EP1445570A2 - Corrugated insert for a heat exchanger tube - Google Patents

Abstract

The insert has corrugation apexes and corrugation troughs, with set wave height (3) and wave length (4). there may be breaks in the flanks. The one-piece insert is formed of sectors (A1, A2, A3) of small and great wave lengths. Each sector consists of several corrugations of the same length, the troughs being of greater length (7) than the apexes.

Description

The invention relates to a corrugated insert for a heat exchanger tube, which in the Inserted heat exchanger tube and with the walls of the heat exchanger tube is preferably metallically connected, the corrugated insert itself alternating wave crests and wave troughs, a certain wave height, a Wavelength (division) and preferably breakthroughs in the wave flanks having. In addition, the invention relates to a manufacturing method for the corrugated insert.

The state of the art in the field addressed is characterized by seemingly limitless variety of variants.

If you restrict yourself to a corrugated insert in a heat exchanger tube Oil cooler, for example, the German utility model DE 296 22nd 191 or to the European patent EP 742 418 B1, from which the use described emerges. Such operations have breakthroughs in the Undulations. There it was pointed out that the stakes one for one low pressure loss of the oil have favorable flow direction, which is transverse to Wave direction lies and an unfavorable, which is exactly in the wave direction lies. Therefore the insert can be inserted into the heat exchanger tube that the direction of the waves has a certain inclination to the direction of flow, whereby an optimal ratio of cooling capacity to pressure loss can be achieved. to Implementation of this idea, however, it is necessary that the operations with the corresponding angle of inclination are punched out, which possibly a higher material waste arises.

Since something like that is not readily accepted, you help yourself to achieve it the optimal ratio of cooling capacity to pressure loss often with the fact that between the edges of the heat exchanger tube and the edges of the insert more or less large bypasses are left. However, these have an impact on the overall flow characteristics of the heat exchanger and they are therefore often not the best solution.

With other heat exchangers, the inserts are in the heat exchanger tube arranged that the flow direction is exactly transverse to the direction of the wave is located, where there are not necessarily breakthroughs in the wave flanks have to be. For example, it could be in flat tubes of charge air coolers or inserts arranged in capacitors.

The object of the invention is to provide a corrugated insert provide that can be produced with the least effort and with an optimized Ratio of cooling capacity to pressure loss in a heat exchanger is possible. It is also intended to provide an advantageous manufacturing process for use become.

The solution according to the invention is corrugated with respect to the formation Use by the characterizing part of claim 1 or by Characteristic of claim 3 reached. Two according to the invention Manufacturing methods for corrugated use are the subject of claims 6 and 7th

Such a division of the wave-shaped insert is preferably chosen that the wave valleys are about twice the length of the wave crests. A bigger one The wavelength of the insert leads to a lower pressure loss. The terms "Wave valleys" and "wave crests" are interchangeable because they are from the point of view of Depend on the viewer.

As a further independent task solution it is provided that the one-piece Use is formed from different wavelengths. For example, on At the beginning of the operation, a section with a shorter wavelength should be present which is followed by a central section with a longer wavelength, which in turn is in passes an end portion of lower wavelength. This order can vary also be changed as needed. Each section preferably consists of several waves of the same length.

In particular, in the case of an insert punched on a press, it is provided that the feed speed or the feed of the strip material accordingly is changed to sections with a larger or smaller wavelength (division) create. A smaller wavelength is replaced by a shorter one Feed speed or a smaller feed realized and a larger one Therefore, by a higher feed rate or a wavelength larger feed. Accordingly, none or at least only minor changes to the punch or other Effort required. Only the speed of the tape feed or alternatively, the continuous stroke speed of the press or the size of the feed must be preprogrammed accordingly to achieve the desired training of the To get a stake. Larger or smaller feeds can be through the Change the angular positions of the eccentric shaft of the press, between which the feed can take place.

The application is designed in such a way that it is optimal for the respective application or the desired ratio of cooling capacity to pressure loss. For further features, reference is made to the claims.

In other words, the methods according to the invention exist In it, the known technical possibilities of the forming machine are targeted for the production of inserts for heat exchanger tubes to exploit them to be formed with shorter and / or longer wavelengths such that they can meet certain heat exchange requirements.

As an additional advantage over the state of the art it is imperative to do so be pointed out that a not inconsiderable material saving by the Providing longer wavelengths occurs in use.

According to independent claim 7, it is provided that the continuous lifting operation the press is temporarily interrupted while the feed continues to operate remains. As a result, an insert can be produced, for example, one Section of any length in which there are no waves, or only a single elongated shaft, which is flat. Such one Section precedes at least one section with waves, and it closes too at least one section with waves to the non-corrugated section. Such Formations of corrugated inserts are desirable in some cases because of them For example, avoid using multiple individual bets can.

The invention is described below on the basis of exemplary embodiments which relate to use in a heat exchanger tube of an oil cooler.
Figures 1 and 2 show photographic images of a known insert and an insert according to the invention. FIG. 3 is a basic illustration of a known insert and FIGS. 4 and 5 are inserts, but according to the present invention. FIG. 6 shows a second exemplary embodiment in a view of the end of a flat tube and FIG. 7 shows an insert which was produced by a further method according to the invention.

The heat exchanger tube can be of any design.

Because of the heat exchanger tube of the exemplary embodiment, reference is made to EP 742 418 B1 and there in particular to FIG. 7. For example, the heat exchanger tube consists of two tube shells that are nested with one another, being soldered tightly at their edges, but their heat exchange surfaces are spaced apart and delimit the space in which the insert is located. The heat exchanger tube has at least one inlet opening 7 and one outlet opening 8 , which are designated in FIG. 5. For example, the oil flows through the heat exchanger tube and is in heat exchange with the upper and lower heat exchanger tubes through which the cooling liquid flows, as can be clearly seen from the mentioned FIG. 7 of the EP.

The insert according to the prior art, as shown in FIGS. 1, 2 and 3, has wave crests 1 and wave troughs 2 and a uniform wavelength 4 which extends over the entire insert. In the flanks 6, which the wave crests 1 with the Connect wave troughs 2 , known openings 5 are provided to allow the oil or the cooling liquid to pass through. The shaft running direction 9 of the insert roughly coincides with the inflow direction 10 , so that the oil or the cooling liquid has to flow through the openings 5 in order to get from one shaft to the next shaft, or from the inlet opening 7 to the outlet opening 8 .

In order to obtain a desired ratio of the cooling capacity to the pressure loss, it is provided according to FIG. 4 and according to the illustrations labeled "invention" in FIGS. 1 and 2 that the wave troughs 2 have a greater length than the wave crests 2 . In other words, the wavelength 4 , often referred to as division, has been enlarged in comparison with the prior art. The length of the wave troughs 2 is approximately twice the length of the wave crests 1 . It can be understood that the pressure loss can be reduced because the oil and / or the cooling liquid has to overcome fewer waves or breakthroughs 5 on the way from the inlet opening 7 to the outlet opening 8 than when used according to the prior art.

It is used on a press in a punching tool manufactured insert. The production takes place from an "endless" band material, preferably made of aluminum, which is very well known from the prior art and was therefore not shown in one figure. The metal band comes with a certain low but constant over the entire stake Feed speed down from the so-called coil and through that Stamping tool transported to an insert according to FIG. 3 or according to the state of technology.

The feed rate in the manufacture of the insert shown in FIG. 4 is also constantly higher than in the prior art according to FIG. 3. As a result, this insert has a wavelength 4 that is approximately twice as large as that of FIG. 3.

In the manufacture of the insert according to FIG. 5, the feed rate is changed at intervals. First, the initial section A1 is produced at a constant but reduced speed. Then the middle section A2 is produced with a constant but increased feed speed or with an increased feed, in order to immediately reduce the speed or the feed back to the value of the start section A1 in order to produce the end section A3 . The speed amounts or feed rates can be determined by tests. The general rule is that a higher speed or a larger feed leads to longer wavelengths and vice versa, reduced speed to smaller wavelengths.

The same result is achieved if the continuous stroke speed of the press is varied instead of the feed speed. For example, according to FIG. 5, section A1 can have a continuous lifting speed of 240 strokes / min. The following section A2 , which has longer wavelengths 4 , can be produced with 200 strokes / min and the end section A3 can again be realized with 240 strokes / min. However, it is clear that the variation of the feed speed or the feed of the aluminum strip is to be preferred because a frequent change in the continuous stroke speed is at the expense of the mechanics of the press.

As is known, a press stroke consists of a 360 ° full circle rotation of the eccentric shaft of the press, the forming operation taking place in the region of bottom dead center, that is to say in the region of 180 °. The belt feed takes place, for example, within an angular position of the eccentric shaft between 320 ° and 40 °, i.e. within an 80 ° angular path, for the passage of which (via the top dead center), depending on the set continuous stroke speed, a certain period of time is assigned, within which the feed can take place. Appropriate programming now ensures that the belt feed takes place, for example, within a 100 ° angular path, for example between 310 ° and 50 °, which allows a longer period of time at the same continuous stroke speed, within the same a longer path or longer, even at the same feed speed Feed is completed, which results in longer wavelengths 4 . The limits of the angular positions within which the feed can be carried out can differ from case to case. These depend, among other things, on the diameter of the eccentric shaft and on the depth of engagement of the upper tool in the lower tool. If this depth is small and the diameter is large, broader limits can be envisaged. However, a larger angular path (radians) than 180 °, i.e. between 270 ° and 90 °, seldom seems to be feasible. Maximized feeds can be achieved if the feed rate is increased in addition to the extension of the angular path.

6 is a welded, soldered or drawn flat tube 11 , as could occur, for example, in air-cooled charge air coolers. An insert is also located in such heat exchanger tubes 11 . It is pure coincidence that the waveform of the insert from FIG. 5 was provided there, because the design of the insert depends on the specific application. The insert from FIG. 6 can also have openings 5 , but it can also be designed without openings 5 because, for example, the charge air flows through the flat tube 11 perpendicular to the image plane. In other words, the flow direction 10 and the wave direction 9 lying in the image plane are perpendicular to one another in this exemplary embodiment.

An insert is shown in principle in FIG. 7 which has a central section A2 without shafts, but which in the present context is regarded as a section A2 with a single elongated shaft. Such a section A2 is produced in that the continuous stroke operation of the eccentric press is interrupted while the feed continues to run. Such inserts are preferably not intended for large-scale production because of the interruption in continuous lifting operation mentioned. The start section A1 and the end section A3 can consist of a plurality of waves of the same length 4 , although it can of course also be varied here in such a way that different wavelengths 4 are present within the start section A1 and / or the end section A3 . In the end section A3 , waves of different wavelengths 4 were therefore provided, by way of example only. The length of sections A1, A2, A3 can be chosen freely and depends on the specific application.

Claims (8)

Corrugated insert for a heat exchanger tube, which is inserted into the heat exchanger tube and is preferably metallically connected to the walls of the heat exchanger tube, the corrugated insert alternating wave crests (1) and wave troughs (2), a certain wave height (3), a wavelength (4) (Division) and preferably openings (5) in the wave flanks (6),
characterized in that the wave valleys (2) have a greater length (7) than the wave crests (1) - or vice versa. Use according to claim 2, characterized in that the wave troughs (2) preferably have twice the length as the wave crests (2) - or vice versa. Corrugated insert for a heat exchanger tube, which is inserted into the heat exchanger tube and is preferably metallically connected to the walls of the heat exchanger tube, the corrugated insert alternating wave crests (1) and wave troughs (2), a certain wave height (3), a wavelength (4) (Division) and preferably openings (5) in the wave flanks (6),
characterized; that
the one-piece insert is formed from sections (A1, A3) with shorter wavelengths (4) and from sections (A2) with longer wavelengths (4), one section (A1, A2, A3) either consisting of several waves of the same wavelength (4) or at least consists of a wave whose wavelength (4) is greater than the wavelength (4) in an adjacent section. Corrugated insert for a heat exchanger tube according to claim 3, characterized in that the insert preferably has an initial section (A1) with a smaller wavelength (4), a central section (A2) with a larger wavelength (4) and an end section (A3) with a smaller wavelength (4 ) having. Corrugated insert for a heat exchanger tube with an inlet opening and an outlet opening for the medium flowing through the heat exchanger tube, according to claim 4, characterized in that the wavelength (4) in the start section (A1) preferably has the same size as in the end section (A3), whereby this Sections (A1, A3) are those in which there is the inlet opening (7) of the medium into the heat exchanger tube or the outlet opening (8) for the medium from the heat exchanger tube. Process for the production of corrugated inserts for a heat exchanger tube according to one of the preceding claims 1-5, which are produced from a sheet metal strip which is transported at a certain feed speed and a certain feed by a forming tool on an eccentric press which works in continuous stroke mode,
characterized in that the feed speed is increased or decreased at a constant continuous stroke speed, with a section (A1, A3) of the insert with a smaller wavelength (4) at a reduced feed speed and a section (A2) of the insert with a larger wavelength (4 ) arises,
or that the constant stroke speed is increased or reduced at a constant feed speed, a section (A2) with a larger wavelength (4) being formed at a reduced constant stroke speed and a section (A1, A3) with a smaller wavelength (4) being formed at an increased constant stroke speed,
or that the angular positions of the eccentric shaft of the press, between which the feed is realized, are changed within permissible limits, as a result of which the feed is increased or decreased. Process for the production of corrugated inserts for a heat exchanger tube according to one of claims 1-5, which are produced from a sheet metal strip which is transported at a certain feed speed and a certain feed by a forming tool on an eccentric press which operates in continuous stroke mode,
characterized in that the continuous stroke operation is interrupted while the feed is running, so that a corrugated insert with a section without shafts or with a section with a single elongated shaft is produced. A method according to claim 6 or 7, characterized in that the desired variations of the continuous stroke, the feed and / or the feed speed are preprogrammed on a programming unit assigned to the press.

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