The present application relates to a tube header of a heat exchanger and to a heat exchanger with such a tube header.
Heat exchangers are used to transfer heat from one fluid to another fluid. Heat exchangers have various uses within an automotive vehicle. For example, in a radiator, heat is transferred from a cooling liquid to the ambient air. In particular in motor vehicles the heat exchanger is used to discharge waste heat released by the internal combustion engine into the ambient air. The cooling medium that flows through the heat exchanger may be a liquid or, in some applications, a gaseous fluid.
Heat exchangers of the radiator type include a plurality of parallel tubes and two header boxes. The header boxes are typically multi-part structures having a header tank and a tube header. The tube header includes a central header plate with passages bordered by side walls forming a ferrule. The ends of the tubes are inserted into the ferrules to establish a fluid communication between the tube header and the interior volume of the tubes. The tubes may be formed from folded or welded sheet metal. While welded tubes are generally more durable, folded tubes are less costly to manufacture.
During operation, the service life of the heat exchanger may be shortened due to non-uniform expansion of the individual components of the heat exchanger when heating up and cooling down and the deformation or displacement resulting therefrom. The stresses can be attributed to the changing thermal conditions in the heat exchanger. The service life of a heat exchanger may thus be shorter for heat exchangers with folded tubes than for those with welded tubes.
In the past, attempts have been made to extend the service life of heat exchangers by modifying the transition between the tube header and the inserted folded tubes, with limited success.
It is therefore an object of the present application to provide a tube header for a heat exchanger in which the service life of the heat exchanger is extended without detriment despite the use of economically manufactured tubes.
According to an embodiment of the invention, a tube header for a heat exchanger comprises a header plate having two major dimensions defining a header plane, the header plate having a row of oblong passages extending through the header plate. Between adjacent passages, the header plate includes tie bars for a corrugation effect resulting in improved dimensional stability against warping. At least one of the tie bars has a generally W-shaped profile in a cross-section across the row of oblong passages. As will be explained below, this structure is mostly beneficial in heat exchangers having multiple zones.
Preferably, the tie bar with the W-shaped profile has a center area forming a plateau surface parallel to the header plane and connecting two generally V-shaped portions of the profile of the tie bar. The plateau can provide a sealing surface for a baffle in a multi-zone heat exchanger.
Each passage is preferably bordered by a ferrule monolithically formed with the header plate. Each of the generally V-shaped portions of the tie bar profile has an outer tie bar side wall connected to an adjacent ferrule and an inner tie bar side wall connected to the center area.
Preferably, the plateau surface defines a plateau plane intersecting the length of the ferrule that extends perpendicular to the header plane.
In an installed position, the center area is located further inside the header tube than an outermost portion of the tie bar.
For structural robustness, the center area preferably has a thickness corresponding to a maximum thickness of the tie bar.
Further, in an installed position, the plateau surface supports an internal header baffle extending perpendicular to the header plane. A gasket bridge may be sealingly disposed along the support tie bar and forms a seal between the support tie bar and the internal header baffle
Between the remaining adjacent passages, the header plate preferably includes trough-shaped tie bars. For this purpose, the tie bars may have side walls with a side wall thickness that is greater than the wall thickness of the ferrules.
The ferrule has a surrounding wall extending perpendicular to the header plane. A transitional area between the ferrule and the header plate has a reduced thickness that is smaller than the wall thickness of the ferrule. This transitional area provides a flexible hinge-like function for compensating dimensional changes during thermal cycles of a heat exchanger.
The center area may have a center area thickness that is greater than the wall thickness of the ferrule. This provides flexibility to the ferrule.
Conversely, reduced thickness of the transitional area may amount to at most 50% of the maximum thickness. This ensures structural robustness to the support tie bar.
For example, in relative terms, the center area may have a center area thickness that is greater than the wall thickness of the ferrule.
Likewise, the trough-shaped tie bar may have side walls with a side wall thickness that is greater than the wall thickness of the ferrules. Preferably, however, the trough-shaped tie bar has a bottom thickness that is smaller than the side wall thickness to provide an accordion-like flexibility to the trough-shaped tie bars.
According to a further aspect of the invention, the header plate may have at least one attachment portion for affixing the tube header to a header tank, wherein the attachment portion extending perpendicular to the header plane in the same direction as the ferrules.
According to a further aspect of the invention, an assembled heat exchanger has at least one header box and a plurality of tubes extending therefrom. The header box comprises a tube header having a header plate defining a header plane with a row of oblong passages extending through the header plate, and a plurality of tie bars, each tie bar arranged between a pair of adjacent oblong passages. At least one of the tie bars is a support tie bar with a generally W-shaped support tie bar profile in a cross-section across the row of oblong passages. The W-shaped tie bar provides a suitable sealing surface for a header baffle in a multi-zone heat exchanger.
The tubes may be folded sheet metal tubes. Each of the ferrules has a length perpendicular to the header plane and terminates in a remote edge at a free end. Preferably, the plateau defines a plateau plane that intersects the length of each ferrule.
The heat exchanger may include an internal header baffle supported by the support tie bar.
A header tank may form a header box in cooperation with the tube header. The header box accommodates the internal header baffle.
Further aspects and benefits of the present invention will become apparent from the following detailed description of the attached drawings. However, the detailed description and the specific examples shown in the drawings are provided for illustrative purposes only and are not intended to limit the scope of the present invention
In the drawings,
Arranged between the tube headers 2 are tubes 8 with elongated cross-sections. The tubes 8 are placed adjacent to one another and extend parallel to one another in a row. The tubes 8 have tube ends 10 that pass through passages 12 in the tube header 2 as will be explained in greater detail in connection with
When the heat exchanger 1 is designed as a radiator, the cooling medium enters an interior of one of the two header boxes 6 through an inlet opening 16 provided in the header box 6. The cooling medium to be cooled distributes itself in the interior, enters the tubes 8, and flows through them. In this process, cooling of the hot cooling medium takes place via the surfaces of the tubes 8 and of the cooling fins 14, and the cooled cooling medium in turn enters an interior of the other header box 6 at the other tube ends 10 of the tubes 8. The other header box 6 contains a first outlet opening 18 of a high-temperature zone and a second outlet opening 19 of a low-temperature zone, through which the cooling medium, which has in the meantime been cooled, is delivered to devices to be cooled. To separate the fluid inside the header box 6 that includes the outlets 18 and 19, an internal header baffle is arranged inside the header box 6 that divides the header box into two separate outlet zones. A schematic illustration of an internal baffle is provided in
For establishing a meandering flow through the pipes, the header boxes 6 may each include one or more further internal header baffles that divide the header boxes into zones. The baffle or baffles on one header box 6 are offset from the baffles of the other header box 6, thereby creating several groups of tubes with a reversal of the flow direction from one group of tubes to an adjacent group of tubes.
The tubes 8 and the cooling fins 14 located between them are exposed to a cooling air flow. In this process, the heat energy of the hot cooling medium flowing through the tubes 8 is transferred to the surfaces of the tubes 8 and from there to the cooling fins 14, and is then carried away by the cooling air flow.
The length L and the width W of the tube header 2, constituting the two greatest dimensions of the tube header 2, define a header plane A. In the perspective of
The tube header 2 has a generally rectangular outer periphery bordered by attachment portions in the form of flanges 20 extending along each of the four sides of the periphery for attaching the tube header 2 to the header box 6. From a central header plate 22 that extends in the header plane A, the flanges 20 extend transverse to the header plane A toward the header box 6 and are separated from each other by slots 24 in the four corners of the tube header 2 for added flexibility during assembly. Punched perforations 26 in the flanges 20 further add to the flexibility of the flanges 20.
The header plate 22 of the tube header 2 bears a row of ferrules 28 alternating with tie bars 30 or 44, respectively. The ferrules 28 surround elongated passages 12 extending along the direction of the width W of the tube header 2. The elongated passages 12 match the elongated cross-section of the tubes 8, with two opposing wide sides and two opposing narrow sides. Each of the ferrules 28 forms a wall 32 surrounding one of the passages 12. The wall 32 extends toward the interior of the header box 6.
The tie bars 30 and 44 provide a corrugation of the tube header 2 and thus provide increased stability for the overall structure of the tube header 2. To this end, the tie bars 30 are trough shaped and are arranged parallel to the passages 12. The bottoms 34 of the trough-shaped tie bars 30 point toward the outside of the header box 6. The tube header of
Below the tube header 2, a header gasket 54 is shown for illustration. The header gasket 54 has a gasket frame 56 that follows the general outline of the tube header 2. Gasket bridges are arranged across the gasket frame 56 that coincide with the locations of the support tie bars 44. The gasket bridges provide a seal between baffles and the tube header 2 as illustrated in more detail in
Referring to
Now referring to
The side walls 36 transition into a tapered portion 38 with a gradually reduced thickness toward the ferrule 28. Outside of the header box 6, the tapered portion 38 forms a steady slope over a taper length Lt that is greater than the height Hf of the ferrule 28, thus avoiding an abrupt change in the thickness of the header plate 22. The tapered portion 38 has a constant slope angle relative to the header plane A in a range of 45° through 80°, i.e. an angle of 10° to 45° relative to the tubes 8. Preferably, the slope angle is in a range of 60° through 66°, thus 24° through 30° relative to the direction of the tubes 8 shown in
It is evident, that the inner side walls 48 and the central area form an inverted profile compared to the trough-shaped tie bars 30. It may thus fittingly be called a reverse tie bar. The tie bar creates a sealing surface for a bridge of a radiator gasket to bear against whilst being compressed by the baffle of a multi-zone heat exchanger tank. This design may, for example, be manufactured by using a pierced and drawn stamping technique or a lanced stamping technique.
In the example shown, the inner side walls 48 have an average thickness that is smaller than the average thickness of the outer tie bars 46. Thus, in the support tie bars, the inner side walls function as live hinges for increased flexibility along the length of the header plate, while the center area provides increased rigidity along the width of the header plate.
One of the passages 12 of this arrangement is shown in a cross-sectional view in
For the core covers, the ferrule design of
All of the embodiments described above have in common that the tapered portion 38 is present around the entire periphery of the passages 12, along the wide sides of the passages 12 as well as along the narrow sides. The tapered portions 38 formed on the narrow side and the wide side serve as insertion aids in the fashion of funnels facing in the insertion direction of the tube. Thus, the tapered portions 38 assist the installation of the tubes 8 in the ferrules 28. The embodiments further have in common that the ferrule 28 has a greater wall thickness Df than the transitional area 40 Dta both along the wide sides of the passages 12 and along the narrow sides. As these embodiments show, the tube headers 2 as presented may be modified to meet various dimensional specifications. For applying the varying thicknesses of the tube header 2 and forming the passages 12 surrounded by the ferrules 28, for example, a pierced or lanced stamping technique may be utilized.
In one example, the maximum thickness of the tube header 2 may be 1.2 mm. The thickness of the bottom 34 of the tie bar 30 may be about 0.8 mm, the side walls 36 about 1.1 mm, the ferrules 28 about 0.6 mm, and the thickness of the transition between the tapered portion 38 of the header plate 22 and the lower edge of the tie bar 30 may be about 0.5 mm. The central area 52 of the support tie bar 44 may be close to the maximum header thickness. Generally, the central area 50 is preferably thicker than the inner side walls 48 of the support tie bar (see
The transitional area 40 between the ferrules 28 and the header plate 22, where the tube would meet the tube header 2, is dimensioned to promote flexibility in the ferrule 28 and removes rigidity of the interface between the tube and the tube header 2 so that more stress can be transferred from the tube to the ferrule 28 during thermal cycling. The tie bar between the ferrules 28 also incorporates flexibility due to the reduced thickness of the bottom 34 for optimal thermal cycle performance, while adding dimensional stability against warping for improved pressure cycle performance. Both thinned areas in the transition between ferrules 28 and header plate 22 as well as at the bottom 34 of the trough-shaped tie bars 30 provide flexible hinges.
Tube headers 2 for radiators are typically available in a range of maximum thicknesses of 1 mm through 2.5 mm. The minimum thickness of the tube header according to the present application is in the transitional area 40 between the ferrules 28 and the tapered portion 38. The inner side walls of the support tie bar may have a thickness near the minimum thickness, preferably slightly greater than the transitional area. The average durability of the heat exchanger needs to meet customer specifications, and the performance should be satisfactorily consistent among heat exchangers 1 of identical build.
It has been found that the performance of the tube headers 2 was optimized when the thinning of the transitional areas 40 amounted to a minimum thickness between 0.3 mm and 0.6 mm, corresponding to a thickness reduction by 50% through 75% for a maximum thickness of 1.2 mm, to a reduction by 60% through 80% for a maximum thickness of 1.5 mm, and to a reduction by 70% through 85% for a maximum thickness of 2 mm.
The resulting thickness for the inner side walls of the support tie bar thus ranges between 20% and 50% of the maximum thickness, while the thickness of the central area of the support tie bar may be in the range of 60% through 100% of the maximum thickness.
The indicated ranges are approximate. In particular, the lower limit depends on manufacturing tolerances. If the minimum thickness is too small, the manufacturing tolerances may result in a locally fragile transitional area, while thicknesses too great may not provide the desired hinge function.
The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 14793135 | Jul 2015 | US |
Child | 15134584 | US |