NL8001138A - FLAT TUBE HEAT EXCHANGER. - Google Patents

Description

- 1 -

Flat tube heat exchanger.

The invention relates to a heat exchanger which has at least one package of flat tubes, which consists of equally long flat tubes arranged for the flow of a first medium, which are mounted with overlapping width sides to form gaps for the flow-through of a second medium, the adjoining ends of which are connected to an end wall, which closes an opening of a receptacle outwards and through which the flat tubes 10 open into a common receptacle of the receptacle, in particular an oil cooler, the first medium passing through the flat tubes is oil and the second medium is air.

A heat exchanger of this kind is known from German Auslegeschrift 21 13 583. The use of flat tubes in heat exchangers not only has the advantage that this results in a relatively good efficiency of the heat exchanger, but also that heat exchangers of this kind have advantages. with regard to the manufacturing technique. For example, a package of flat tubes may be formed from the rectangular plates, which are alternately joined or framed at different opposing edges. soldered, which close the spaces between the plates outwardly and thus form flow-through spaces which alternate in directions rotated 90 ° relative to each other. As is known, such flat tube packages can be manufactured very simply in that solder-lined rectangular plates and corresponding strips are stacked one above the other into a package and then soldered together in an oven.

Flat tube packages, in which the flat tubes are formed of welded or of squeezed, seamless round tubes, for example, also have special advantages when corrosion-resistant heat exchangers are to be formed. In such a case, for example, flat pipes can be made of stainless steel.

In all known heat exchangers using packages of flat tubes of welded or seamless flat tubes, the flow spaces through the flat tubes for the first medium extend in a straight direction. In practice, however, circumstances may arise in which the first medium must be guided along a curved path. Since these flat tubes cannot be bent about an axis perpendicular to their flattening, only flat tubes could be used in such cases when they were made of arcuate plates with arcuate curved moldings. However, such arcuate plates lead to a great loss of material.

The problem underlying the invention is to provide a heat exchanger with packages of flat tubes, whereby a curved flow-through path for the first medium 15 is also possible with straight flat tubes.

This problem has been solved with a heat exchanger of the above-mentioned type according to the invention in that the receptacle for the connection to an end wall of a package of flat tubes in each case has two openings, the surfaces defined by these openings are at an angle to each other so that the receptacle forms a corner bin which connects two packages of flat tubes such that the flow-through directions of the flat tubes of the two packages of flat tubes run at said angle relative to each other. This achieves that a corner box can be used to interconnect two packs of flat tubes at an angle to each other and so that the flow of the first medium can be reversed notwithstanding the straight flat tubes.

The invention can be further developed particularly advantageously in that the angle between the two opening surfaces of the corner box i is 360 ° and n equal packages of flat pipes are interconnected by n corner trays of this type into an n-sided ring heat exchanger. The invention thus provides the surprising possibility of manufacturing a ring cooler from packages of flat tubes consisting of straight flat tubes. It is admittedly known from German Offenlegungsschrift 22 00 826 a ring cooler of flat tubes. However, it consists of annular cut plates, 40 which are formed by annular curved strips to form the 800 1 1 38 i * * 3 - flat tubes, for the first medium and by annular curved plate slats to form the radially oriented flow spaces for the second medium are connected together. When manufacturing the annular plates 5 and fins for this known ring heat exchanger, a lot of material is lost during the cutting of the annular plates. On the other hand, it is achieved by the invention that the flat tubes for a ring cooler can be manufactured from rectangular plates, which are connected to each other by straight strips. Cutting the plates and strips to size is practically possible without loss.

A further advantage of this embodiment according to the invention consists in the fact that for a ring cooler packages of flat tubes of welded or of flat pressed seamless round tubes can also be formed, which in particular can be very favorable in special cases of use. , if the round cooler must be made of a corrosion-resistant material, eg stainless steel.

For the supply and discharge of the first medium into the 20 rotating flat tubes of a circular heat exchanger according to the invention, two corner trays can be provided, each with a supply or. a first medium discharge stub, which are preferably arranged at diametrically opposed locations.

In a preferred embodiment, a collecting space is added to each of the two openings in at least one corner box, wherein the two storage spaces are separated from each other by an inner wall and are each provided with a connecting piece for the first medium. This achieves that it is possible to design a ring heat exchanger according to the invention in such a way that the first medium is led into one collection space of the corner box and then through all the flat tubes of the annular heat exchanger to the other collection room of the same corner box. backwards, where it is then discharged through the discharge stub. However, it is also possible to use two or more such divided corner trays, so that two or more flow-through spaces for two or more different first media are then obtained.

It is therefore possible to use one and the same annular heat exchanger and, for example, one and the same second medium, e.g.

Air cooling some different first media.

Another, advantage, of the. The invention consists in that only by different shapes of the corner boxes, namely by the choice of different fractions of 360 ° for the angle between the two opening surfaces. ring heat exchangers of different versatile circumferences and thus of different ring diameters can be manufactured from the same packages of flat tubes, which also shows the manufacture of differently sized cooling devices. simplifies.

The invention will be explained in more detail below with reference to the drawing, in which, by way of example, a number of embodiments of the heat exchanger according to the invention are shown.

In the drawing: Fig. 1 shows a perspective view of a first exemplary embodiment of a heat exchanger, which consists only of two packages of flat pipes of squeezed seamless pipes; Fig. 2 is a side view of a package of flat tubes of the heat exchanger according to Fig. 1; Fig. 2a is a perspective view of the corner box used in the exemplary embodiment of Fig.

1 and 2; Fig. 3 is a perspective view of a second embodiment of a heat exchanger, which consists of two packages of flat tubes; Fig. 4 shows a top view of the heat exchanger according to Fig. 3, partly in section and broken off; FIG. 5 is a perspective view showing the construction of the flat tube package of the exemplary embodiment of FIGS. 3 and 4 in exploded view; Fig. 6 is a view corresponding with Fig. 2 of a corner bin with two collecting spaces; 7 to 10 are top views of various annular heat exchangers mounted according to the invention.

The heat exchanger shown in Fig. 1 consists of two packages of flat tubes, indicated as a whole, by 11, which are interconnected by a corner box, which is indicated as a whole by 12 to 40. The corner box 12, which is only shown in fig. 2a in press 800 1 1 38 - 5 -

It is »shown pectively, has two openings 13. and 14., each of which defines a flat opening surface. These opening surfaces are at an angle 15 to each other (fig. 1 and 4) and are mutually connected by the inner space of the corner box.

In the exemplary embodiment shown in Figures 1 and 2, the package of flat tubes 11 consists of equally long, straight flat tubes 21, which are formed by flat pressing of seamless round tubes and, for example, may be made of stainless steel or subject to corrosion when used. another non-corroding metal. The ends of the flat tubes 21 of equal length are connected to the edges of openings 22 in a plate 23 each, e.g. welded, so that the plates 23, which are located at both ends of the package of flat tubes 11, end walls of the package form flat tubes. Each of the two openings 13 and 14. of the corner box 12 is closed with such an end wall of a package of flat tubes 11 formed by a plate 23, which can be achieved, for example, by the plate 23 being placed at the edges of the opening 13 or 14 is welded. The. the non-binding end wall can then be connected to a further corner bin or another collecting bin. The connection of the two packages of flat tubes through the corner tray 12 provides a curved flow-through path for the first medium, despite the straight flow-through spaces of the flat tubes.

The exemplary embodiment shown in Figures 1 and 2 may also be a part. forming an annular heat exchanger as described in detail below and shown in Figures 7 to 10. Figures 1 and 2 can therefore also be regarded as broken images of part of such a ring heat exchanger. The particular advantage of such an annular heat exchanger, which is built up from flat tube packages, consists in that it can be manufactured from packages of flat pressed seamless pipes of a corrosion-resistant metal, for instance of stainless steel or the like metal.

The exemplary embodiment of a heat exchanger shown in Figs. 3 to 5 corresponds to the heat exchanger according to Fig. 1 with the only difference that here each package of flat pipes 111 is formed of mutually congruent, rectangular plates 123, which are superposed one above the other and are spaced from one another by strips 124 and 125 and are connected to these strips, e.g. soldered. The frames 124 are here arranged along the longitudinal edges of the rectangular plates 123, so that two flat plates 123 adjoining each other and the longitudinal strips 124 each form a flat tube extending in the longitudinal direction of the rectangular plates 123, which fulfills the function of a flat tube 21 of 10, the exemplary embodiment according to fig. 1, and for the flow-through of a first medium, for example of oil in an oil cooler. The spacing, formed by the distance between two flat tubes constructed in this way, is laterally bounded by two strips 125, which extend along the opposite short edges of the plates 123 and there are connected to the adjacent plates 123. Flow-through spaces are defined by these strips 125 and the plates connected thereto, the flow direction of which is perpendicular to the flow-through direction of the flat pipes and which serve to flow through a second medium, eg air in an oil cooler. In order to improve the heat transfer between the second medium through the plates 123 delimiting these interspaces and the first medium flowing through the flat tubes, in these flow-through spaces extending along the frames 125 are plate lamellae 126 which can be soldered with the adjacent plates 123. Such a package of flat tubes can be manufactured very simply and practically without loss by cutting to size, because the plates 123 and the frames 124 and 125, as in Fig. 5 superimposed. When the plates 123 and the frames 124 and 125 are provided with solder, a package so assembled in known manner need only be guided in a soldering furnace or a soldering bath, so that these parts are soldered closely together in one operation.

In a package of flat tubes 111 brazed in this manner, the end walls are formed by the short sides of the plates 123, the ends of the moldings 124, and the external width sides of the moldings 125. These end-40 walls can be now simply be connected to the edges 800 1 1 38. J »- 7 - of. the openings 13. of corner trays 112, e.g. soldered together.

Figures 7 to 10 show various annular heat exchangers, which are built up from the 5 flat tube packages 11 or 111. In this ring heat exchanger s, in addition to a corner container 12, there is also a corner container 112 (Figure 6) or 212 (Figure 8). ) required. At the corner box 112, the inner space is divided by an inner wall 16 into two collecting spaces 17 and 18, to which the openings 13 and 13 respectively. 14 10 have been added. Each of these collection spaces 17 and 18 is connected to a connecting stub 19. The corner box 212, like the corner box 12, has a continuous inner space and is additionally provided with a connecting stub 19 '. Depending on the size of the angle 15, which is formed by the two opening surfaces of the corner trays 12, 112, 212, the number of sides of the versatile ring heat exchanger can be varied arbitrarily.

In the exemplary embodiments according to Figures 7 and 8, the angle indicated by 15 is 90 °. As a result, a four-sided annular heat exchanger is obtained. In the exemplary embodiment of Fig. 7, two corner trays 112 are provided here, each with two collecting spaces and each with two connecting stubs 19. These corner trays 112 are arranged at opposite corners of the ring-shaped coolers. The other two corner boxes 12 each enclose a single continuous collection space.

As shown in FIG. 7 by the arrows 127 and 128 as well as by the streamlines 129 and 128 denoted by stripes. 130, this embodiment provides two flow-through spaces 30 for the first medium flowing through the flat tubes. Such a ring heat exchanger can be used for a two-stream flow of a first medium or for two different first media.

The annular heat exchanger 35 shown in Fig. 8 differs from the ring heat exchanger, which is shown in Fig. 7, only in that here the two corner trays 212, which are provided with connecting stubs 19 ', only have a single flow-through space and therefore only a single flow connection stub 19 '. This results in a ring heat exchanger which can only be used for one single medium - 8 - which flows through the flat tube leg, this medium following the flow shown in arrows and dashed lines in FIG. two branches are divided, which are then combined into one stream again in the connecting stub 19 '.

In the exemplary embodiment shown in Fig. 9, an annular heat exchanger is tilted, in which "the opening faces of the corner trays 12 'and 112' form an angle of 360 ° = 120 °. With these corner trays 12 'and 10 3 112 A three-sided ring heat exchanger can now be mounted. In this exemplary embodiment, only one corner tray 112 'is divided into two collection spaces and is provided with two connecting stubs 19. The other two corner trays 12' only have one enhle collection space as flow-through space.

In this round heat exchanger, the first medium flows through the one connecting piece 19 into the heat exchanger, circulates in the one heat exchanger through the flat tubes and then flows out of the second connecting piece 19.

The ring heat exchanger, shown in Fig. 10, has two corner trays 12 * 'and three corner trays 112' ', the angle 15 between the opening surfaces being 360 ° = 72 °.

5

A five-sided heat exchanger can be constructed with these corner trays. The triangular trays 11211 25 used therein are each divided into two collecting spaces and each provided with two connecting stubs 19. As a result, this ring heat exchanger has three flow-through spaces 131, 132 and 133. It can therefore be used for three different first media. It should be noted that the different flow-through spaces for all the annular heat exchangers shown may be of different lengths depending on where the corner trays 112, 112 'or 112' 'are fitted.

This has the advantage that different heat exchange conditions can be provided for this when using different first media.

When the ring heat exchangers according to the invention in the preferred embodiment of the invention are constructed from the flat tube packages according to Figs. 3 and 5, the first and surprising advantage arises, that the ring heat exchanger can be built up here from 800 1 1 38 - 9- flat tube packages 111, which can be made practically without loss of material when cutting plates 123 and frames 124 and 125 to size.

A further advantage is that these flat tube packages 511, but also the flat tube packages 11 according to the exemplary embodiment of Figs. 1 and 2, can be used for differently sized ring heat exchangers depending on what kind of baking trays 12, 12 ', 121', 112, 212, 112'1 are used.

w C o 'n' c 1 'u s i es- 800 1 1 38

Claims (7)

1. A heat exchanger having at least one package of flat tubes consisting of flat tubes of equal length arranged for the flow-through of a first medium, which are mounted with overlapping width sides under the formation of 5 spaces for the flow-through of a second medium and of which adjoining ends are connected to an end wall, which closes an opening of a collection bin outwards and through which the flat tubes open into a common collection space of the collection bin, characterized in that the collection bin for each connection with an end wall of each package of flat tubes (11,111) has two openings (13,14), the surfaces defined by. these openings are at an angle (15) to each other, so that the collection bin forms a corner bin (12,12 ', 12' ', 112,112', 112 '', 212) connecting two packages of flat tubes, that the flow directions of the flat tubes of the two packages of flat tubes run at said angle relative to each other. 20 Heat exchanger according to claim 1, characterized in that the angle (15) between the two opening surfaces of the corner box (12.12 ', 12' ', 112.112', 112 '', 212) is 360 °. and that n equal packages of flat tubes 25 are interconnected by n corner trays of this type into an n-sided ring heat exchanger. Heat exchanger according to claim 1 or 2, characterized in that at least one corner box (212) is provided with a connecting piece (19) for the first medium. 4. Heat exchanger. according to a. one of the preceding claims, characterized in that a collecting space (17,18) is added to each of the two openings 35 (13,14) at least in a corner box (112,112 ', 11211) and the two collecting spaces through an inner wall ( 16) are separated from each other and each is provided with a connecting piece (19) for the first medium. '800 1 f 38 - 11 - 5. Heat exchanger. according to claim 4, characterized in that at least two in two. gathering areas (17,1.8) divided corner bins. (112) having at least two flow-through spaces in front. separate one or at least two different first media. Heat exchanger according to one of the preceding claims, characterized in that the flat tubes of at least one package of flat tubes (Owl) are formed by rectangular plates (123), which are alternately connected to strips (124, 125) at different, opposite edges. , preferably soldered. 7. Heat exchanger according to one. of the preceding claims, characterized in that the flat tubes (21) of at least one package of flat tubes (11) are formed by welded or by squeezed seamless round tubes, the ends of which are connected to the edges of openings (22) of a plate (23), which forms the end wall of the flat tube package. 800 f 1 38