-end contact to the interior surface of a tube, especially in place of an existing internal fin and on an inside surface of the tube minor dimension, which is typically the location of highest stress in the tube. These aspects of the present disclosure allow a resistance to thermal fatigue in high stress areas. By providing for a structure and, in particular, an increase in the tube wall thickness on the minor dimension existing material, thicknesses and alloys may be used in all but the highest stress area of a CAC. Reduced material gages are possible in such heat exchangers, while having an improvement in cost of the heat exchanger assembly. By determining the area of need for strength in the tube of the heat exchanger, different tube strengthener-end contact thicknesses and fin pitches may be specified. In embodiments of the present disclosure, use of a tube strengthener-end contact increases wall thickness in the tube's end radius where fractures often occur. In accordance with these aspects, the highest thermal/pressure stress concentration problems are typically at the radius of the tube adjacent to the tube-to-header braze joint, which are solved by using the tube strengthener.
As described hereinabove, various aspects of the present disclosure add strength to heat exchangers, such as CACs, at specific locations of highest stress, normally within the first sections of tube past an end of an inlet tube. In some of the preferred aspects, the strength is added by inserting a short section of the tube strengthener-end contact, such as the internal fin or fin section of greater than 25% of the thickness of the tube wall, and brazing a portion of the thickened internal fin across the location of highest stress to create a thickened tube strengthening structure that resists thermal fatigue in the high stress area, which typically is the minor dimension of the tube. These aspects or embodiments enable the formation of the heat exchanger requiring no more than the standard or existing material thicknesses and use of traditionally used alloys in all but the highest stress area of the heat exchanger, such as a CAC. Reduced material gages are possible in such heat exchangers, while having an improvement in cost characteristics of the heat exchanger assembly for lower temperature/pressure applications.
In one aspect of the present disclosure, at least one tube strengthener, which hereafter is known as the tube strengthener-structural, is provided. As referred to herein, the “tube strengthener-structural” is a modified or formed fin or fin section with a thickness equal to or greater than the internal fin which it substitutes, which preferably replaces or is located in the area where normally is located an outermost internal fin in the tubes of the heat exchanger, which fin is especially formed to contact the locations of highest stress in the tube and also having a structure formed into the tube strengthener-structural adjacent to the location of highest stress, being brazed to the minor tube dimension and retaining some heat transfer properties while improving temperature/pressure durability at a specific location in the heat exchanger. By design, the features of the tube strengthener-structural allow for contact with the inner surface or surfaces of the heat exchanger tube at an identified or determined location or locations of highest stress, normally at a portion of minor dimension. The stress areas are affected by providing additional thickness of material directly at the location of greatest stress with additional strengthening by having a structure adjacent to the location of highest stress to further resist thermal/pressure stresses.
In aspects of the present disclosure using the tube strengthener-structural comprising a modified formed internal fin, durability of the heat exchanger is increased by brazing the tube strengthener-structural to the interior surface of a tube, especially in place of an existing internal fin and at the location of highest stress which is normally on the inside surface of the tube minor dimension with a structural feature formed into the tube strengthener-structural adjacent to the location of highest stress in the tube. These aspects of the present disclosure allow a resistance to thermal fatigue in high stress areas. By providing for an adjacent structure and, in particular, an increase in the tube wall thickness at the location of highest stress, existing material thicknesses and alloys may be used in all but the highest stress area of a CAC. Reduced material gages are possible in such heat exchangers, while having an improvement in cost of the heat exchanger assembly. By determining the area of need for strength in a tube of the heat exchanger, different tube strengthener-structural thicknesses, formed structures, and fin pitches may be specified. In embodiments of the present disclosure, use of the tube strengthener-structural increases the wall thickness at the location of highest stress where fractures often occur and additionally forms a stiffening structure into the tube strengthener-structural adjacent to the location of highest stress for further resistance to thermal fatigue. In accordance with these aspects, the highest thermal/pressure stress concentration problems are typically at a radius of the tube adjacent to the tube-to-header braze joint, which are solved by use of the tube strengthener-structural.
As described hereinabove, various aspects of the tube strengthener-structural add strength to the heat exchangers, such as CACs, at specific locations of highest stress normally within the first sections of a tube past the end of the inlet tube. In some of the preferred aspects, the strength is added by inserting a short section of the tube strengthener-structural, such as an internal fin section of greater than 25% the thickness of the tube wall, brazing a portion of the thickened internal fin across the location of highest stress to create a thickened tube strengthening structure with an additional formed structure that resists the thermal fatigue in the high stress area, which typically will be at the minor dimension of a tube. These aspects or embodiments enable heat exchanger formation requiring no more than standard or existing material thicknesses and use of traditionally-used alloys in all but the highest stress area of the heat exchanger, such as a CAC. Reduced material gages are possible in such heat exchangers, while having an improvement in cost characteristics of the heat exchanger assembly for lower temperature/pressure applications.
In one aspect of the present invention, at least one tube strengthener, which hereafter is known as a tube strengthener-extruded, is provided. As referred to herein, the “tube strengthener-extruded” is an extruded internal fin, the tube strengthener having a central web or multi-structural support feature or element, which substitutes, replaces, or is located in an area where, in preferred embodiments, normally is located an outermost internal fin in the tubes of the heat exchanger and, in specific embodiments, of a CAC while retaining some heat transfer properties. The central web is designed to have projections in it at specific or selected locations. The preferred embodiments of the present invention have at least one, preferably, a plurality of extruded projections with a multi-structural support feature or element (central web) designed to fit into a tube of the heat exchanger in place of, in substitution of, or placed where would normally be located a traditional internal fin or section. By design, the features attached to the central web allow for contact with the inner surface or surfaces of a heat exchanger tube at an identified or determined location or locations of highest stress. The stress areas are affected in at least two different ways: by providing a direct structure to resist the thermal forces, and to provide additional thickness of material directly at and only at the location of greatest stress.
In aspects of the present disclosure, using the tube strengthener-extruded comprising extruded internal fin (extruded tube strengthener) durability is increased by inserting a structure (for example, a section or sections of extruded internal fin), typically a structure or structures which are projections, extensions, branches, or arms off a central web. In aspects of the present disclosure where heat exchangers are brazed, the structures are brazed to the inside of a tube at the locations of highest stress. These aspects allow a resistance to thermal fatigue in high stress areas. By providing for a structure and, in particular, a structure coming off of a central web arrangement, existing material thicknesses and alloys may be used in all but the highest stress area of the CAC. Use of such a structure and, in particular, a structure coming off of a central web in embodiments of the present disclosure are also used to reduce material gages in CACs with a corresponding improvement in cost control and performance enhancement. The section thickness of, for example, the projections can vary to add material into areas of highest stress and minimize material in lower stress areas. The use of varying material thickness in the embodiments of the present disclosure utilizing the tube strengthener-extruded also assists in minimizing a potential pressure drop affect due to tube blockage at its opening or other such blockage(s). Also in embodiments of the present disclosure, the structural projection, extension, branches, arms, or the like may be of various thicknesses. By determining the area of need for strength in the tube of the heat exchanger, different structural projections, extensions, branches, arms, or the like may be of different thicknesses at different locations off the central web. The use of the extruded tube strengthener, in embodiments of the present disclosure, with a central web adds strength to a specific location or locations of highest thermal/pressure stress in the CAC. Also, the amount of material used to provide the maximum strength is provided by providing increased thickness and structure, as needed, in the location or locations of highest thermal/pressure stress. These aspects or embodiments enable heat exchanger manufacture (formation) requiring no more than the standard or existing material thicknesses and use of traditionally-used alloys in all but the highest stress area of the heat exchanger, such as the CAC. Reduced material gages are possible in such heat exchangers, while having an improvement in cost characteristics of the heat exchanger assembly for lower temperature/pressure applications.
Aspects of the present disclosure solve various problems including the strength problem by adding strength, for example, to the CAC at a specific location or locations of highest stress, normally within the first 25 mm past the end of the inlet tube.
One aspect of the tube strengthener significantly reduces the potential of failures and, particularly, thermal/pressure fatigue failures. In preferred embodiments of the present disclosure, it has been found that thermal stress resistance upward of 200 percent to about 400 percent or more may result using some embodiments of the present disclosure with the tube strengthener leading to significant durability of both the tube and the heat exchanger assembly.
Alternative or preferred embodiments of the present disclosure provide a cost effective method for increasing the thermal/pressure resistance or thermal durability of CAC designs in high temperature applications (>220 C). Additional potential of reducing material costs in high temperature applications (>220 C) also exists.
Additional embodiments provide a concurrent reduction in tube thickness and, particularly, internal fin thickness without deleteriously affecting the thermal/pressure durability of the heat exchanger assembly, particularly in after cooler or CAC applications, in lower temperature environments (<220 C).
The embodiments of the present disclosure further preferably provide for greatly improved thermal/pressure durability without the cost associated with design, tooling, or major process changes seen in the prior art.
By distributing stress (reducing fatigue) associated with the bending moment, particularly amongst internal components of the CAC (e.g. the tube and the core versus the header and the tank) stress is taken away or substantially reduced in the high stress area or the area of stress concentration such as that found at the braze joint with the header.
In embodiments of the present disclosure, the tube strengthener is positioned at high stress areas or areas of stress concentration to eliminate the potential of outer internal fin fracture near or at the inlet header and subsequent or associated propagation of fracture through the tube wall.
In preferred methods of the present disclosure, minor modification(s) of manufacturing operation(s) with no additional labor or other significant modifications provides for the heat exchanger with the tube strengthener with the qualities of increased lifetime for the heat exchanger assemblies, particularly in CAC applications.
In preferred methods of the present disclosure, manual or automated means may be used for tube stuffing (i.e. insertion of the internal fin into the tube).
In a particularly preferred method of the present disclosure, an automated tube stuffer is provided to insert the internal fin into the tube, wherein the tube location within the core and within the tube strengthener replaces the first and/or final internal fin or fin portions inserted into the tube. Also in preferred embodiments of the present disclosure, the tube strengthener may be applied to ameliorate stresses in CAC designs. The internal fin is replaced by the tube strengthener at the areas of highest stresses.
The present disclosure also provides, in one aspect, a method for reducing contamination of charged air by, for example, internal fins which typically cleave chips on the inlet side of the CAC due to the high stresses at the inlet tube-to-header joint. By positioning the tube strengthener in an area of stress in the tube wall, brazing the tube strengthener as part of the heat exchanger brazing process subsequently reduces contamination from the internal fin in charge air coolers. In aspects of the present disclosure, there is a heat exchanger assembly comprising a first end tank, a second end tank opposite the first end tank, at least one tube in fluid communication with the first and second end tanks, the at one least tube adapted to have a fluid flow therethrough, at least one tube strengthener, and at least one internal fin, wherein the at least one tube strengthener and the at least one internal fin is positioned inside the at least one tube. In particular embodiments of the present disclosure, the heat exchanger assembly is brazed. In particular embodiments of the present disclosure, the at least one tube and at least one of the first end tank or the second end tank contact each other to form a header joint. Embodiments of the present disclosure have a tube strengthener that is a tube strengthener-end contact or tube strengthener-structural, or the tube strengthener is a tube strengthener-extruded.
In some preferred embodiments of the present disclosure, a modified fin is positioned inside the tube such that the modified fin is an outermost modified fin that contacts and follows the contour of an inside wall of the tube on either the radius or minor dimension of the tube.
The modified fin and tube in embodiments of the present disclosure have an overall thickness at the point of contact, which is approximately equal to or greater than to the thickness of the tube at areas outside of the area of contact between the fin and the tube. In embodiments of the present disclosure, the overall thickness at the point of the header joint is greater than or equal to the thickness of the tube at areas outside of the area of contact between the fin and the tube. Another aspect of the present disclosure comprises a heat exchanger assembly comprising a first end tank, a second end tank opposite the first end tank, at least one tube between the first and second end tanks, and at least one tube strengthener. wherein the at least one tube strengthener is positioned inside the at least one tube. In particular embodiments, the at least one tube is in fluid communication with the first or second end tank. In particular, the at least one tube is adapted to have a fluid flow therethrough. The heat exchanger assembly, in aspects of the present disclosure, for example, may comprise a heat exchanger that is a turbo charger after cooler, charge air cooler, or EGR.
In embodiments of the present disclosure, the tube strengthener abuts the tube at a localized contact area, and the tube strengthener plus the tube at the localized contact area form a strengthened joint comprising the tube, the tube strengthener, and the header where the tube touches or abuts the header (header joint). The header joint may be brazed to form a brazed header joint.
Fluid, in connection with various aspects of the present disclosure, can be, for example, gasses such as air or other gasses, liquids such as cooling automotive fluids, or other fluids, or mixtures of the above.
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c, in an aspect of the disclosure, shows the formed structure (826) with additional thickness (829) areas at the tube minor dimension end radius. The contour of the tube strengthener-structural covering the inside tube minor dimension radius with at least two or less additional thicknesses (829) and at least one adjacent formed structure (826) for further localized strengthening of the tube assembly at the area of greatest stress, thereby forming a strengthened joint when the heat exchanger is brazed. The formed structure consisting of a portion of the tube strengthener-structural that is straight and approximately perpendicular to the tube major dimension surface.
d, in an aspect of the disclosure, shows formed structures (836, 837) with additional thickness (839) areas at the tube minor dimension end radius. One side of the inside tube minor dimension radius is a folded tube end (838) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (834) at a minimum abuts part of, partially, or completely the minor tube dimension wall of the folded tube (838) and is supported by the formed structure (837) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg. The contour of the tube strengthener-structural covers the inside tube minor dimension radius with at least two or less additional thickness (839) and at least one adjacent formed structure (836,837) for further localized strengthening of the tube assembly at the area of greatest stress, thereby forming a strengthened joint when the heat exchanger is brazed.
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b, in an aspect of the disclosure, shows formed structures (916, 917) with additional thickness (919) areas at the tube minor dimension end. The contour of the tube strengthener-structural covering the inside tube minor dimension with at least two or less additional thickness (919) and at least one adjacent formed structures (916, 917) for further localized strengthening of the tube assembly at the area of greatest stress, thereby forming a strengthened joint when the heat exchanger is brazed.
c, in an aspect of the disclosure, shows formed structures (926, 927) with additional thickness (929) areas at the tube end minor dimension. One side of the inside tube end minor dimension is a folded tube end (928) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (924) at a minimum, abuts part of, partially, or completely the minor tube dimension wall of the folded tube (928) and is supported by the folded structure (927) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg. The contour of the tube strengthener-structural covering the inside tube end minor dimension with at least two or less additional thicknesses (929) and at least one adjacent formed structure (926,927) for further localized strengthening of the tube assembly at the area of greatest stress, thereby forming a strengthened joint when the heat exchanger is brazed.
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a, in an aspect of the disclosure, shows formed structures (1006, 1007) with additional thickness (1009) areas at the tube minor dimension end radius. The contour of the tube strengthener-structural covering the inside tube minor dimension radius with at least two additional thicknesses (1009) and at least one adjacent formed structure (1006, 1007) for further localized strengthening of the tube assembly at the area of greatest stress. This is a largely strengthened joint when the heat exchanger is brazed.
b, in an aspect of the disclosure, shows the formed structure (1016) with additional thickness (1019) areas at the tube minor dimension end radius. The contour of the tube strengthener-structural covering the inside tube minor dimension radius with at least two or less additional thicknesses (1019) and at least one adjacent formed structure (1016) for further localized strengthening of the tube assembly at the area of greatest stress. This is a largely strengthened joint when the heat exchanger is brazed. The formed structure consists of a portion of the tube strengthener-structural that is straight and approximately perpendicular from the tube major dimension surface.
c, in an aspect of the disclosure, shows formed structures (1026, 1027) with additional thickness (1029) areas at the tube minor dimension end radius. One side of the inside tube minor dimension radius is a folded tube end (1028) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (1024) at a minimum, abuts part of, partially, or completely the minor tube dimension wall of the folded tube (1028) and is supported by the folded structure (1027) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg, thereby forming a strengthened joint when the heat exchanger is brazed. The other tube end minor dimension radius uses the contour of the tube strengthener-structural covering the inside tube minor dimension radius with at least two or less additional thicknesses (1029) and at least one adjacent formed structure (1026) for further localized strengthening of the tube assembly at the area of greatest stress. This is a largely strengthened joint when the heat exchanger is brazed.
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a, in an aspect of the disclosure, shows an extruded structure (1207, 1208) approximately centered about the central web (1206) providing strength in the locations of highest stress, normally the tube end minor dimension radius. Additionally, the fins (1205) with the localized contact surface (1204) projections contact the tube inside surface on the major dimension. The contour of the tube strengthener-extruded covers none, part of, or all of the inside tube minor dimension radius with the extruded structure with localized contact surfaces, where a flux groove (1209) is optional, thereby forming a strengthened joint when the heat exchanger is brazed.
b, in an aspect of the disclosure, shows an extruded structure (1217, 1218) approximately centered about the central web (1216) providing strength in the locations of highest stress, normally the tube end minor dimension radius. Additionally, the fins (1215) with the localized contact surface (1214) projections contact the tube inside surface on the major dimension. One side of the inside tube minor dimension radius is a folded tube end (1220) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (1214) abuts part of, partially, or completely the minor tube dimension wall of the folded tube (1220) and is supported by the extruded structure (1218) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg. The contour of the tube strengthener-extruded covering none, part of, or all of the inside tube minor dimension radius with the extruded structure with localized contact surfaces, the flux groove (1219) is optional, thereby forming a single strengthened assembly by brazing.
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a, in an aspect of the disclosure, shows the extruded structure (1307, 1308) approximately centered about the central web (1306) providing strength in the locations of highest stress, normally the tube end minor dimension. Additionally, the fins (1305) with the localized contact surface (1304) projections contact the tube inside surface on the major dimension. The contour of the tube strengthener-extruded covering none, part of, or all of the inside tube minor dimension with an extruded structure with localized contact surfaces, the flux groove (1309) is optional, thereby forming a strengthened joint when the heat exchanger is brazed.
b, in an aspect of the disclosure, shows the extruded structure (1317, 1318) approximately centered about the central web (1316) providing strength in the locations of highest stress, normally the tube end minor dimension. Additionally, the fins (1315) with the localized contact surface (1314) projections contact the tube inside surface on the major dimension. One side of the inside tube minor dimension is a folded tube end (1320) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (1314) abuts part of, partially, or completely the minor tube dimension wall of the folded tube (1320) and is supported by the extruded structure (1318) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg. The contour of the tube strengthener-extruded covering none, part of, or all of the inside tube minor dimension radius with an extruded structure with localized contact surfaces, a flux groove (1319) is optional, thereby forming a single strengthened assembly by brazing.
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a, in an aspect of the disclosure, shows the extruded structure (1407, 1408) approximately centered about the central web (1406) providing strength in the locations of highest stress, normally the tube end minor dimension radius. Additionally, the fins (1405) with the localized contact surface (1404) projections contact the tube inside surface on the major dimension. The contour of the tube strengthener-extruded covers none, part of, or all of the inside tube minor dimension radius with an extruded structure with the localized contact surfaces, a flux groove (1409) is optional, thereby forming a strengthened joint when the heat exchanger is brazed.
b, in an aspect of the disclosure, shows the extruded structure (1417, 1418) approximately centered about the central web (1416) providing strength in the locations of highest stress, normally the tube end minor dimension radius. Additionally, the fins (1415) with the localized contact surface (1414) projections contact the tube inside surface on the major dimension. One side of the inside tube minor dimension radius is a folded tube end (1420) and provides a strengthened joint that is supported by the tube strengthener-structural. The localized contact area (1414) at a minimum abuts part of, partially, or completely the minor tube dimension wall of the folded tube (1420) and is supported by the extruded structure (1418) adjacent to covering all, a portion, or none of the inside folded tube minor dimension leg. The contour of the tube strengthener-extruded covering none, part of, or all of the inside tube minor dimension radius with an extruded structure with localized contact surfaces, a flux groove (1419) is optional, thereby forming a single strengthened assembly by brazing.
Aspects of the present disclosure are variable as they relate to size, length, thickness, and number of fins that are used to form the tube strengtheners, and their exact geometric shape may vary dependent on the actual heat exchanger assembly and application and tube design of the assembly. In high stress environmental applications, the overall thickness of the tube wall and tube strengthener may vary, for example, specific charge air cooler applications and tube design may vary.
In heat exchangers with stressful temperature/pressure operating conditions, aspects of the present disclosure having a tube strengthener are beneficial, for example, in CAC designs. Such aspects can be applied with minimal additional labor and only minor modification of manufacturing operations. In various aspects of a method of the present disclosure, an automated tube stuffer (an automated means or machine of insertion of a turbulator or fin into a tube) can be applied. In such applications, the strengthener can be the first or the last internal fin inserted in the tube and provides for ease of production. In aspects of the disclosure having a tube strengthener using an extruded internal fin or internal fin, the use of extrusion dies gives flexibility to the engineer or designer in designing the extruded external fin or internal fin so that appropriate strength under stressful environmental operating conditions is obtained with a minimum of material and structure, focalized at the location or locations of minimal stress, as well as allowing the designer the flexibility to add structure and material at the locations of highest stress as appropriate.
The relative size, length, thickness, and number of fins and exact geometric shape of a heat exchanger assembly, in accordance with the present disclosure, may vary depending on the heat exchanger application used (e.g. radiator, condenser, after cooler, charge air cooler, air to oil cooler, exhaust gas recirculation cooler (ERG)), and tube design.
In aspects of the present disclosure, a method of making a heat exchanger comprising a tube, internal fin or fins, a tube strengthener or strengtheners comprises forming an internal fin or fins with a tube strengthener or strengtheners; stuffing the internal fin or fins with a fin strengthener strengtheners into the tube; localizing the tube strengthener or strengtheners with the tube at areas of the tube in order to provide increased strength or durability to the heat exchanger; brazing the tube and a header at the header joint to form a brazed joint of increased thermal durability is contemplated. In some methods of the present disclosure, the step of localizing the tube strengthener or strengtheners at the region of the header joint, and brazing the tube and header at the header joint to form a brazed joint of increased thermal durability are also contemplated.
Unless stated otherwise, dimensions and geometries of the various structures depicted herein are not intended to be restrictive of the disclosure, and other dimensions or geometries are possible. Plural structural components can be provided by a single integrated structure. Alternatively, a single integrated structure might be divided into separate plural components. In addition, while a feature of the present disclosure may have been described in the context of only one of the illustrated embodiments, such feature may be combined with one or more other features of other embodiments, for any given application. It will also be appreciated from the above that the fabrication of the unique structures herein and the operation thereof also constitute methods in accordance with the present disclosure.
The preferred embodiment of the present disclosure has been disclosed. A person of ordinary skill in the art would realize however, that certain modifications would come within the teachings of this disclosure. Therefore, the following claims should be studied to determine the true scope and content of the disclosure.
This application is a divisional application of U.S. application Ser. No. 11/190,484 filed Jul. 27, 2005 now U.S. Pat. No. 7,487,589, which itself claims the benefit of U.S. Provisional Application Ser. No. 60/591,680, filed Jul. 28, 2004. These applications are herein incorporated by reference in their entirety.
| Number | Name | Date | Kind |
|---|---|---|---|
| 2488615 | Arnold | Nov 1949 | A |
| 2757628 | Johnston | Aug 1956 | A |
| 2899177 | Harris et al. | Aug 1959 | A |
| 4501321 | Real et al. | Feb 1985 | A |
| 4805693 | Flessate | Feb 1989 | A |
| 4813112 | Pilliez | Mar 1989 | A |
| 5105540 | Rhodes | Apr 1992 | A |
| 5185925 | Ryan et al. | Feb 1993 | A |
| 5372188 | Dudley et al. | Dec 1994 | A |
| 5511613 | Mohn et al. | Apr 1996 | A |
| 5555729 | Momose et al. | Sep 1996 | A |
| 5560424 | Ogawa | Oct 1996 | A |
| 6032728 | Ross et al. | Mar 2000 | A |
| 6192977 | Dey et al. | Feb 2001 | B1 |
| 6213158 | Rhodes et al. | Apr 2001 | B1 |
| 6571473 | Nozaki et al. | Jun 2003 | B1 |
| 6640886 | Lamich | Nov 2003 | B2 |
| 20050161194 | Emrich et al. | Jul 2005 | A1 |
| 20050247444 | Ohata et al. | Nov 2005 | A1 |
| Number | Date | Country |
|---|---|---|
| 1243884 | Sep 2002 | EP |
| 2777645 | Oct 1999 | FR |
| 1533466 | Nov 1978 | GB |
| 2394037 | Apr 2004 | GB |
| 61110892 | May 1986 | JP |
| WO 03093751 | Nov 2003 | WO |
| WO 2004005831 | Jan 2004 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20090166020 A1 | Jul 2009 | US |
| Number | Date | Country | |
|---|---|---|---|
| 60591680 | Jul 2004 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 11190484 | Jul 2005 | US |
| Child | 12347436 | US |
