The present invention relates to fins or turbulizers, for example, for heat exchangers, and to methods for forming same.
It is known to manufacture low pressure drop (LPD) turbulizers by stamping metal strip stock to form it with transverse corrugations having openings and offset portions formed in side walls of the corrugations. In known stamping processes, a single transverse corrugation is created by each stamp cycle. Accordingly, this process is relatively slow and expensive. Further, as there are practical limits in terms of the amount by which the material can be deformed during stamping without fracture, turbulizers produced by this method typically have a relatively low ratio of corrugation amplitude to pitch and relatively low offset distance. However, known transverse-stamping processes of this type are nonetheless widely used, as same permit the manufacture of turbulizers of high utility, flowing from the geometry of the corrugations, openings and offsets obtainable. Of note, a turbulizer can be produced by this methodology which has substantially vertical corrugation sidewalls, i.e. sidewalls orientated normally to the plane of the turbulizer. Such a turbulizer, suitably brazed inside a flat tube, can render the tube relatively resistant to deformation, even under relatively high pressures. As well, balanced turbulizers can be produced by this method, i.e. turbulizers wherein the “blades” of the turbulizer (the planar portions of the turbulizers orientated parallel to the flow) are substantially equally spaced from one another.
It is also known to form LPD turbulizers by rolling or stamping strip stock to form a longitudinally-corrugated strip of sinusoidal profile, and, as indicated schematically in
Forming one aspect of the invention is a method of forming an offset strip for use as a fin or a turbulizer, the offset strip being of the type having longitudinally-extending corrugations each having side walls with openings and offset portions. The method comprises the step of: crimping a longitudinally-corrugated strip between a core die and a cavity die to form said offset strip, wherein each corrugation of said longitudinally-corrugated strip has a substantially flat surface and substantially parallel sidewalls extending substantially perpendicularly from opposite sides of the flat surface.
Forming another aspect of the invention is a method of forming apparatus for use as a turbulizer or fin for a heat exchanger, the apparatus including a member having a longitudinal axis, a lateral width and a plurality of strips including one or more first strips and one or more second strips, each strip extending widthwise of the apparatus and being corrugated longitudinally so as to form a plurality of sections laterally spaced-apart from one another and connected to one another by bridges projecting from the sections in a common direction, wherein the bridges of the first strips and the second strips extend in the same direction and the corrugations of the one or more second strips are offset laterally from the corrugations of the one or more first strips. The method comprises: crimping longitudinally-corrugated strip material between first and second forming dies to form said apparatus, said dies being adapted such that substantially all lateral movement of strip material in the crimping step occurs as a result of strip material being drawn laterally by material that has been displaced in a direction parallel to the direction of relative die movement.
Forming yet another aspect of the invention is a method of forming apparatus for use as a turbulizer or fin for a heat exchanger, the apparatus including a member having a longitudinal axis, a lateral width and a plurality of strips including one or more first strips and one or more second strips, each strip extending widthwise of the apparatus and being corrugated longitudinally so as to form a plurality of sections laterally spaced-apart from one another and connected to one another by bridges projecting from the sections in a common direction with respect to each strip, wherein each of the one or more first strips and each of the one or more second strips has a profile which differs from that of the longitudinally-corrugated strip, wherein the bridges of the first strips and the second strips extend in the same direction and the corrugations of the one or more second strips are offset laterally from the corrugations of the one or more first strips. The method comprises: crimping a longitudinally-corrugated strip between a core die and a cavity die to form said turbulizer, wherein each corrugation of said longitudinally-corrugated strip has a flat surface and parallel sidewalls extending substantially perpendicularly from opposite sides of the flat surface; and wherein each bridge of the first strip and second strip is formed by a flat surface of the core die which impinges upon and in coplanar relation with the flat surface of a respective corrugation as crimping commences.
Forming another aspect of the invention is a method of forming, from a longitudinally-corrugated strip, apparatus for use as a turbulizer or fin for a heat exchanger, the apparatus including a member having a longitudinal axis, a lateral width and a plurality of strips including one or more first strips, one or more second strips and one or more third strips, each strip extending widthwise of the apparatus and being corrugated longitudinally so as to form a plurality of sections laterally spaced-apart from one another and connected to one another by bridges projecting from the sections in a common direction with respect to each strip, wherein each of the one or more first strips and the one or more second strips has a profile which differs from that of the longitudinally-corrugated strip, wherein the bridges of the first strips and the second strips extend in the same direction and the corrugations of the one or more second strips are offset laterally from the corrugations of the one or more first strips. The method comprises: a forming step, wherein first and second forming dies move between an open position and a closed position to engage the corrugated strip between them to form said turbulizer, characterized in that substantially all lateral movement of longitudinally-corrugated strip material in the forming step occurs as a result of said strip material being drawn laterally by a laterally-connected portion of said strip material that has been displaced in a direction parallel to the direction of relative die movement.
Apparatus formed according to the methods form further aspects of the invention.
The methods permit the relatively inexpensive construction of the apparatus. The structures can have substantially vertical bridge sidewalls, can have offset corrugations having a relatively high ratio of corrugation amplitude to pitch, can produce a relatively low pressure drop in use and can have relatively large offsets.
Other advantages, features and characteristics of the present invention, as well as methods of operation and functions of the related elements of the structure, and the combination of parts and economies of manufacture, will become more apparent upon consideration of the following detailed description and the appended claims with reference to the accompanying drawings, the latter being briefly described hereinafter.
The present invention will now be more fully described, by way of example only, with reference to the accompanying drawings. In the accompanying drawings:
A turbulizer or fin apparatus 20 for a heat exchanger forms one aspect of the invention and is hereinafter described with reference to
The turbulizer structure 20 will be seen to comprise a member, designated with general reference numeral 21, having a longitudinal axis X-X, a lateral width Y and a plurality of strips 22,24,26. Member 21 takes the form of a 0.010″ inch aluminum sheet material. The plurality of strips 22,24,26 includes first strips 24, second strips 26 and third strips 22. The first strips 24 and the second strips 26 are arranged in groupings 28, wherein they are arranged in longitudinally-alternating relation to one another. The third strips 22 are separated from one another by the groupings 28.
With reference to
The exemplary turbulizer structure 20 could be used, for example, in a stacked-plate type radiator, in a low-pressure-drop orientation wherein the longitudinal axis of the turbulizer was orientated parallel with the fluid flow. Suitably brazed inside a flat tube, this turbulizer 20 would render the tube relatively resistant to deformation, even under relatively high internal pressures, and would provide turbulence to the flow, which can be of assistance in heat transfer.
Construction of such turbulizers can be via a method of the general type, as described, for example, in U.S. Patent Application Publication No. US 2005/0016240, wherein in a forming step first and second forming dies move between an open position and a closed position to engage the corrugated strip between them and form a portion of said turbulizer by cutting and displacing portions thereof.
However, whereas in US 2005/0016240 substantially all of the corrugations in the strip are laterally or transversely offset during the forming step, as indicated by the sequence of
An exemplary die set is shown in
The manner in which the offsets are provided in the present invention via the exemplary die set is shown in the sequence of
This methodology produces turbulizer/fin structures which can exhibit relatively low pressure drop in the LPD orientation in comparison to known LPD turbulizers. Without intending to be bound by theory, it is believed that this flows from the fact that much of the “burr” material resultant from shearing lies in the plane of the sidewalls of the corrugations, since the sidewalls of the corrugations are orientated parallel to the direction of relative die movement. Dies used in the method have also been observed to wear at a relatively low rate, which tends to reduce burring. Without intending to be bound by theory, such low wear rate is believed to flow at least in part from the fact that the dies used in this method do not deform all of the sheet material to produce the corrugations, but leave portions untouched. A yet further advantage associated with the methodology is an improved ability to produce turbulizers wherein the ratio of corrugation amplitude to pitch is relatively high, which flows from the relatively more robust structure associated with the die elements employed in the subject method. By way of explanation, in known methods, such as described in U.S. Patent Application Publication No. US2005/0016240, the dimensions of the die elements are constrained by the “width” of the offset corrugations. This is because all of the corrugations are fully occupied by the dies at the midpoint of each stamping cycle, since substantially all of the material is displaced, in one direction or another, during the stamping step. This is in contrast to the methodology of the present invention wherein portions of the strip material are not displaced, i.e. in the construction of the first strips and the second strips, only one side of each corrugation in the precursor longitudinally corrugated strip is displaced. Thus, the dimensions of the die elements employed are not constrained by the corrugation size, but rather, as a function of the spacing between corrugations in the precursor strip and the offsets, which permits the die elements to be relatively robust.
Persons of ordinary skill in the art will readily recognize that this exemplary die set 50,60 could be used in the method to produce the turbulizer shown in
The distance by which the corrugated material was longitudinally displaced between stamp cycles defines the longitudinal length of the third strip 22 separating the groupings 28 from one another. The then-stamped material could then be cut to length as necessary in a conventional manner, to form the structure of
Whereas but a single turbulizer or fin 20 has been thus far described, along with an exemplary die set for the production of same, it will be appreciated that with routine modification, turbulizers and fins of great variety can be produced.
For example, turbulizers and fins of greatly varied length can be produced.
As well, whereas in the turbulizer shown, six (6) corrugations are provided, greater or lesser numbers of corrugations could be provided (in which case the number of the teeth on each die portion would normally be varied accordingly).
Further, whereas in the turbulizers shown and described thus far, all of the corrugations have a similar “height”, the invention can be employed in the context of variable height turbulizers or fins 99, as indicated in
Of course, whereas aluminum sheet material 0.010″ in thickness has been previously specified, it will be understood that other materials of other thicknesses could be utilized. For turbulizers, 0.010-0.012″ thickness aluminum is regularly utilized and for fins, aluminum material of about 0.005″ in thickness is regularly used, but variations can be routinely accommodated and are contemplated.
Additionally, whereas in the turbulizer shown in
As well, it should be emphasized that, whereas the exemplary turbulizer is described with reference to first, second and third strips, it will be evident that turbulizers can be produced by the method with more than three different strip profiles, which may be present in any order, although as indicated, balanced turbulizers are normally most desirable.
In view of the foregoing, it should be understood that the present invention is limited only by the accompanying claims, purposively construed.
This application is a continuation of Ser. No. 12/469,783, filed May 21, 2009 which is a continuation of Ser. No. 12/126,695 filed May 23, 2008, both of which are incorporated by reference in their entirety and which are pending as of the filing date of this application.
Number | Date | Country | |
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Parent | 12469783 | May 2009 | US |
Child | 13399524 | US |
Number | Date | Country | |
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Parent | 12126695 | May 2008 | US |
Child | 12469783 | US |