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Patent Searching and Data


Title:
TUBE BODY AND PRODUCTION METHOD
Document Type and Number:
WIPO Patent Application WO/2017/108929
Kind Code:
A1
Abstract:
The invention relates to a tube body (1), in particular for a heat exchanger, with an outer structure (2) composed of a band material (10), which outer structure delimits an outer structure interior space (4) and for this purpose has two mutually opposite wide sides (5a, 5b) and two mutually opposite narrow sides (6a, 6b), with an inner structure (3) integrally formed on the outer structure (2) and composed of the band material (10), which inner structure is arranged in the outer structure interior space (4) and which subdivides the outer structure interior space (4) into at least two fluid ducts (7) which are fluidically separated from one another and intended for the through-flow of a fluid, wherein a material thickness (dI) of the band material (10) of the inner structure (3) is less, at least in certain portions, than a material thickness (dA) of the band material (10) of the outer structure (2).

Inventors:
JEDRASZAK PAWEL (PL)
KRUPA ANDRZEJ (PL)
MALESZKA MICHAL (PL)
ZYWICA LUKASZ (PL)
Application Number:
PCT/EP2016/082145
Publication Date:
June 29, 2017
Filing Date:
December 21, 2016
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
MAHLE INT GMBH (DE)
International Classes:
F28D1/03; F28F3/02
Foreign References:
DE102014200708A12015-07-16
FR2869678A12005-11-04
JPH11351777A1999-12-24
JPH10311694A1998-11-24
Attorney, Agent or Firm:
BRP RENAUD UND PARTNER MBB (DE)
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Claims:
Claims

1 . Tube body (1 ), in particular for a heat exchanger,

with an outer structure (2) composed of a band material (10), which outer structure delimits an outer structure interior space (4) and for this purpose has two mutually opposite wide sides (5a, 5b) and two mutually opposite narrow sides (6a, 6b),

with an inner structure (3) integrally formed on the outer structure (2) and composed of the band material (10), which inner structure is arranged in the outer structure interior space (4) and which subdivides the outer structure interior space (4) into at least two fluid ducts (7) which are fluidically separated from one another and intended for the through-flow of a fluid,

wherein a material thickness (di) of the band material (10) of the inner structure (3) is less, at least in certain portions, than a material thickness (dA) of the band material (10) of the outer structure (2).

2. Tube body according to Claim 1 ,

characterized in that

the tube body (1 ) is formed in one piece.

3. Tube body according to Claim 1 or 2,

characterized in that

the outer structure (2) has a main portion (8) which transitions at the ends into two secondary portions (9a, 9b), wherein the two secondary portions (9a, 9b) are folded in towards the centre to form a closed tube body profile, with the result that the main portion (8) forms a first wide side (5a) and the two secondary portions (9a, 9b) together form a second wide side (5b).

4. Tube body according to one of Claims 1 to 3,

characterized in that,

in order to form the at least two fluid ducts (7), the inner structure (3) has a region (12) of corrugated form which is supported on the mutually opposite wide sides (5a, 5b) of the outer structure (2).

5. Tube body according to Claim 4,

characterized in that

the corrugated region (12) is formed without kinks.

6. Tube body according to Claim 4 or 5,

characterized in that

the corrugated region (12) has a wave-like geometry.

7. Tube body according to any of claims 4 to 6,

characterized in that

the corrugated region (12) having a wave-like geometry is supported on the mutually opposite wide sides (5a, 5b) of the outer structure (2) by means of supporting areas (17), located at apex zones (18) of the corrugated region (12).

8. Tube body according to any of claims 4 to 7,

characterized in that

the material thickness (di) of the band material (10) has a constant value in the corrugated region (12) of the inner structure (3).

9. Tube body according to one of Claims 3 to 8,

characterized in that

the two secondary portions (9a, 9b) in each case have an outer structure end portion (13a, 13b) in which the outer structure (2) respectively transitions into the inner structure (3),

wherein the material thickness of the band material (10) decreases at the transition from the outer structure (2) into the respective inner structure (3).

10. Tube body according to claim 9,

characterized in that

a recess (15a, 15b) is formed in at least an outer structure end portion (13a, 13b), preferably in both outer structure end portions (13a, 13b).

1 1 . Tube body according to claim 10,

characterized in that

the recess (15a, 15b) is located in an inner side (16a, 16b) of the outer structure end portion (13a, 13b) facing the inner structure (3).

12. Tube body according to one of Claims 4 to 1 1 ,

characterized in that

the inner structure (3) has two inner structure end portions (14a, 14b) which face away from the outer structure (2),

wherein the material thickness of the band material (10) in the inner structure end portions (14a, 14b) is enlarged in comparison to the corrugated region (12) of the inner structure (3).

13. Tube body according to Claim 12, characterized in that

at least one inner structure end portion (14a, 14b) fits snugly against a narrow side (6a, 6b) of the outer structure (2).

14. Tube body according to Claim 12 or 13,

characterized in that

the at least one inner structure end portion (14a, 14b) and the narrow side (6a, 6b) assigned to this inner structure end portion (14a, 14b) in each case have a round contour, preferably the contour of a segment of a circle.

15. Tube body according to one of the preceding claims,

characterized in that

the tube body has in the tube profile an axis of symmetry (S) which extends along an axis direction (A) defined by the narrow sides (6a, 6b),

wherein the tube body (1 ) is formed axisymetrically with respect to this axis of symmetry (S).

16. Tube body according to one of the preceding claims,

characterized in that

the tube body (1 ) is formed as a profiled part whose tube profile extends along a direction of longitudinal extent (L) which runs orthogonally to the wide sides (5a, 5b) and orthogonally to the narrow sides (6a, 6b) of the tube profile.

17. Tube body according to one of the preceding claims,

characterized in that

the band material (10) is a sheet metal strip.

18. Heat exchanger having at least one tube body (1 ) according to one of the preceding claims.

19. Method for producing a tube body (1 ), in particular according to one of Clainns 1 to 17, from a band material (10),

in which a material thickness of the band material (10) is reduced to form an inner structure (3) of the tube body (1 ).

Method according to Claim 19,

characterized in that the reduction in the material thickness is obtained by means of a rolling process.

Description:
Tube Body and Production Method

The invention relates to a tube body and to a heat exchanger having at least one such tube body. The invention further relates to a method for producing the tube body.

Flat tubes through which a fluid can flow are routinely used in heat exchangers. While the fluid flows through, heat exchange can be produced between the fluid inside the flat tube and a second fluid, such as, for example, the surrounding air outside the flat tube. To increase stability and heat exchange, rib structures can be arranged inside the flat tube.

The prior art discloses a multiplicity of flat tubes which can be used in a variety of applications. Thus, there exist, for example, extruded flat tubes which have a one-part closed casing. In this context, extrusion processes require high pressures to produce sufficient deformation of the raw material. Furthermore, the investment costs for an extrusion system are very high and the extrusion tools are subject to a high degree of wear. Owing to the high pressures, the tolerance windows for the material thickness of the extruded flat tubes that is produced are relatively high, a factor which can lead to inaccuracies within the context of mass production and to increased reject rates. The tube designs which can be produced by extrusion are also limited.

It is therefore further known for flat tubes for heat exchangers to be fabricated from a sheet metal band in a continuous method on an appropriate tube production machine. After bending and shaping the flat tube cross section, the flat tube is closed by a welded or brazed longitudinal seam. Such flat tubes are used, for ex- ample, for coolant radiators in motor vehicles, the flat tubes being joined by corrugated ribs to form a block and brazed. In order to achieve as low a pressure drop as possible on the air side, the flat tube cross sections are formed to be as slender as possible, and, in order to increase the internal pressure resistance, webs, folds or beads are provided which act as tension rods and divide the flat tube cross section into chambers.

Against this background, DE 10 2008 052 785 A1 discloses a flat tube for heat exchangers having two narrow sides and two wide sides, which flat tube can be produced from at least three sheet metal strips having deformable longitudinal strips. Two of the sheet metal strips form an outer wall of the flat tube, and the third sheet metal strip forms a corrugated inner insert. The three sheet metal strips are brazed to one another.

FR 2 923 591 concerns a flat tube having two end portions folded inwardly towards the centre. Such folding makes it possible to form two fluid ducts which are fluidically separated from one another in the flat tube.

DE 10 2004 concerns a flat tube for a heat exchanger, which is produced from a one-piece sheet metal band and has inwardly directed impressions which act as turbulence generators for the fluid flowing through the flat tube.

DE 37 25 602 concerns a flat tube for a heat exchanger, which is composed of a bent metal strip and has a support web in its interior between the tube flat strips. The metal strip is braze-plated at least on one side. The support web has a bearing surface which is brazed onto the tube wall on the tube flat side.

DE 10 2006 052 581 A1 concerns a flat heat exchanger tube which is produced from a single endless sheet metal strip having a thickness between 0.03 mm and 0.2 mm. The heat exchanger tube has two narrow sides and two wide sides. First and second folds are arranged in the sheet metal strip. A narrow side is formed by means of bends arranged in the narrow side.

DE 10 2014 200 708 A1 concerns a flat tube for a heat exchanger, wherein the flat tube is produced by folding in two mutually opposite free end regions of a one-piece band material. The flat tube has two wide sides and two narrow sides which are formed by an outer structure of the flat tube. An inner structure which subdivides the interior of the flat tube into a plurality of ducts is arranged in the interior of the flat tube.

It is an object of the present invention to demonstrate new approaches in the development of tube bodies, in particular for use in heat exchangers.

This object is achieved by the subject matter of the independent patent claims. Preferred embodiments form the subject matter of the dependent patent claims.

Accordingly, the basic idea of the invention is for a tube body with an outer structure for delimiting a fluid line and an inner structure for subdividing the fluid line into a plurality of individual fluid ducts to be produced in one piece from a band strip. In this context, according to the invention, a material thickness of the band material forming the inner structure is less, at least in certain portions, than a material thickness of the band material forming the outer structure. Since the inner structure serves not only for producing individual fluid ducts but at the same time has the effect of reinforcing the outer structure and thus the entire tube body, there is as a result created a tube body which has a reduced inherent weight in comparison to conventional tube bodies without losses in the stiffness of the tube body being entailed thereby. A tube body according to the invention, in particular for a heat exchanger, comprises an outer structure composed of a band material, which outer structure delimits an outer structure interior space. For this purpose, the tube body has two mutually opposite wide sides and two mutually opposite narrow sides. Integrally formed on the outer structure - and thus likewise composed of the band material - is an inner structure which is arranged in the outer structure interior space. The inner structure subdivides the outer structure interior space into at least two fluid ducts which are fluidically separated from one another and intended for the through-flow of a fluid. According to the invention, a material thickness of the band material of the inner structure is less, at least in certain portions, than a material thickness of the band material of the outer structure.

In a preferred embodiment, the tube body is formed in one piece. This allows simple production of the tube body from a band material, in particular from one or more sheet metal strips.

In a further preferred embodiment, the outer structure has a main portion which transitions at the ends into two secondary portions. The two secondary portions are folded in towards the centre to form a closed tube body profile, with the result that the main portion forms a first wide side and the two secondary portions form a second wide side. In this way, it can be ensured, even when using a band material having a small material thickness, that the outer contour has a high degree of stiffness.

In a further preferred embodiment, in order to form the at least two fluid ducts, the inner structure has a region of corrugated form. Said corrugated region is supported on the mutually opposite wide sides of the outer structure. The formation of a corrugated region allows the subdivision according to the invention of the outer structure interior space into at least two fluid ducts by means of the inner structure in a technically simple manner.

The corrugated region is particularly preferably formed without kinks. In this way, a particularly high degree of stiffness can be ensured in the inner structure.

Preferably, the corrugated region has a wave-like geometry. In this way, mechanical stiffness of the inner structure can be significantly enhanced.

In an advantageous development, the corrugated region having a wave-like geometry is supported on the mutually opposite wide sides of the outer structure by means of supporting areas located at apex zones of the corrugate region. In this way, mechanical stiffness of the inner structure can be significantly enhanced.

In a further preferred embodiment, the material thickness of the band material has a constant value in the corrugated region of the inner structure. This measure is accompanied by a significant reduction in production costs.

The two secondary portions particularly expediently in each case have an outer structure end portion in which the outer structure respectively transitions into the inner structure. In this variant, the material thickness of the band material decreases at the transition from the outer structure into the respective inner structure. In this way, the inherent weight of the entire tube body can be kept particularly low.

In another preferred embodiment, a recess is formed in at least an outer structure end portion, preferably in both outer structure end portions. In this way, folding of the inner structure can be significantly facilitated. In another advantageous embodiment, the recess is located in an inner side of the outer structure end portion facing the inner structure.

In another preferred embodiment, the inner structure has two inner structure end portions which face away from the outer structure. In this variant, the material thickness of the band material in the inner structure end portions is enlarged in comparison to the corrugated region of the inner structure. This measure allows particularly stable fastening of the inner structure to the outer structure with the aid of said inner structure end portions.

Particularly stable fastening of the inner structure to the outer structure can be achieved in a further preferred embodiment in which at least one inner structure end portion fits snugly against a narrow side of the outer structure. This particularly preferably applies to both inner structure end portions of the inner structure.

The at least one inner structure end portion and the narrow side assigned to this inner structure end portion preferably have a round contour, particularly preferably the contour of a segment of a circle. Such a contour can be produced particularly simply by means of a folding operation.

The tube body expediently has in the tube profile an axis of symmetry which extends along an axis direction defined by the narrow sides. In this variant, the tube body is formed axisymetrically with respect to this axis of symmetry. A tube body formed symmetrically in such a way can be produced in a particularly simple manner. This leads to reduced costs in the production of the tube body.

The tube body is particularly expediently formed as a profiled part whose tube profile extends along a direction of longitudinal extent which runs orthogonally to the wide sides and to the narrow sides. In this way, it is also possible for tube bodies having a considerable tube length along the direction of longitudinal extent to be produced with a high degree of stiffness.

The band material can expediently be a sheet metal strip. This allows simple production of the tube body using suitable machines for sheet metal processing.

The invention further relates to a heat exchanger having at least one tube body as presented above.

The invention also relates to a method for producing a tube body as presented above from a band material, in particular from a sheet metal strip. In the method according to the invention, a material thickness in the region of an inner structure of the tube body that is to be formed is reduced, at least in certain portions, in comparison to an outer structure of the tube body that is to be formed.

In an advantageous development, the reduction in the material thickness is obtained by means of a rolling process.

Further important features and advantages of the invention will become apparent from the subclaims, from the drawing and from the associated description of the figure with reference to the drawing.

It will be understood that the features mentioned above and those yet to be explained below can be used not only in the combination specified in each case, but also in other combinations or alone, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are illustrated in the drawing and are explained in more detail in the description which follows. The single Figure 1 shows by way of example a tube body 1 according to the invention which is formed in one piece, in profile. The tube body 1 can be used as a fluid line in a heat exchanger. The tube body 1 comprises an outer structure 2 composed of a band material 10, which outer structure delimits an outer structure interior space 4. The outer structure 2 has a first wide side 5a and a second wide side 5b opposite the first wide side 5a. Furthermore, the outer structure has a first narrow side 6a and a second narrow side 6b opposite the first narrow side 6a. Furthermore, the tube body 1 comprises an inner structure 3 integrally formed on the outer structure 2 and composed of the band material. The inner structure 3 is arranged in the outer structure interior space 4 and subdivides it into a plurality of fluid ducts 7 which are fluidically separated from one another and are intended for the through-flow of a fluid. The band material 10 can be a sheet metal strip or can comprise at least one sheet metal strip.

The tube profile 1 is formed as a profiled part whose tube profile extends along a direction of longitudinal extent L which runs orthogonally to the wide sides 5a, 5b and to the narrow sides 6a, 6b.

The outer structure 2 has in profile a main portion 8 which transitions at its two ends into two secondary portions 9a, 9b. The two secondary portions 9a, 9b are folded in towards the centre 1 1 to form a closed tube body profile. As can be seen from Figure 1 , the main portion 8 forms the first wide side 5a of the outer structure 2, whereas the two secondary portions 9a, 9b form the second wide side 5b.

The inner structure 3 is of corrugated form in certain portions. For this purpose, the inner structure 3 has a region 12 of corrugated form in profile. In the region 12, the inner structure 3 is supported on the two mutually opposite wide sides 5a, 5b of the outer structure 2. As shown in Figure 1 , the corrugated region 12 is preferably formed without kinks in profile. Moreover, the corrugated region 12 can have a wave-like geometry. In this way, mechanical stiffness of the inner structure 3 can be significantly enhanced. The corrugated region 12 having a wave-like geometry is supported on the mutually opposite wide sides 5a, 5b of the outer structure 2 by means of supporting areas 17 located at apex zones 18 of the corrugate region. In this way, mechanical stiffness of the inner structure 3 can be enhanced.

As can be seen from Figure 1 , a material thickness di of the band material 10 of the corrugated region 12 is less than a material thickness d A of the band material 10 of the outer structure 2. Preferably, the material thickness di of the band material has a constant value in the corrugated region 12 of the inner structure 3. This measure is accompanied by a significant reduction in production costs.

According to Figure 1 , the two secondary portions 9a, 9b in each case have an outer structure end portion 13a, 13b in which the outer structure 2 respectively transitions into the inner structure 3 in the profile shown in Figure 1 . The material thickness of the band material decreases at the transition from the outer structure into the respective inner structure from the value d A to the value di.

In the profile of the tube body 1 that is shown in Figure 1 , the inner structure 3 has two inner structure end portions 14a, 14b which face away from the outer structure 2. The first inner structure end portion 14a fits snugly on the inside against the first narrow side 6a of the outer structure 2. The second inner structure end portion 14b fits snugly on the inside against the second narrow side 6b of the outer structure 2.

In the inner structure end portions 14a, 14b of the inner structure 3, the material thickness of the band material 10 is enlarged in comparison to the corrugated region 12 of the inner structure 3. In particular, the material thickness of the inner structure end portions 14a, 14b can have the same value as the material thickness d A of the outer structure 2.

The two inner structure end portions 14a, 14b and the two narrow sides 6a, 6b can in each case have a round contour, preferably the contour of a segment of a circle as illustrated in Figure 1 .

According to Figure 1 , the tube body 1 has in the profile of Figure 1 an axis of symmetry S which extends along an axis direction A defined by the narrow side. As can be seen from Figure 1 , the tube body 1 is formed axisymetrically with respect to this axis of symmetry S.

During the production of the tube body 1 described here, the inner structure 3 can be formed from the band material 10, that is to say typically from a sheet metal strip, by reducing the material thickness of the band material 10. By contrast, there is no need for such a reduction in the material thickness in that region of the band material 10 which is to form the outer structure 2. The desired reduction in the material thickness can preferably be achieved with the aid of a rolling process. Preferably, the reduced material thickness has an value of at least 0.01 mm.

According to figure 1 , a recess 15a, 15b can be formed in the outer structure end portions 9a, 9b, respectively. In this way, when fabricating the tube body 1 , folding of the inner structure 3 with respect to the outer structure 2, can be significantly facilitated. Preferably, the recess is located in an inner side 16a, 16b of the respective outer structure end portion 9a, 9b facing the inner structure 3.

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