AT508156B1 - Heat Exchanger - Google Patents

Abstract

Heat exchanger, preferably latent heat exchanger (1), comprising a with a storage medium (3) filled storage tank (2) within which of a heat transfer medium (6) flowed pipe strands (4a-4e) of a first piping system (4) and by a secondary medium (7) flowed through Pipe strands (5a-5e) at least a second piping system (5) are arranged. According to the invention, heat-conducting elements (8, 8 ') are attached to the outer sides of the pipe strands (4a-4e, 5a-5e), first heat-conducting elements (8) attached to the strands of tubing (4a-4e) of the first piping system (4). in the direction of each adjacent pipe strands (5a-5e) of the second pipe system (5) protrude and on the pipe strands (5a-5e) of the second pipe system (5) mounted second heat conducting elements (8 ') in the direction of each adjacent pipe strands (4a-4e) of the protrude first piping system (4). In this way, the heat transfer between the piping systems (4) and (5) can be significantly accelerated and thereby the efficiency of generic heat exchangers can be increased.

Description

Austrian Patent Office AT 508 156 B1 2010-11-15

Description: The invention relates to a heat exchanger, preferably a latent heat exchanger, comprising a storage container filled with a storage medium, within which pipe strands of a first piping system through which a heat transfer medium flows and pipe strands of at least one second piping system through which a secondary medium flows are arranged, according to the preamble of Claim 1.

Storage facilities for storing heat from solar panels, wood boiler systems or other energy sources are already well known.

The achievable by the present invention advantages relate to heat exchangers in general, but in particular latent heat exchangers, by means of which the invention is also described.

Latent heat exchangers are heat storage in which storage media are used, which store or release heat when their physical state changes. The melting or solidification heat occurring during solid-liquid conversion of the storage medium is called latent heat.

As storage media, this may e.g. Paraffins or salt hydrates are used. Using latent storage media, up to five times the heat storage capacity can be achieved than with water storage tanks.

Latent heat exchanger systems have a relatively low volume and high energy efficiency.

Generic latent heat exchangers are used for hot water and / or for heating support. In most cases, latent heat exchangers are powered by a heat transfer medium, usually water, which has been heated by means of solar plants. The hot heat transfer medium is guided in a first pipeline system through a storage container filled with the (latent) storage medium and melts the initially solid storage medium. As soon as a return temperature of the heat transfer medium measured at the exit from the storage tank essentially corresponds to its flow temperature measured when it enters the storage tank, the storage medium has completely melted. The storage medium is now charged with heat, which is ready for further disposition.

To remove the heat stored by means of the storage medium is provided by a secondary medium, usually also water, perfused second piping system. The second piping system also passes through the storage tank. The storage medium thus serves as a mediator of the heat from the first to the second piping system.

However, the heat transfer between the two piping systems often takes place too slowly and prevents a satisfactorily efficient supply of respective heat consumers. In particular, in latent storage media heat transfer is subject to a considerable inertia, so that in many cases can not be done satisfactorily fast supply of heat consumers with sufficiently heated secondary medium.

If you wanted to accelerate the heat transfer taking place in the storage tank, the individual pipe strands of the two piping systems would have to be brought closer together or be passed next to one another at the smallest possible distance. However, this would result in a very high density of tubing cross-sections in the reservoir and is considered uneconomical except for the reduced volume that would be available for the storage medium.

The present invention is therefore based on the object to optimize the heat transfer between the first and the second piping system, thereby providing a more efficient heat exchanger system. In particular, the heat transfer between the piping systems should be accelerated by using as little material as possible.

According to the invention, these objects are achieved by a device having the characterizing features of claim 1.

A heat exchanger preferably embodied as a latent heat exchanger comprises a storage container filled with a storage medium, within which any number of pipe strands of a first piping system through which a heat transfer medium and any number of pipe strands flowed through by a secondary medium are arranged at least one second piping system.

According to the invention it is provided that heat-conducting elements are attached to the outer sides of the pipe strands, projecting toward the pipe strands of the first piping first heat conduction towards each adjacent strands of the second piping and attached to the tubing of the second piping second heat conduction towards each adjacent Protruding pipe strings of the first piping system.

In this way, the heat transfer between the first and the second piping system can be significantly accelerated.

Since no additional pipe strands have to be used to optimize the heat transfer, but merely simple to manufacture, e.g. made of sheet metal heat conduction, a cost-effective, yet more power efficient heat exchanger system can be provided.

According to a particularly preferred embodiment of the invention, in each case a heat-conducting element of a pipe string of the first pipe system projects into an open volume enclosed by two adjacent heat-conducting elements of a pipe string of the second pipe system. Two heat-conducting elements of a pipe string of a pipe system thus include a volume into which projects at least one heat-conducting element of a pipe string of the other pipe system.

By such an arrangement of the heat-conducting a particularly good heat transfer between the first and the second piping system is ensured.

According to a preferred embodiment of the invention, the pipe strands of the piping systems have a ring-cylindrical cross-section, wherein the heat-conducting elements are arranged tangentially on the outer sides of the pipe strands.

Manufacturing, flow and thermal advantages result from preferred embodiments of the invention.

Thus, it is provided according to a preferred embodiment of the invention that a protruding from the pipe strands leg of a heat conducting element - considering the cross section of the pipe strands along the tube axis - longer, preferably more than twice as long as the diameter or the outer Width of the pipe strands at the attachment point or region of the heat-conducting element is.

According to a further preferred embodiment of the invention, it is provided that the heat-conducting elements of a tubing of the first piping system and the adjacent heat-conducting elements of a tubing of the second piping system-viewed in a direction orthogonal to the facing outer surfaces of the heat conducting viewing direction (in the case of curved Wärmeleitelementen: orthogonal to applied to the outer surfaces of the heat conducting tangential planes) - overlap each other by an amount which is larger, preferably more than twice larger than the diameter or the outer width of the pipe strands at the point of attachment of the heat conducting elements. In this way, optimum heat transfer between the first and the second piping system is ensured. In an alternative approach related to the already defined volume, in each case one heat-conducting element of a pipe string of the first pipe system protrudes into the volume enclosed by two adjacent heat-conducting elements of a pipe string of the second pipe system by a measure which is larger, preferably more than twice as large as the diameter or the outer width of the pipe strands at the respective attachment point or region of the heat-conducting.

According to a further preferred embodiment of the invention, it is provided that the heat-conducting elements of a tubing of the first piping system and the adjacent heat conducting elements of a tubing of the second piping system-viewed in a direction of the tube axis following direction - each other by more than a quarter, preferably by more as half of the cross-sectional longitudinal extent (ie the longest side length of the cross section) overlap one of the heat conducting elements.

In order to enable a simple and space-economical installation of the pipe strands, the cross-sectional longitudinal extension (the longest side length of the cross section) of the first heat conducting elements is preferably substantially the same size as the cross-sectional longitudinal extension of the second heat conducting elements.

According to a further preferred embodiment of the invention, it is provided that each heat-conducting element are arranged substantially centrally on the outer sides of the pipe strands, so that the heat-conducting - in consideration of the cross section of the pipe strands and with respect to the mounting point or area - each have two mutually symmetrical leg sections. The plane of symmetry between the leg sections is therefore formed by a plane running through the cross section of the pipe string and orthogonally through the cross section of the heat conducting element associated with this pipe strand.

According to a further preferred embodiment of the invention, it is provided that the heat-conducting elements of a tubing of the first piping system extend at least partially substantially parallel to the adjacent heat-conducting elements of a tubing of the second piping system.

According to a further preferred embodiment of the invention, in each case a heat conducting element of a tubing of the first piping to each of the two adjacent, the open volume forming heat conducting elements of a tubing of the second piping system is spaced by a measured orthogonal to the outer surfaces of the heat conducting elements. As the overlapping heat-conducting elements are distanced from one another, an optimal liquid circulation or a desired stratification of the storage medium surrounding the piping systems within the storage container is made possible.

According to a further embodiment of the invention, however, it is also possible that the mutually adjacent first and second heat-conducting elements contact each other at least in sections. By such contacting overlapping the heat transfer from the first to the second piping system can be further increased.

According to another particularly preferred embodiment of the invention, it is provided that the tubing of the first piping system extend in several primary planes and the tubing of the second piping system in multiple secondary planes, wherein the primary and secondary planes are arranged alternately side by side and preferably parallel to each other ,

Here, the primary planes and the secondary planes may be substantially vertical or substantially horizontal. The arrangement of the primary planes and the secondary planes, which is selected in each case according to specific requirements of the heat exchanger, may favor an ideal stratification of the storage medium held within the storage container.

The choice of a distance between the primary planes and the secondary planes determines the size of the overlap dimension of adjacent heat-conducting elements required for a desired heat transfer performance. According to a preferred embodiment of the heat exchanger according to the invention, each second pipeline level is used to remove heat from the storage tank or a feed respectively connected heat utilization devices.

According to a particularly preferred embodiment of the invention, the tube strands are wound meandering within the primary / secondary planes.

According to a particularly preferred embodiment of the invention, the meandering coiled tubing at regular intervals curved pipe sections, within which the pipe strands are bent by 18 0 °, and substantially linear, preferably parallel pipe sections, which connect the curved pipe sections together, wherein the heat-conducting elements are arranged on the substantially linear pipe sections.

According to a further particularly preferred embodiment of the invention, it is provided that the heat-conducting elements, more precisely their cross-sectional longitudinal extents, inclined relative to the horizontal, preferably inclined at an angle α between 20 ° and 70 °. This measure allows an advantageous arrangement of the piping systems and a thermally favorable meshing of adjacent heat-conducting elements of the first and second piping system.

According to a manufacturing technology advantageous embodiment of the invention, the heat conducting elements are plate-shaped. The plate-shaped heat-conducting elements are not necessarily made flat, but may also have an at least partially bent or angled geometry.

The invention will now be explained in more detail with reference to an embodiment. FIG. 1 shows a schematic representation of a heat exchanger according to the invention in FIG

Vertical section along section line B-B in FIG. 2 [0040] FIG. 2 is a sectional view of the heat exchanger according to the invention from FIG. 1

along section line A-A

FIG. 3 shows a perspective individual view of a component equipped with heat-conducting elements. FIG

Pipe Strands [0042] FIG. 4 shows a schematic detail of heat conducting elements adjacent

Pipe Ropes Fig. 5 is a schematic detail of heat conducting elements adjacent

Pipe Strands in an Alternative Arrangement Variant [0044] FIG. 6 shows a schematic detail of heat conduction elements adjacent

Pipe Strands in an Alternative Arrangement Variant FIG. 1 shows a preferred embodiment of a heat exchanger 1 according to the invention in a vertical sectional view.

In the present embodiment, the heat exchanger 1 according to the invention is designed as a latent heat exchanger to allow the highest possible heat storage capacity at a relatively small storage volume.

The heat exchanger 1 comprises a storage container 2 filled with a storage medium 3 and preferably made of stainless steel or glass fiber reinforced plastic. The storage medium 3 is a customary latent storage medium, e.g. Sodium acetate is used. The storage medium 3 is filled into the storage container 2 via a filling support 21 and, in the case of maintenance, can be drained off from the storage container 2 via a discharge connection 22.

Sections of a first pipeline system 4 and sections of a second pipeline system 5 are passed through the storage tank 2, in the form of any desired number of pipe runs 4 a and 2 a guided in planes. 4e, 5a-5e, which eg made of copper. As a pipe string is understood in the present context, each pipe assembly which is fed by a feed line described in more detail below.

The pipe strands 4a-4e, 5a-5e can each be constructed from one or more arbitrarily configured tubular elements. According to the present embodiment, the pipe strands 4a-4e, 5a-5e are meandering wound.

As can be seen in a side view of FIG. 2, the pipe strands 4a-4e, 5a-5e here at regular intervals curved pipe sections 13, within which the pipe strands 4a-4e, 5a-5e are bent by 180 ° and in Substantially linear pipe sections 14, which connect the curved pipe sections 13 of the piping systems 4, 5 together, so that the course of each pipe string 4a-4e, 5a-5e can be designated as meandering. The linear pipe sections 14 preferably run parallel to one another.

The meandering pipe strings 4a-4e of the first piping system 4 are in planes, referred to below as primary planes 11. The meandering coiled tubing strings 5a-5e of the second pipeline system 5 are also in planes, referred to below as secondary planes 12.

The primary and secondary planes 11, 12 are arranged alternately side by side and preferably run parallel to each other.

The storage container 2 has a bottom portion 2a, a lid portion 2b and a jacket portion 2c. The storage container 2 is executed in the present embodiment, essentially cuboid, but could also be designed cylindrically.

The end portions of the tubing strings 4a-4e, 5a-5e pass through the lid portion 2b of the storage container 2, the tubing 4a-4e of the first piping system 4 to the heat supply line 15 and the tubing 5a-5e of the second piping system 5 to the heat extraction line sixteenth are connected. The heat supply line 15, like the heat extraction line 16, comprises a feed line 15a or 16a and a return line 15b or 16b. Both heat supply line 15 and heat extraction line 16 are part of the piping system 4 and 5. The pipe strings 4a-4e, 5a-5e of the piping systems 4 and 5 can of course also be connected in another position to the heat supply line 15 and to the heat extraction line 16, eg by passing through the bottom portion 2a or through a side portion of the storage container 2. Also, the piping systems 4, 5 could include a plurality of flow lines 15a, 16a and / or return lines 15b, 16b.

The first piping system 4 together with the heat supply line 15 is a heat transfer medium 6, preferably water, flows through. The second piping system 5 together with the heat extraction line 16 is flowed through by a secondary medium 7, preferably also water.

The heat recovery device, e.g. a thermal solar system or a boiler heated heat transfer medium 6 flows via the flow line 15a of the heat supply line 15 from above into the connected to the first pipe system 4, lying in primary planes 11 pipe strands 4a-4e (arrow 17), is on the meandering pipe strands 4a-4e led to approximately the bottom portion 2a of the storage container 2 and then flows up again in the return line 15b of the heat supply line 15 (arrow 18), from where it is fed to a renewed heating by the heat recovery device, not shown. According to the present exemplary embodiment, the supply line 15a of the heat supply line 15 feeds five meander-shaped tube strands 4a, 4b, 4c, 4d, 4e, which lie in five primary planes 11 arranged vertically and parallel next to one another. During this passage of the (hot) heat transfer medium 6 through the storage container 2, the storage medium 3, which is still in solid state when the system is started up, is melted. The change in the state of aggregation of the storage medium sodium acetate from solid to liquid is about 59 ° C. The storage medium 6 is here charged with heat, which is absorbed by the pipe strands 5a-5e of the second piping system 5 or by the circulating in this secondary medium 7 ,

The secondary medium 7 also flows via the supply line 16a of the heat extraction line 16 from above into the pipe strands 5a-5e of the second pipe system 5 or into the secondary planes 12 formed by these (arrow direction 19), via the meandering pipe strands 5a-5e led to approximately the bottom portion 2a of the storage container 2 and then flows up again in the return line 16b of the heat extraction line 16 (arrow 20). The return line 16b of the heat extraction line 16 simultaneously forms a flow line for one or more heat consumers, not shown. Heat consumers can e.g. a floor or wall heating or a hot water line.

According to the present embodiment, the flow line 16a of the heat supply line 16 feeds five meandering pipe strings 5a, 5b, 5c, 5d, 5e and five vertical and parallel juxtaposed secondary planes 12th

According to the invention, heat-conducting elements 8, 8 'are attached to the outer sides of the pipe strands 4a-4e, 5a-5e, first heat-conducting elements 8 attached to the pipe strands 4a-4e of the first pipe system 4 in the direction of respectively adjacent pipe strands 5a 5e of the second pipe system 5 protrude and on the pipe strands 5a-5e of the second pipe system 5 attached second heat-conducting elements 8 'in the direction of each adjacent pipe strands 4a-4e of the first piping system 4 protrude.

The heat-conducting elements 8, 8 'are preferably made of copper or stainless steel. In the present embodiment, they are designed as rectangular sheet metal strips.

According to a particularly preferred embodiment, the heat-conducting elements 8, 8 'are plate-shaped. However, any other configurations of the heat-conducting elements 8, 8 'are possible, e.g. in the form of spirals, webs, lamellas, gratings etc.

The heat-conducting elements 8, 8 'can be made by any fastening technique, e.g. be attached by soldering, welding, gluing or by crimping on the pipe strands 4a-4e, 5a-5e. Between the heat-conducting elements 8, 8 'and the pipe strands 4a-4e, 5a-5e may take place a linear or a flat contact.

As can be seen with reference to FIG. 4, each heat-conducting element 8, 8 'of a tubing 4a-4e, 5a-5e projects into one of two adjacent plate-shaped heat-conducting elements 8, 8' of an adjacent tubing 4a, 4b. 4e, 5a-5e of the other piping system 4.5 enclosed, open volume V inside. The volume V is bounded according to FIG. 4 by the facing outer surfaces of the adjacent heat-conducting elements 8, 8 'and by imaginary planes connecting the lateral regions of the adjacent heat-conducting elements 8, 8'.

As shown in the figures for the present embodiment, the mutually adjacent and overlapping first and second heat-conducting elements 8, 8 'to each other about a perpendicular to the outer surfaces of the heat-conducting elements 8, 8' measured distance y distanced (Fig. 4).

In an alternative embodiment, however, it would also be possible that the mutually adjacent and overlapping first and second heat conducting elements 8, 8 'contact each other.

The plate-shaped heat-conducting elements 8, 8 'are flat according to the present embodiment, but may also have an arbitrarily modified shape and e.g. be concave and / or convex curved or angled. The heat-conducting elements 8, 8 'can each be constructed in one or more parts. Furthermore, the heat conduction elements can also be profiled, slotted or perforated. SUMMARY OF THE INVENTION

4, it is provided that the heat-conducting elements 8 of a tubing 4a-4e of the first piping system 4 and the adjacent second heat-conducting elements 8 'of a tubing 5a-5e of the second piping system 5 to each other by a Dimension x overlap, which is larger, preferably more than twice larger than the diameter or the outer width of the pipe strands 4a-4e, 5a-5e at the point of attachment of the heat-conducting elements. Considered in a direction orthogonal to the facing outer surfaces of the heat-conducting elements 8, 8 'extending viewing direction, protrude the heat-conducting elements 8, 8' of a tubing 4a-4e, 5a-5e of the piping systems 4, 5 by the dimension x in between two adjacent heat-conducting. 8 , 8 'of a tubing 4a-4e, 5a-5e of the respective other piping system 4, 5 formed volume V inside.

According to a further preferred embodiment of the invention, it is provided that the heat-conducting elements 8 of a tubing 4a-4e of the first piping system 4 and the adjacent heat-conducting elements 8 'of a tubing 5a-5e of the second piping system 5 by more than a quarter, preferably overlap by more than half of the cross-sectional longitudinal extension or of the respective longest side length of the cross section of one of the heat-conducting elements 8, 8 '(viewed in a viewing direction following the tube longitudinal axis). According to the present exemplary embodiment, the heat-conducting elements 8 of a pipe string 4a-4e of the first pipe system 4 and the heat-conducting elements 8 'of a pipe string 5a-5e of the second pipe system 5 overlap one another by approximately one third of their cross-sectional longitudinal extent. The cross-sectional longitudinal extension of the first heat-conducting elements 8 measured tangentially to the outside of the pipe string is substantially the same as the cross-sectional longitudinal extension of the second heat-conducting elements 8 '.

The heat-conducting elements 8, 8 'can also overlap the pipe strands of the respectively adjacent piping system 4, 5 (FIG. 5). In this arrangement variant, the heat transfer between the first piping system 4 and the second piping system 5 is particularly increased.

As can be seen in FIGS. 1, 4 and 5, a contact takes place between the heat-conducting elements 8, 8 'and the pipe strands 4a-4e, 5a-5e, when the cross-section of the pipe strands 4a-4e, 5a-5e or in a viewing direction following the pipe longitudinal axis, essentially in the region of a central component section of the heat-conducting elements 8, 8 '. Here, the pipe strands 4a-4e, 5a-5e each have two mutually symmetrical leg sections 9, 10.

Preferably, the heat-conducting elements 8 of a tubing 4a-4e of the first piping system 4 extend parallel to the adjacent heat-conducting elements 8 'of a tubing string 5a-5e of the second piping system 5.

The heat-conducting elements 8, 8 'are arranged according to FIG. 3 on the substantially linear pipe sections 14. Of course, the predominantly attached to the linear pipe sections 14 heat conducting elements 8, 8 'in this case also the curved pipe sections 13 completely or partially overlap.

The tubing strings 4a-4e, 5a-5e of the piping systems 4, 5 according to the present embodiment have a ring-cylindrical cross-section, wherein the heat-conducting elements 8, 8 'are arranged tangentially on the outer sides of the tubing strings 4a-4e, 5a-5e. In an alternative embodiment variant according to FIG. 6, the heat-conducting elements 8, 8 'can also be arranged radially on the pipe strands 4a-4e, 5a-5e.

As shown in Fig. 4, a protruding from the pipe strands 4a-4e, 5a-5e leg portion 9, 10 of the heat-conducting elements 8, 8 'is longer, preferably more than twice as long as the diameter or the outer width the pipe strands 4a-4e, 5a-5e at the attachment point of the heat-conducting elements 8, 8 '(again when looking at the cross section of the pipe strands 4a-4e, 5a-5e or in one of the pipe longitudinal axis following viewing direction).

The pipe strands 4a-4e, 5a-5e lying in the primary / secondary planes 11, 12 are 7/12

Claims (18)

Austrian Patent Office AT 508 156 B1 2010-11-15 each with a plurality of heat-conducting elements 8, 8 '(in the present embodiment: nine) equipped, the heat-conducting elements 8, 8' preferably each have a longitudinal extent, which at least two thirds of the clear width or the inner diameter of the storage container 2 corresponds. To ensure a satisfactory heat transfer, each pipe string 4a-4e, 5a-5e is equipped with at least five heat-conducting elements 8, 8 '. With regard to the arrangement of the primary and secondary planes 11, 12 and the course of the pipe strands 4a-4e, 5a-5e, multiple variations are conceivable. Thus, the primary planes 11 could be horizontal instead of vertical. In addition to the choice of the size of the heat-conducting elements 8, 8 ', the choice of a distance z shown in the bottom left in FIG. 1 between the primary planes 11 and the secondary planes 12 also determines the size of an overlapping measure x of adjacent heat-conducting elements 8, 8'. According to a particularly preferred embodiment of the invention, it is provided that the heat-conducting elements 8, 8 ', inclined relative to the horizontal, preferably inclined at an angle α between 20 ° and 70 °. In this case, an inclination of the heat-conducting elements 8, 8 'with respect to the horizontal by an angle α of substantially 45 ° has proved to be particularly advantageous. 1. Heat exchanger, preferably latent heat exchanger (1), comprising a with a storage medium (3) filled storage container (2), within which of a heat transfer medium (6) flowed through tubing (4a-4e) of a first piping system (4) and of a secondary medium (7) flowed through pipe strands (5a-5e) at least a second pipe system (5) are arranged, characterized in that on the outer sides of the pipe strands (4a-4e, 5a-5e) heat conducting elements (8, 8 ') are mounted, wherein The first heat conduction elements (8) attached to the pipe strands (4a-4e) of the first piping system (4) protrude in the direction of respectively adjacent strands of pipe (5a-5e) of the second piping system (5) and on the pipe strands (5a-5e) of the second piping system (5 ) mounted second heat-conducting elements (8 ') in the direction of respectively adjacent pipe strands (4a-4e) of the first piping system (4) protrude. 2. Heat exchanger according to claim 1, characterized in that in each case a heat conducting element (8) of a tubing (4a-4e) of the first piping system (4) in one of two adjacent heat conducting elements (8 ') of a tubing string (5a-5e) of the second piping system (5) protrude into the enclosed, open volume (V). 3. Heat exchanger according to claim 1 or 2, characterized in that the pipe strands (4a-4e, 5a-5e) of the piping systems (4, 5) have a ring-cylindrical cross-section and the heat conducting elements (8, 8 ') tangentially on the outer sides of the pipe strands (4a-4e, 5a-5e) are arranged. 4. Heat exchanger according to one of claims 1 to 3, characterized in that one of a tubing string (4a-4e, 5a-5e) protruding leg portion (9,10) of a heat conducting element (8, 8 ') - when considering the cross section of the tubing (4a-4e, 5a-5e) along the tube axis - longer, preferably more than twice as long as the diameter or the outer width of the tubing string (4a-4e, 5a-5e) at the attachment point of the Wärmeleitelementes (8, 8 ' ). 5. Heat exchanger according to one of claims 1 to 4, characterized in that the heat-conducting elements (8) of a tubing (4a-4e) of the first piping system (4) and the adjacent heat-conducting elements (8 ') of a tubing string (5a-5e) of the second Pipe system (5) - viewed in a orthogonal to the facing outer surfaces of the heat-conducting elements (8, 8 ') extending viewing direction - overlap each other to a dimension (x), which is larger , Preferably by more than twice greater than the diameter or the outer width of the pipe strands (4a-4e, 5a-5e) at the attachment point of the heat-conducting elements (8, 8 '). 6. Heat exchanger one of claims 2 to 4, characterized in that in each case a heat-conducting element (8) of a tubing string (4a-4e) of the first piping system (4) in the of two adjacent heat-conducting elements (8 ') of a tubing string (5a-5e) of the second pipe system (5) enclosed volume (V) by a dimension (x) protrude, which is larger, preferably more than twice larger than the diameter or the outer width of the pipe strands (4a-4e, 5a-5e) at the respective Attachment point of the heat-conducting elements (8, 8 '). 7. Heat exchanger according to one of claims 1 to 6, characterized in that the heat-conducting elements (8) of a tubing (4a-4e) of the first piping system (4) and the adjacent heat-conducting elements (8 ') of a tubing string (5a-5e) of the second Piping system (5) - viewed in a direction following the tube axis - overlap each other by more than a quarter, preferably by more than half of the respective longest side length of the cross section of one of the heat conducting elements (8, 8 '). 8. Heat exchanger according to one of claims 1 to 7, characterized in that each heat-conducting element (8, 8 ') is arranged substantially centrally on the outer sides of the pipe strands (4a-4e, 5a-5e), so that the heat-conducting elements (8, 8 ') - in view of the cross section of the pipe strands (4a-4e, 5a-5e) and with respect to the mounting point-each have two mutually symmetrical leg portions (9, 10). 9. Heat exchanger according to one of claims 1 to 8, characterized in that the heat-conducting elements (8) of a tubing string (4a-4e) of the first piping system (4) to the adjacent heat-conducting elements (8 ') of a tubing string (5a-5e) of the second Piping system (5) extend at least partially substantially parallel. 10. Heat exchanger according to one of claims 1 to 9, characterized in that in each case a heat conducting element (8) of a tubing string (4a-4e) of the first piping system (4) to each of the two adjacent, the open volume (V) forming heat conducting elements (8 ') of a pipe string (5a-5e) of the second piping system (5) is spaced by a distance orthogonal to the outer surfaces of the heat-conducting elements (8, 8') measured distance (y). 11. Heat exchanger according to one of claims 1 to 9, characterized in that the heat-conducting elements (8, 8 ') of mutually adjacent pipe strands (4a-4e, 5a-5e) contact each other at least in sections. 12. Heat exchanger according to one of claims 1 to 11, characterized in that the pipe strands (4a-4e) of the first piping system (4) extend in a plurality of primary planes (11) and the pipe strands (5a-5e) of the second piping system (5) a plurality of secondary planes (12) extend, wherein the primary and secondary planes (11, 12) are arranged alternately side by side and preferably parallel to each other. 13. Heat exchanger according to claim 12, characterized in that the pipe strands (4a-4e, 5a-5e) within the primary / secondary planes (11, 12) are meandering wound. 14. Heat exchanger according to one of claims 12 or 13, characterized in that the primary planes (11) and the secondary planes (12) extend substantially vertically. 15. Heat exchanger according to one of claims 12 or 13, characterized in that the primary planes (11) and the secondary planes (12) extend substantially horizontally. 16. Heat exchanger according to one of claims 12 to 15, characterized in that the meandering wound tubing strands (4a-4e, 5a-5e) at regular intervals curved pipe sections (13), within which the pipe strands (4a-4e, 5a-5e ) are bent by 180 ° and substantially linear, preferably parallel to each other pipe sections (14) which connect the curved pipe sections (13), wherein the heat-conducting elements (8 , 8 ') are arranged on the substantially linear tube sections (14). 17. Heat exchanger according to one of claims 1 to 16, characterized in that the heat-conducting elements (8, 8 '), inclined relative to the horizontal, preferably at an angle α between 20 ° and 70 ° inclined. 18. Heat exchanger according to claim one of claims 1 to 17, characterized in that the heat-conducting elements (8, 8 ') are plate-shaped. For this 2 sheets drawings 10/12