ES2672642T3 - Pipe element for a heat exchanger medium - Google Patents

Abstract

Pipe element (10, 10 ') for a heat exchanger means (100, 100'), the pipe element (10, 10 ') being at least partially a rigid elongated heat exchanger tube having at least a first end (20) and at least a second end (30) and having a first side wall (40) and a second side wall (50), the first side wall (40) and the second side wall (50) being substantially arranged parallel to each other and being a distance (d) between the first side wall (40) and the second side wall (50) considerably smaller than the width (W) of the first side wall (40) and the second wall side (50), resulting in a substantially flat general pipe structure with connecting walls (45, 55) on both sides, the pipe element (10, 10 ') having a plurality of fins (60, 60') on at least one of the outer surfaces (42, 52) of the first side wall (40) and / or of the second pa lateral network (50), in which the pipe element is at least partially inclined or at least partially inclined and sloping and at least partially wound and / or twisted helically to form at least a part of a helical structure, characterized in that fins (60, 60 ') are arranged along a curve that extends along the entire width (W) of at least one of the outer surfaces (42, 52) of the first side wall (40) and / or of the second side wall (50) and are curved, so that between the fins (60, 60 '), which are arranged along a curve, there is a gap and / or a space and the fins (60 , 60 ') are arranged in a plurality of rows, in which the fins (60, 60') extend along a curve that extends between the connecting walls (45, 55), in which a first distance (a) in the entrance section of the space defined by two adjacent fins (60, 60 ') is greater than one sec a distance (b), in which the fins (60, 60 ') have a definition angle γ delimited by the fins (60, 60') and a connecting wall (45, 55).

Description

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DESCRIPTION

Pipe element for a heat exchanger medium

The present invention relates to a pipe element for a heat exchanger means, a heat exchanger means and the method of manufacturing a pipe element.

In the technical field of heat exchangers such as evaporators, condensers, radiators and refrigerators, many attempts have been made to provide compact and energy efficient heat exchangers. It is generally known that a heat exchanger provides an exchange of thermal energy between a first medium such as, for example, water and / or a cooling agent, and a second medium such as, for example, air.

For example, EP 1 840 494 A2 discloses a heat exchanger, in which the heat exchanger comprises a profile having two flat tubes with several channels and whereby the tubes are connected by means of a bar. The profile is a one piece profile and can consist of aluminum or an aluminum alloy.

In addition, DE 20 2008 006 379 U1 discloses an aluminum or aluminum alloy profile, which can be used for tubes for heat exchangers. The profile has a central channel and several additional channels arranged around the central channel.

Document DE 2 209 325 describes a tube for heat exchangers having a helical structure. In addition, DE 2 209 329 describes heat exchanger tubes having ribs on the inner side and on the outer side of the tube.

Additionally, GB 1 390 782 describes a heat exchanger pipe having spaced metal fins projecting into the tube from the pipe wall sections and extending in the longitudinal direction of the pipe.

In addition, EP 0 640 803 A1 refers to a heat transfer coil, in which a second piece of pipe is wound around the first piece of pipe while the first piece is straight and in which the first piece The pipe is then formed to define the general shape of the coil and then the first and second pieces of the pipe internally sized by internal pressurization to also force the two pieces of the pipe to enter into intimate contact with each other.

In addition, document DE 38 15 647 A1 refers to a circular heat exchanger with a flat tube comprising ribs within the spaces of the different layers.

Also US 3 662 582 describes a heat exchange pipe with an oblong cross-sectional peripheral wall and inner fins in the wall. Both this last document and DE 38 15 647 disclose the preamble of claim 1. However, it is still desirable to improve the technical solutions already known in the field of heat exchangers.

Therefore, an object of the present invention is to improve a pipe element for a heat exchanger means, a heat exchanger, the use of a pipe element to at least partially manufacture a heat exchanger means, the use of a heat exchanger for exchanging heat and a method of manufacturing a pipe element, in particular because the efficiency of heat exchange is increased and the overall structure of the pipe element and heat exchanger is improved and simplified and allows a more structure Compact heat exchanger.

The above object is solved in accordance with the present invention by a pipe element for a heat exchanger with the features of claim 1. Accordingly, a pipe element for a heat exchanger is provided, the pipe element being the less partially a rigid and elongated heat exchanger pipe having at least a first end and at least a second end and having a first side wall and a second side wall, the first side wall and the second side wall being substantially parallel a to the other and the distance between the first side wall and the second side wall is considerably smaller than the width of the first side wall and the second side wall, resulting in a substantially flat pipe structure in general with connecting walls on both sides, the pipe element having a plurality of fins in at least one of the supe outer surfaces of the first side wall and / or the second side wall, in which the fins have an angle of definition Y enclosed by the fins and a connection wall.

The pipe element having a plurality of fins on at least one of the outer surfaces of the first side wall and / or the second side wall increases the surface of the pipe element for better heat exchange between said second means, such as air, and heat exchanger medium.

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The definition angle Y, enclosed by the fins and a connecting wall, extends the path of heat exchange between the second medium and the surface of the pipe element having a plurality of fins on at least one of the outer surfaces of the first side wall and / or the second side wall. The plurality of fins generates a better air path along the fins and the pipe element. The fins can influence the direction of the air flow along the pipe element. Due to the orientation of the plurality of fins on at least one of the outer surfaces of the pipe element, the air flow along the pipe element in the heat exchanger means can be controlled.

Such a pipe element for a heat exchanger can be an elongated microchannel tube of heat exchanger. An elongated heat exchanger microchannel tube of this type can have a first and second open ends. There may be relatively large parallel opposite side walls of the microchannel tube with generally flat surfaces, which are joined with relatively small opposite edge walls between the side walls. These edge walls can be convexly curved.

The steam or heat transfer fluid can fill a microchannel tube of the heat exchanger and can flow from one end of the microchannel tube to the other end. The term microchannel is also known as a microport.

The said second means such as air can flow around the outer sides of the pipe element and can transport heat from the tube outwards or vice versa.

By providing a plurality of fins on at least one of the outer surfaces of the first side wall and / or the second side wall, the surface for heat exchange increases. Therefore, the efficiency of the heat exchanger can also be significantly improved.

Furthermore, it is possible that the width of the first side wall and the second side wall is approximately at least 10 times greater than the distance between the first side wall and the second side wall and / or that the first side wall and the second wall laterally they are connected respectively on both sides by a rounded connection wall.

Additionally, the pipe element is at least partially inclined or at least partially inclined and with slope and at least partially wound and / or twisted helically in order to form at least a part of a helical structure, so preferably the helical structure It has a general cylindrical structure and / or that the helical structure is shaped with a cylindrical shape.

A pipe element having an inclined orientation also creates an inclined orientation of the fins that are polished on at least one of the outer surfaces of the first side wall and / or the second side wall.

The helical structure of the pipe element is determined simply by the variables radius r, angle a and angle p. The radius r defines the distance between the center of the pipe element and the central longitudinal axis X of the heat exchanger means. The angle a defines the slope of the pipe element and extends between the central longitudinal axis X of the heat exchanger means and the central axis Z of the pipe element. The angle p defines the inclination of the pipe element and extends between the central longitudinal axis X of the heat exchanger means and the central transverse axis Y of the pipe element.

Therefore, due to the inclined orientation of the pipe element, there are almost no horizontal surfaces in the pipe element within the heat exchanger medium. The natural condensate of the air humidity disappears very quickly due to the inclined pipe element and at least partially wound and / or helically twisted. The natural condensate of the air humidity disappears to the external surface of the heat exchanger medium, due to the inclined orientation of the pipe element. Therefore, the freezing of the condensate of the air humidity between each of said pipe elements can be minimized.

In comparison with the prior art, the pipe element, at least partially inclined and at least partially wound and / or helically twisted to form at least a part of a helical structure, is more efficient with less material. In addition, the heat exchanger means needs a smaller volume throughout the heat exchanger system, due to the compact set of pipe elements, making this heat exchanger a high power density solution with a minimal volumetric footprint.

In addition, this pipe element, at least partially inclined and at least partially wound and / or helically twisted to form at least a part of a helical structure, effects a better interaction between said second means such as air and the surface of the element of pipe, due to the inclined orientation of the pipe element.

Furthermore, it is possible that the pipe element has a plurality of fins on both outer surfaces of the first side wall and the second side wall. By providing a plurality of fins on both surfaces

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outside the first side wall and the second side wall, the advantage is obtained that the surface used for heat exchange can be very easily increased and that the volume necessary for the pipe element is not substantially increased.

It is also possible that the fins are at least partially covered by a drain plate and / or that the fins are monobloc fins.

The fins can be arranged substantially perpendicularly on at least one of the outer surfaces of the first side wall and / or the second side wall.

Alternatively, the fins are arranged inclined on at least one of the outer surfaces of the first side wall and / or the second side wall, whereby, in an exemplary manner, the angle between the fins and the outer surface is chosen within a range of approximately 15 ° to 85 °.

Additionally, the fins simply extend along the entire width of at least one of the outer surfaces of the first side wall and / or the second side wall and / or are curved.

In addition, the fins are arranged along a curve that extends along the entire width of at least one of the outer surfaces of the first side wall and / or the second side wall and / or are curved, with what between the fins arranged along a curve is a gap and / or space.

It is possible that the fins and / or the curve of the fins and at least one of the connecting walls are arranged such that they contain an angle. The angle can be substantially perpendicular. Alternatively, the angle can be chosen within the range of about 15 ° to about 60 ° and preferably is chosen within a range of about 20 ° to about 25 °. An angle of approximately 45 ° between the fins or the curve of the fins and at least one of the connecting walls is considered to be substantially neutral, in particular as a neutral arrangement with respect to interference with, for example, fans or the like. , which could be connected or used together with a heat exchanger means comprising said pipe element.

The fins and / or the curve of the fins may be slightly concave or convex. In particular, the slightly concave or convex shape of the fins can be achieved by displacing the central part of the middle section of the fins and / or the curve of the fins with respect to the end points of the fins and / or of the curve of the fins within a range of about 0.5 mm to about 5 mm, preferably from about 1 mm to about 2 mm, most preferably about 1.5 mm.

It is preferred that the fins are arranged so that the medium flowing against the fins flows against a concave formed part of the fin.

The fins may have a height chosen within a range of about 0.5 mm to about 5.0 mm, preferably about 2-3 mm.

Furthermore, it is possible that the fins are arranged in a plurality of rows, preferably substantially parallel rows and / or preferably along at least a part of the length of the pipe element.

The pipe element may comprise at least one microchannel. Preferably, several microchannels are provided with a round or circular cross section and / or several microchannels with an angular cross section, exemplary several microchannels with a triangular cross section and / or several microchannels with a quadrangular cross section.

At least some of the microchannels can be arranged with a deviation from each other, so, for example, all microchannels are arranged with a deviation from each other.

The deflection can result in several bevels and / or grooves within the first side wall and / or the second side wall.

In addition, the pipe element may comprise at its first end and at its second end a collecting portion that reduces the width of the first side wall and the second side wall to a smaller width.

Further, the present invention relates to a heat exchanger means with the features of claim 9. Accordingly, a heat exchanger means is provided, the heat exchanger means having at least one tubular element according to any of the claims. 1 to 8

Additionally, the heat exchanger may comprise several pipe elements that are formed as a substantially cylindrical overall structure that has a central longitudinal axis and that the pipe elements are spirally curved about the central longitudinal axis and interspersed in the structure.

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The heat exchanger medium may be a radiator or a refrigerator or a condenser or an evaporator.

Further, the present invention relates to a method of manufacturing a pipe element with the features of claim 12. Accordingly, a pipe element according to any one of claims 1 to 8 is manufactured, whereby the element Pipe is received using an extrusion process of a heat transfer material, so preferably the extrusion process is a unique extrusion process. In addition, preferably the heat exchanger material is at least partially aluminum or copper or an alloy thereof.

More details and advantages of the present invention will be described below with respect to the drawings:

Figure 1: perspective view of the pipe element according to the present invention in a first embodiment;

Figure 2: perspective view of a pipe element according to a first embodiment of the present invention;

Figure 3: Additional perspective view of the pipe element shown in Figure 2 showing the angles for the slope and inclination of the pipe element;

Figure 4: Perspective view shown in Figure 3 in more detail;

Figure 5: Perspective view of a pipe element according to the present invention and as shown in Figure 2 together with connection elements;

Figure 6: side elevation of the pipe element as shown in Figures 2 to 5;

Figure 7: perspective view of a heat exchanger comprising a plurality of pipe elements;

Figure 8: perspective view of a pipe element according to the present invention in a second embodiment;

Figure 9: Detailed perspective view of the embodiment shown in Figure 8 :.

Figure 10a, b: perspective view of a drain plate and the respective pipe element thereof; Y

Figure 11: Perspective view of a further embodiment of a heat exchanger comprising the drain plate and the pipe element according to Figures 10a, b.

Figure 1 shows the perspective view of a first embodiment of the pipe element 10, however, without fins 60 or fins 60 '.

The pipe element 10 is a rigid elongated heat exchanger tube having a first end 20 and a second end 30. There are relatively large parallel side walls 40 and 50 with generally flat surfaces. The opposite side walls arranged parallel 40, 50 of the pipe element are joined to relatively small opposite edge walls 45, 55, which are rounded connecting walls 45, 55. The pipe element 10 is partially inclined and sloped and also rolled and twisted helically as to form at least a part of a helical structure.

The distance d between the first side wall 40 and the second side wall 50 is considerably smaller than the width W of the side walls 40, 50.

There are relatively large parallel side walls 40 and 50 with generally flat surfaces. The opposite side walls arranged parallel 40, 50 of the pipe element are joined with relatively small opposite edge walls 45, 55, which are rounded connecting walls 45, 55. The pipe element 10 is partially inclined and sloped and also rolled and twisted helically as to form at least a part of a helical structure.

The opposite side walls 40 and 50 of the heat exchanger microchannel tube 10 are arranged in opposition in general parallel planes on the propeller inside the tube 10 and there may be one or more medium flow channels, which are formed between the arranged side walls. in opposition 40, 50. A steam or heat transfer fluid such as water or oil or coolant fills the heat exchanger microchannel tube 10 and flows from one end 20 of the microchannel tube 10 to the other end 30. Preferably, the propeller resulting from the microchannel tube 10 is shaped in a cylindrical shape

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Figure 2 shows a perspective view of a first embodiment of the pipe element 10. On both outer surfaces 42, 52 of the first side wall 40 and of the second side wall 50, several fins 60 are arranged.

The fins 60 may be monobloc fins and are disposed inclined with respect to the outer surface 42, 52 of the first side wall 40 and a second side wall 50. The angle between the fins and the outer surface 42, 52 is 22.5 degrees In this example. The fins 60 simply extend along the entire width W of the outer surfaces 42, 52 of the first side wall 40 and the second side wall 50.

As can be seen, for example, in Figures 5 and 6, the fins 60 are slightly curved.

Figure 3 shows the definition angles, that is, the angle at which a slope defines and the angle p1 that defines the inclination. In addition, Figure 3 shows the definition axes X, Y and Z and also the radius r. The heat exchanger microchannel tube 10 may be longitudinally curved about the central axis X in a propeller. This X axis is shown in Figure 3 and is the central X axis of the general and imaginary cylindrical shape of the propeller.

As can be seen in Figure 3, fins 60 follow the slope and inclination.

The angle at which the slope is defined is defined as the angle between the X and Z axes. The angle p1 that defines the inclination is defined as the angle p1 between the X and Y axes. As can be seen in Figure 3, the radius r is the distance from the X axis to the center of the angled pipe element with fins 10 and / or the intersection point of the Y axis and the Z axis.

As can be seen additionally in Figure 4, the fins 60 have two angles of definition Y and 6. The angle Y is the angle that is delimited by the fins 60 and the connection walls 45, 55 as also shown in the figures 2, 5 and 8. The angle 6 is the angle of the fin 60 and the outer surface 42, 52 of the first side wall 40 or the second side wall 50.

As can be seen from the additional detail shown in Figure 4, the first distance between two adjacent fins 60 is greater than a second distance b of these adjacent fins 60. The first distance a2 is used in the entrance section of the space defined by two adjacent fins 60, that is, the section for the entry of a heat transfer medium flowing through the fins. In this way, the fins 60 are substantially parallel.

The fins 60 according to the embodiment shown in Figures 2 to 6 are arranged at angles between 22.5 and 45 degrees with respect to the outer surfaces 42, 52 of the first side wall 40 and the second side wall 50 .

This, however, is not mandatory. Alternatively, the fins 60 may be arranged inclined on at least one of the outer surfaces 42, 52 of the first side wall 40 and / or of the second side wall 50, whereby, for example, the angle between the fins 60 and The outer surface 42 or 52 can be chosen within a range of approximately 15 ° to 85 °.

The fins 60 simply extend along the entire width W of the outer surfaces 42, 52 of the first side wall 40 and / or the second side wall 50 and are slightly curved.

In addition, the fins 60 are arranged in a plurality of parallel rows substantially along the entire length of the pipe element 10.

The fins 60 and the connecting walls 45, 55 are arranged such that they contain an angle and.

However, this angle and can be substantially perpendicular. Alternatively, this angle and can be chosen within the range of about 15 ° to about 60 ° and can preferably be chosen within a range of about 20 ° to about 25 °. An angle of approximately 45 ° between the fins 60 and at least one of the connecting walls 45, 55 is considered to be substantially neutral, in particular as a neutral arrangement with respect to interference with, for example, fans or the like, which they are connected or used together with a heat exchanger means comprising said pipe element 10.

The fins 60 are formed slightly concave or convex, which, however, is not mandatory. In particular, the slightly concave or convex shape of the fins 60 can be achieved by displacing the central part of the middle section of the fins 60 with respect to the end points of the fins 60 within a range of approximately 0.5 mm to about 5 mm, preferably about 1 mm to about 2 mm, most preferably about 1.5 mm. In the embodiment shown in Figure 2, the displacement of the central part of the middle section of the fins 60 with respect to the end points of the fins 60 is approximately 1 mm.

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The fins 60 are arranged so that the medium flowing against the fins flows against a concave part formed of the fin.

In addition, the fins 60 according to the embodiment shown in Figure 2 have a height of approximately 2.5 mm. Generally, the fins 60 may have a height chosen within a range of about 0.5 mm to about 5.0 mm, preferably about 2-3 mm.

At the ends 20, 30 of the pipe element 10, collecting elements 25, 35 are provided, which reduce the width of the pipe element 10 to a larger diameter, that is, the diameter of the tubular connectors of circular cross-sections 27, 37.

Fig. 7 is a perspective view of a heat exchanger means 100 comprising a plurality of a first set of interlocking inclined helical microchannel pipe elements 10 with adjacent tubing elements 10 helically shaped and similarly twisted and a second respective set S2 within the first set S1. With this, a compact structure is received together with an increased surface for heat exchange.

Figure 8 is a perspective view of the second embodiment of the pipe element according to the present invention. The second embodiment of the pipe element 10 'is merely the same as that shown in Figures 2 to 6. However, a different type of fins, ie fins 60', is used. The fins 60 'are arranged along a curve that extends substantially throughout the width W of at least one of the outer surfaces 42, 52 of the side wall 40 and of the side wall 50 and as can be seen in the Figure 9, a space is provided between each fin 60 'arranged along a curve. The fins 60 'are arranged in a plurality of rows that are arranged in parallel.

The fins 60 'according to the embodiment shown in Figure 8 are arranged at an angle of 22.5 degrees with respect to the outer surfaces 42, 52 of the first side wall 40 and the second side wall 50.

Alternatively, the fins 60 'may be arranged inclined on at least one of the outer surfaces 42, 52 of the first side wall 40 and / or of the second side wall 50, whereby for example the angle between the fins 60' and the outer surface 40, 50 is substantially perpendicular.

In addition, the fins 60 'are arranged along a curve that extends along the entire width W of the outer surfaces 42, 52 of the first side wall 40 and / or the second side wall 50 and are also curved, whereby between the fins 60 'which are arranged along a curve there is a space 62.

It is possible that the fins 60 'and the curve of the fins 60' and the connecting walls 45, 55 are arranged such that they contain an angle y.

However, this angle and can be substantially perpendicular. Alternatively, this angle and can be chosen within the range of about 15 ° to about 60 ° and can preferably be chosen within a range of about 20 ° to about 25 °. An angle of approximately 45 ° between the fins 60, at least one of the connecting walls 45, 55 is considered to be substantially neutral, in particular as a neutral arrangement with respect to interference with, for example, fans or the like, which can be connected or used together with a heat exchanger means comprising said pipe element 10.

The fins 60 'and the curve of the fins 60' form slightly concave. In particular, the slightly concave shape of the fins 60 'is achieved by means of a displacement of the central part of the middle section of the fins 60' and the curve of the fins 60 'with respect to the end points of the fins 60 'and the curve of the fins 60' within a range of about 0.5 mm to about 5 mm, preferably from about 1 mm to about 2 mm, most preferably about 1.5 mm.

The fins 60 'are arranged so that the medium flowing against the fins 60' flows against a concave part formed of the fins 60 '.

In addition, the fins 60 'according to the embodiment shown in Figure 8 have a height of approximately 3 mm. Generally, the fins 60 'can have a height chosen within a range of about 0.5 mm to about 5.0 mm, preferably about 2-3 mm.

The curves of the fins 60 'are arranged in a plurality of substantially parallel rows along the pipe element.

Figure 9 shows in detail the embodiment of a tube 10 'with fins 60' as shown in Figure 8 and has a plurality of microchannels 70 with a square cross section.

Figure 10a shows in a perspective view a drain plate 80 that is inclined and helically wound so that it can be attached to the microchannel tube of the helically wound heat exchanger 10 as shown in Figure 10b.

As can be seen additionally in Figure 11, several drain plates 80 and heat exchanger tubes 5 10 can be arranged in a heat exchanger 100 comprising a plurality of tube elements

estuary 10 of microchannel helically wound and inclined inclined slopes and drain plates 80 between each of the pairs of adjacent pipe elements 10.

The use of drain plates 80 is preferred in cases where the heat exchanger means 100 is an evaporator.

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Claims (13)

5 10 fifteen twenty 25 30 35 40 Four. Five 1. Pipe element (10, 10 ') for a heat exchanger means (100, 100'), the pipe element (10, 10 ') being at least partially a rigid elongated heat exchanger tube having at least a first end (20) and at least a second end (30) and having a first side wall (40) and a second side wall (50), the first side wall (40) and the second side wall (50) being arranged substantially parallel to each other and being a distance (d) between the first side wall (40) and the second side wall (50) considerably smaller than the width (W) of the first side wall (40) and of the second side wall (50), resulting in a substantially flat general pipe structure with connecting walls (45, 55) on both sides, the pipe element (10, 10 ') having a plurality of fins (60, 60 ') on at least one of the outer surfaces (42, 52) of the first side wall (40) and / or of the second side wall (50), in which the pipe element is at least partially inclined or at least partially inclined and sloping and at least partially wound and / or helically twisted to form at least a part of a helical structure, characterized in that the fins (60, 60 ') are arranged along a curve that extends along the entire width (W) of at least one of the outer surfaces (42, 52) of the first side wall (40) and / or of the second side wall (50) and are curved, so that between the fins (60, 60 '), which are arranged along a curve, there is a gap and / or a space and the fins (60 , 60 ') are arranged in a plurality of rows, in which the fins (60, 60') extend along a curve that extends between the connecting walls (45, 55), wherein a first distance (a) in the entrance section of the space defined by two adjacent fins (60, 60 ') is greater than a second distance (b), in which the fins (60, 60 ') have an angle of definition and delimited by the fins (60, 60') and a connection wall (45, 55). 2. Pipe element (10, 10 ') according to claim 1, characterized in that the width (W) of the first side wall (40) and the second side wall (50) is approximately at least 10 times greater than the distance (d) between the first side wall (40) and the second side wall (50 ) and / or because the first side wall (40) and the second side wall (50) are connected respectively on both sides by a rounded connection wall (45, 55). 3. Pipe element (10, 10 ') according to claim 1, characterized in that The helical structure has a cylindrical overall structure and / or the helical structure is formed in a cylindrical shape. 4. Pipe element (10, 10 ') according to any of the preceding claims, characterized in that The pipe element (10, 10 ') has a plurality of fins (60, 60') on both outer surfaces (42, 52) of the first side wall (40) and the second side wall (50). 5. Pipe element (10, 10 ') according to any of the preceding claims, characterized in that the fins (60, 60 ') are at least partially covered by a drain plate (80). 6. Pipe element (10, 10 ') according to any of the preceding claims, characterized in that the fins (60, 60 ') are monobloc fins. 7. Pipe element (10, 10 ') according to any of claims 1 to 6, characterized in that 5 10 fifteen twenty 25 the fins (60, 60 ') are arranged inclined on at least one of the outer surfaces (42, 52) of the first side wall (40) and / or of the second side wall (50), whereby angle 6 between the fins (60, 60 ') and the outer surface (42, 52) is chosen within a range of approximately 15 ° to 85 °. 8. Pipe element (10, 10 ') according to any of the preceding claims, characterized in that the pipe element (10, 10 ') comprises at its first end (20) and at its second end (30) a collecting portion (25, 35) that reduces the width of the first side wall (40) and the second side wall (50) to a smaller width. 9. Heat exchanger means (100, 100 ') having at least one pipe element (10, 10') according to any of the preceding claims. 10. Heat exchanger medium (100, 100 ') according to claim 9, characterized in that Several pipe elements (10, 10 ') form a substantially cylindrical overall structure that has a central longitudinal axis (X) and because the pipe elements (10, 10') are spirally curved around the central longitudinal axis (X) e interspersed in the structure. 11. Heat exchanger medium (100, 100 ') according to claim 9 or 10, characterized in that The heat exchanger medium (100, 100 ') is a condenser or an evaporator or a radiator or a refrigerator. 12. Method of manufacturing a pipe element (10, 10 ') according to any one of claims 1 to 8, wherein the pipe element (10, 10') is received using an extrusion process of a material of heat transfer, so preferably the extrusion process is a unique extrusion process. 13. Method of manufacturing a pipe element (10, 10 ') according to claim 12, characterized in that The heat transfer material is at least partially aluminum or copper or an alloy thereof.