DE2928014C2 - - Google Patents

Description

The invention relates to a heat exchanger of the generic type Concept of claim 1, method of manufacture and one with such heat exchanger equipped thermoelectric device.

By the U.S. Patent 35 27 621 is a heat exchanger of the generic type known, in which the heat exchange surfaces that extend between the two base plates, according to a first embodiment as flat guide surfaces are formed. Such guiding surfaces allow one simple construction and simple assembly of the heat exchanger; the disadvantage, however, is that between the guide surfaces in generally a laminar flow of the medium flowing through results, so that the heat transfer coefficient is relatively low. A Another disadvantage of the known arrangement is seen in  that the Ab condensation is very bad, even on these surfaces.

According to a further embodiment, that mentioned in the U.S. Patent specification is briefly mentioned, the guide surfaces also have a rod-like training that does it flowing medium would allow in different Direction to flow. Even if it is assumed that this way a turbulent flow instead of a laminar one of the medium flowing through and thus a higher heat number of transitions reached and also the drainage of condensed water is facilitated, however, is the attachment of many Single bars on the respective base plates difficult and so expensive.

The same applies analogously to the state of the art according to German Offenlegungsschrift 26 50 563 to; this publication shows a heat exchanger in which the between the bottom plate-shaped heat exchange surfaces by bundles of rods being represented. There could also be a turbulent flow there of the flowing medium and thus an increased heat transfer number as well as a good drainage of the condensed water in all Positions of the heat exchanger are assumed; it remains however, the difficulty of attaching the many bars on the base plates is complex and expensive. With the help of The invention aims to achieve the disadvantages of both known heat exchangers avoided, but the advantages of be kept.

The invention is based on the object, a heat exchanger of the type mentioned in the preamble of claim 1 create which with simple construction and little assembly allows a good heat transfer and where  Condensed water that forms in all rooms layers can run off easily.

This task is accomplished by the in the labeling section of the patent claims 1 included features solved.

In the claimed solution, therefore, neither form continuous Sheet metal many more bars the heat exchange surfaces, son Each heat exchange surface consists of several centers bands that are between across them but in the same Extend flat sidebands. In this way it is possible to take advantage of the dissolution of heat exchange surfaces in single rods, i.e. the turbulent flow the flowing media with the correspondingly high heat transition figures and the comparatively good drainage possible condensate with the ability to connect the Heat exchange surfaces light and therefore inexpensive, even sometimes even with the help of automatic assembly machines, with the reason to connect plates.

There are further advantages of the claimed heat exchanger in that the heat exchange surfaces from a thick Material can be made so that you have central bands with a large cross-section and thus heat exchanger with receives advantageous mechanical properties. These properties allow, on the one hand, stacks of heat exchangers exposed to considerable pressure without the danger there is a buckling of the central ligaments, and on the other hand the heat exchange surfaces with pressurized water jets clean without deforming the central ligaments will.

Developments of the invention, method for manufacturing and a thermoelectric device are in the Claims 2 to 10 marked.

The arrangement of the heat exchanger 5 in the thermoelectric device according to claim 3 supports very much the good flow of the condensed water.

The heat exchanger characterized in claims 4 to 7 represent different possible variations of the the greatest possible help in different flow media Turbulence can be generated.

In the heat exchangers according to FIGS. 4 and 5, the removal of the condensed water is improved by a suction effect which results from a local increase in the flow velocity of the flow medium.

In the manufacture of the heat exchanger according to claims 8 and 9 can use rolled metal sheets which has the advantage that this Materials have better thermal conductivity properties than for example casting materials, such as materials for Heat exchange surfaces are also known (e.g. through DE-OS 26 50 593).  

In the method according to claim 9, it is advantageous that the production of Heat exchange surfaces without removing material and thus practically without waste.

Execution will now be made with reference to the accompanying drawings examples of the invention described in detail. Show it:

Figure 1 is a partially diagrammatic section through a heat exchanger according to one Ausführungsbeisspiel the invention.

Fig. 2 is a perspective view of a heat exchange surface of the heat exchanger shown in Fig. 1;

Fig. 3 is a partial section along III-III in Fig. 1;

Fig. 4- Fig. 6 of the representation in Fig. 3 corresponding partial sections on an enlarged scale, the three different, preferred embodiments of the invention are and

Fig. 7 is a schematic perspective view showing the electrical circuit of a thermoelectric device provided with the heat exchangers.

In Fig. 1, a heat exchanger for a thermoelectric device according to an embodiment of the invention was shown in section. This thermoelectric device comprises thermocouples 1 , which are each arranged between two heat exchange surfaces, ie a warm wall 2 and a cold wall 3 .

This heat exchanger comprises two base plates 4 , which each form or carry a warm wall 2 and a cold wall 3 of the device. The two base plates 4 are arranged parallel to one another and connected to one another by a multiplicity of heat exchange surfaces 5 .

Each heat exchange surface 5 comprises, as shown in FIGS . 1 to 3, two continuous or discontinuous side bands 6 , which are intended for attachment to the two base plates 4 , and a central region 7 , which is formed by flat central bands 8 arranged in one plane which connect the two side bands 6 to one another. It can be seen that the problem of connecting the central bands 8 to the base plates is no longer a problem of fastening the individual bands to the base plates, since the central bands are fastened via the two side bands 6 . With the attachment of these two side straps 6 to the respective base plate, the attachment of as many central straps 8 as are contained in a heat exchange surface 5 is achieved in two attachment steps. The two side straps 6 can be fastened by folding, and / or riveting and / or brazing and / or welding.

It is also possible to form the two sidebands 6 in a straight line, thereby facilitating their attachment to the base plates. For this purpose, one can form in each base plate 4 grooves 9 , which are intended for receiving the side bands 6 .

Due to the fact that the fixing of the central belts 8 takes the two side bands 6, one can give the central belts 8 different shapes. The cross section of the central bands can be rectangular or square. The shapes can be chosen so that the heat exchange is favored and / or the flow of condensed water is facilitated.

. As shown in Figure 4, each central belt - as viewed in cross-section - a planar portion and a curved portion 8 a 8 b, which extends out of the plane defined by the two side bands 6. Relative to the flow direction of the fluid, which is indicated by the arrow F, is the plane AB cut 8a upstream of the curved section 8 b.

Thanks to this arrangement, the heat exchange is favored by the fact that the convection heat exchange coefficient is increased by the turbulence caused by the curved sections 8 b of the central bands 8 .

If the heat exchanger is arranged so that its two base plates 4 are vertical and the heat exchange surfaces 5 are horizontal, the curved sections 8 b are preferably arranged below the flat sections 8 a. This makes it easier to remove condensed water. The curved sections 8 b of the central belts 8 cause a local increase in the flow rate of the fluid flowing through the heat exchanger and thus a negative pressure which pulls the water drops down.

According to the two examples shown in FIGS . 4, 5 and 6, each central band 8 - viewed in cross section - has a central section 8 c, which is bordered by two curved sections 8 b. These extend on the same side out of the plane defined by the two side bands 6 . With regard to the flow direction of the fluid, which is indicated by the arrow F, the heat exchange surfaces 5 thus formed behave the same in a flow direction in the direction of the arrow F and in a flow direction opposite the direction of the arrow F.

As in the previously described embodiment, the heat exchange is favored by the fact that the convection heat exchange coefficient is increased by the turbulence caused by the curved sections 8 d of the central bands 8 .

If the heat exchanger with vertical base plates 4 and horizontally lying heat exchange surfaces 5 is arranged, the curved sections 8 d are preferably below the central section 8 c. The removal of condensed water is thus facilitated by the shell, which is formed by two mutually adjacent central bands 8 belonging to curved sections 8 d.

In the embodiment shown in Fig. 5, adjacent heat exchange surfaces are arranged so that their central bands 8 are aligned with each other. In the embodiment shown in Fig. 6, however, adjacent heat exchange surfaces are net angeord such that their central bands 8 are each offset. The arrangement according to this embodiment facilitates the removal of condensed water to an even greater extent, since the water that has accumulated in the shell formed by two adjacent central bands is drawn off by the negative pressure prevailing under half of the shell. This negative pressure is caused by the increase in the flow velocity in the constriction, which is formed by the central section 8 c of the central band lying under the shell.

In the manufacture of embodiments of the heat exchange surfaces 5 shown in Figs. 4 to 6 the procedure is preferably such that the central belts are formed by punching and bending the material located between two punch cuts, and nothing has ten abgeschnit of the material. In this way, one can obtain the heat exchanger at a relatively low production cost, both due to the high production speed of the Wärmeäustausch surfaces 5 as is also influenced by the economic recovery of the recycled for preparation of the heat exchange surfaces 5 material, since a material having a good electrical conductivity and has good thermal conductivity, is relatively expensive.

In the thermoelectric device shown in FIG. 1, several thermocouples 1 and heat exchangers connecting them can be arranged in the form of a stack. If several such stacks are arranged next to one another according to FIG. 7, the electrical circuit can take a particularly simple form in such a thermoelectric device, since the successive heat exchangers of each stack of heat exchangers are connected in series with one another, with side connections 12 establishing the connection between two stacks .

Claims (10)

1. Heat exchanger for thermoelectric devices, each having a thermocouple arranged between a warm wall and a cold wall, comprising two base plates, which each form or carry a warm wall and a cold wall, and a plurality of heat exchange surfaces which extend between the base plates, in which each heat exchange surface is formed by a flat befestig th to higher-level group of the two base plates components, characterized in that the components of each heat exchange surface consist of arranged flat central belts (8), which has two aligned transverse to the central belts (8) pages ribbons ( 6 ) interconnect, which in turn are intended for attachment to the two base plates ( 4 ). 2. Heat exchanger according to claim 1, characterized in that the two side bands ( 6 ) on the two base plates ( 4 ) by a clamping and / or a Quetschver connection and / or brazing and / or welding are attached. 3. Heat exchanger according to claim 1 or 2, characterized in that it is arranged in the thermoelectric device such that the two base plates ( 4 ) are directed vertically and the heat exchange surfaces ( 5 ) are directed horizontally. 4. Heat exchanger according to claim 3, characterized in that each central band ( 8 ) - viewed in cross section - comprises a flat section ( 8 a) and a curved section ( 8 b), which is formed by the two side bands ( 6 ) defined level extends. 5. Heat exchanger according to claim 3, characterized in that each central band ( 8 ) - viewed in cross section - has a central section ( 8 c) and two hemmed, curved edge sections ( 8 d), which on the same side from the extend both side bands ( 6 ) defined level out. 6. Heat exchanger according to one of claims 1 to 5, characterized in that adjacent heat exchange surfaces ( 5 ) are arranged relative to one another in such a way that their central bands ( 8 ) are each aligned. 7. Heat exchanger according to one of claims 1 to 5, characterized in that adjacent heat exchange surfaces ( 5 ) are arranged relative to one another such that their central bands ( 8 ) are each offset from one another. 8. A method for producing a heat exchanger according to one of claims 1 to 7, characterized in that each heat exchange surface ( 5 ) is made from a flat plate in which a central region ( 7 ) while leaving the two side bands ( 6 ) a punching process is subjected to, in which the central bands ( 8 ) remain. 9. A method of manufacturing a heat exchanger according to claim 5, characterized in that each heat exchange surface ( 5 ) is made from a flat plate in which a central region ( 7 ) is left with the two side bands ( 6 ) subjected to processing which is carried out therein there is that the central bands ( 8 ) are formed by punching and bending the material lying between two central bands ( 8 ), this material not being removed or only to a small extent. 10. Thermoelectric device, characterized, that they have a variety of heat exchangers according to one of the Claims 1 to 7 comprises.