EP0938380A1 - Method and device for producing structured sheet metal - Google Patents

Abstract

The invention relates to a method and a device to produce structured sheet metal. According to the inventive method, a strip of sheet metal (6) initially undergoes a structuring operation wherein a structure (8) is formed, whose structural height (H) is greater than a theoretical structural height (SH), followed by a calibration operation in a calibration unit (9). The structure (8) is guided through two rollers (10, 11) of the calibration unit (9) whereby the height of the structure once it has passed through the calibration unit (9) corresponds to the theoretical structural height (SH).

Description

 Method and device for producing structured metal sheets

The invention relates to a method for producing at least one structured metal sheet, a method for producing a coated sheet metal stack and an apparatus for producing structured metal sheets. Such metal sheets are predominantly processed into honeycomb bodies for catalytic converters, as are used in particular in exhaust systems of motor vehicles. Such a honeycomb body is described for example by EP 0 245 737 B1.

In the prior art, structured metal sheets are generally produced by intermeshing profile rollers, which preferably have involute teeth or a similarly shaped teeth. However, there are other geometries of the structures, e.g. B. trapezoidal shape, zigzag shape, etc., known.

Sections are separated from the structured, band-shaped metal sheet, which are stacked to form a metal sheet stack, a smooth sheet being inserted between the structured metal sheets. For example, the ends of the stack are intertwined in opposite directions about at least two fixed points. The stack thus deformed is inserted into a casing tube. The jacket tube with the metal sheet stack used is then subjected to a soldering process in which the jacket tube is soldered to the metal sheet stack and the individual sheets to one another. The jacket tube and the sheet metal package have different coefficients of thermal expansion. In order to ensure that a perfect solder connection between the metal sheets and the metal sheets and the casing tube is achieved, it has already been proposed that the metal sheet insert package with a prestress in the jacket tube, so that no gap occurs between the metal sheets and / or the metal sheets and the jacket tube. In the case of spirally wound honeycomb bodies, it has already been proposed to provide radial depressions in the structured metal sheet at the apex areas of the structure, in which the material used for the soldering can be inserted.

During the structure-forming step, the band-shaped metal sheet is deformed. Fluctuations in the material properties of the metal sheet lead to fluctuations in the structural height of the structured metal sheet. These fluctuations in the structural height are attributed to the fact that the elasticity of the metal sheet lies within a tolerance band. This effect is possibly also superimposed by tolerances of the profile rolls, so that it is not ensured that metal sheet packages can always be inserted into a tube with the same prestress. It has also been found that the cell density of a honeycomb body can also be different in the same production process.

Proceeding from this, the invention is based on the object of specifying a method for producing at least one structured metal sheet and a layered sheet metal stack and a device for producing structured sheets by which it is ensured that when the structured metal sheets or the metal sheet stack are further processed into a honeycomb body, Fluctuations in a preload with which a metal sheet package can be inserted into a jacket tube are small. Another object of the invention is to ensure that a honeycomb body formed by structured metal sheets has a constant cell density.

The method according to the invention for producing at least one structured metal sheet is characterized in that initially in a structured forming step, a ribbon-shaped metal sheet is formed with a structure. During the structure-forming step, a structure is produced whose structure height is greater than a target structure height that the structured metal sheet is to have as a finished product. The structure-forming step is followed by a calibration step in which a force is exerted on the structure of the metal sheet in such a way that after the calibration step the height of the structure corresponds to the desired structure height. The fact that during the structure-forming step the structure height is greater than a desired structure height ensures that the structure height of the metal sheet is sufficiently high despite springback. Furthermore, any tolerances of profile tools are compensated. In the calibration step, a force is exerted on the apex areas of the structure, by which the structure is deformed, so that after the calibration step the height of the structure corresponds to the desired structure height.

To form a structure during the structure-forming step, the metal sheet is passed between two intermeshing profile rollers. The total profile height of the profile rollers is greater than the target structure height. The profile rollers can, for example, be rollers with an involute profile.

The calibration step is preferably carried out in such a way that the metal sheet with the structure is passed through a gap, the gap height of which is smaller than the desired structural height of the metal sheet or corresponds to the desired structural height of the metal sheet. Such a gap can be formed in that two rollers are arranged axially parallel.

To ensure that a honeycomb body that consists of a structured

Sheet metal or a sheet metal package is produced, has a constant cell density, it is proposed that after the calibration step Spring property of the structure of the metal sheet is determined. Taking the spring property into account, a cut length is determined and a section of a metal sheet is cut from the band-shaped metal sheet in accordance with the cut length. A structured metal sheet produced in this way can be used to produce a honeycomb body which has a reproducible cell density and the metal sheets can be inserted into a jacket tube with a reproducible prestress.

According to another concept according to the invention, a method for producing a layered sheet metal stack, as is known, for example, from EP 0 245 737, is proposed, in which a first band-shaped sheet metal is first subjected to a structure-forming step by which the first sheet metal is formed with a structure, whose structure height is greater than the desired structure height, then a calibration step, in which a force is exerted on the structure of the first metal sheet, that after the calibration step the height of the structure corresponds to a desired structure height, and then a second band-shaped metal sheet on the first metal sheet is placed.

During the structure-forming step, the first band-shaped metal sheet is passed between two intermeshing profile rollers.

Alternatively, it is proposed that the second metal sheet be placed on the metal sheet before the calibration step. With this measure, the structured metal sheet is calibrated together with the second, preferably smooth, metal sheet.

After the calibration step, the spring characteristic of the structure of the first

Sheet metal or the spring property of the layered metal sheets is determined and, taking the spring property into account, a cut length determined, and the first metal sheet or the layered metal sheets are cut according to the cut length.

According to a further idea according to the invention, a device for producing structured metal sheets with a structuring unit for forming a structure with a structure height is proposed, in which the structuring unit, which has at least two interlocking profile tools with an overall profile height that is greater than the desired structure, and one in the transport direction of the metal sheet considers downstream calibration unit, through which a force is exerted on the structure of the metal sheet such that the height of the structure corresponds to a predetermined desired structure height.

The structuring unit has at least two intermeshing profile rollers, which preferably have an involute profile. The use of rotatable profile rollers enables a continuous manufacturing process of a structured metal sheet. Alternatively, for the sequential production of a structure in a metal sheet, a structuring unit can be used which comprises two profile tools which can be moved towards one another and between which the metal sheet can be deformed.

According to a further advantageous development of the device, it is proposed that the calibration unit have at least two calibration tools between which the metal sheet can be placed, and the calibration tools limit a gap whose gap height is smaller than the profile height of the profile tools. The gap height preferably corresponds to the target structural height that a structured metal sheet is to have. The gap height is preferably adjustable by adjusting the calibration tools. The calibration tools are preferably formed by two rollers arranged essentially axially parallel. The rollers are preferably arranged such that the roller axes run essentially transversely to the direction of transport of a metal sheet.

According to a further advantageous development of the device, it is proposed that the calibration unit is followed by a measuring unit by which the spring property of the metal sheet is determined, and a separating unit by which the metal sheet is cut to length according to the spring property.

Further advantages and features of the invention are explained on the basis of the exemplary embodiments shown in the drawing. Show it:

1 schematically shows a first embodiment of a device for producing structured metal sheets,

Fig. 2 shows a calibration unit and

3 shows a second exemplary embodiment of a device for producing structured metal sheets.

Fig. 1 shows schematically a device for producing structured sheets. The device has a structuring unit 1. The structural unit 1 comprises two intermeshing profile rollers 2, 3. The profile rollers 2, 3 have, for example, an involute-shaped profile. The axes 4, 5 of the profile rollers 2, 3 run parallel to one another. Between the profile rolls 2, 3 runs a band-shaped metal sheet 6, which is unwound from a coil 7. A structure 8 is imparted to the metal sheet 6 as it passes through the structuring unit 1. The structure 8 essentially corresponds to the profile of the profile rolls 2, 3. When viewed in the transport direction of the metal sheet 6, the structuring unit 1 is followed by a calibration unit 9. The calibration unit 9 has two calibration tools which are designed in the form of two rollers 10, 11. The rollers 10, 11 are arranged axially parallel to one another. The lateral surfaces of the rollers 10, 11 delimit a gap 12 through which the structured metal sheet 6 is passed. The calibration unit 9 is followed by a measuring unit 13 and a separation unit 14.

The spring property of the structure 8 of the metal sheet 6 is determined by the measuring unit 13. Taking into account the spring property of the structure 6, a cut length L is determined and a section 15 corresponding to the cut length L is separated from the band-shaped metal sheet 6 in the separating unit 14. The spring property of the structure 6 of the metal sheet can be determined by a force / displacement measurement.

The profile of the profile rollers 2, 3 is designed such that the height H of the structure 8 is greater than a predetermined desired structure height SH. The metal sheet 6 is given a structure 8, as shown for example in FIG. 2. The metal sheet structured in this way is felt through the gap 12 between the rollers 10, 11. The height h of the gap 12 is dimensioned such that when the metal sheet 6 passes between the rollers 10, 11, the structure 8 is compressed, as a result of which the structure 8 'according to the calibration unit 9 has a height which corresponds to the desired structure height SH . The rollers 10, 11 are rotatably mounted. The gap height h is preferably adjustable by means of adjustable rollers 10, 11.

We now refer to the representation of a device according to FIG. 3. The device shown in FIG. 3 has a structuring unit 1, which is formed by two profile rollers 2, 3 arranged at a distance from one another and axially parallel. Viewed in the direction of transport, the profile unit 1 is followed by a calibration unit 9, to which a measuring unit 13 and a separation unit 14 are connected. The calibration unit 9 is formed by two rollers 10, 11 arranged at a distance from one another and axially parallel. The rollers 10, 11 are rotatably mounted. The lateral surfaces of the rollers 10, 11 delimit a gap 12.

A strip-shaped metal sheet 6 is unwound from a coil 7 and fed to the structuring unit 1. In the structuring unit 1, the metal sheet 6 is given a structure 8 by the profile rollers 2, 3. The structure 8 has a height H which is greater than the desired structure height SH. The metal sheet 6 structured in this way is subsequently fed to the calibration unit 10. The metal sheet 6 passes through the gap 12 between the rollers 10, 11. The gap 12 has a height h which is smaller than the height H of the structure 8. During the passage of the metal sheet 6 through the calibration unit 9, the structure 8 becomes one Force exerted by which the height of the structure is brought to the desired structure height SH. In front of the calibration unit 9, a smooth metal sheet 16 is fed onto the structured sheet 6, which is unwound from a coil 17. The smooth metal sheet 16 and the structured metal sheet 8 pass through the calibration unit 9 together.

The calibration unit 9 is followed by a measuring unit 13, by means of which the spring properties of the smooth and the structured metal sheet 6, 16 are determined. A cut length L is determined on the basis of the spring property determined. A separating unit 14 following the measuring unit 13 separates a section 8 of the smooth metal sheet 16 and the structured metal sheet 6. The structured sheets 6 are stacked one on top of the other, creating a Sheet metal package 19 is formed, which can be inserted into a jacket tube after being devoured.

B e z u g s z e i c h e n l i s t e

1 structuring unit

2, 3 profile roller

4, 5 axis

6 sheet metal

7 coil

8, 8 'structure

9 calibration unit

10, 11 roller

12 gap

13 measuring unit

14 separation unit

15 section

16 smooth sheet

17 coil

18 section

19 sheet metal package

Claims

PATENT CLAIMS

1. A method for producing at least one structured metal sheet, in which a band-shaped metal sheet (6) first has a structure-forming step by which a structure (8) is formed, the structure height (H) of which is greater than a desired structure height (SH) , and then a calibration step in which a force is exerted on the structure (8) of the metal sheet (6) so that after the calibration step the height (H) of the structure (8) corresponds to the desired structure height (SH) becomes.

2. The method according to claim 1, wherein the metal sheet (6) is passed between two intermeshing profile rollers (2, 3) during the structure-forming step.

3. The method according to claim 2, wherein the metal sheet (6) between profile rollers (2, 3) is passed, the total profile height is greater than the desired structure height (SH).

4. The method of claim 1, 2 or 3, wherein the metal sheet (6) through a gap (12), the gap height (h) is smaller than the desired structural height (SH) of the metal sheet (6) or the desired structural height (SH) of the metal sheet (6) corresponds, is passed.

5. The method according to claim 4, wherein the gap (12) is formed by two axially parallel rollers (10, 11).

6. The method according to any one of claims 1 to 5, in which according to

Calibration step determines the spring property of the structure of the metal sheet (6), taking into account the spring property a cut length (L) is determined and a section (15, 16) corresponding to the cut length (L) is separated from the band-shaped metal sheet (6).

7. The method according to claim 8, wherein the blank length (L) is used as a measure for further sections.

8. A method for producing a layered sheet metal stack (19), in which a first, band-shaped sheet metal (6) first a structure-forming step through which the first sheet metal (6) with a

Structure (8) is formed, the structure height (H) is greater than the desired structure height (SH), is then subjected to a calibration step in which a force is exerted on the structure (8) of the first metal sheet (6) such that after the calibration step, the height (H) of the structure (8 ') corresponds to a desired structure height (SH), and then a second, band-shaped metal sheet, preferably a smooth metal sheet (6), is placed on the first metal sheet (6).

9. The method according to claim 8, wherein the first metal sheet (6) during the structure-forming step between two intermeshing profile rollers

(2, 3) is passed.

10. The method according to claim 9, wherein the first metal sheet (6) between profile rolls (2, 3) is felt, the total profile height is greater than the desired structure height (SH).

11. The method according to claim 8, 9 or 10, wherein the first metal sheet (6) through a gap (12), the gap height (h) substantially corresponds to the desired structural height (SH) of the first metal sheet (6), to be led.

12. The method according to claim 11, wherein the gap (12) is formed by two axially parallel rollers (10, 11).

13. The method according to claim 11 or 12, in which, however, the second metal sheet (6) is placed on the first metal sheet (6) before the calibration step.

14. The method according to any one of claims 8 to 13, wherein after the calibration step, the spring property of the structure of the first metal sheet (6) or the spring property of the layered metal sheets (6, 16) is determined and cut to length according to the spring property.

15. Device for producing structured metal sheet with a structure setting unit (1) for forming a structure with a structure height

(H), characterized by a structuring unit (1) which has at least two interlocking profile tools (2, 3) with a total profile height that is greater than the desired structure height (SH) and a downstream one viewed in the transport direction of the metal sheet (6) Calibration unit (9), by means of which a force is exerted on the structure (8) of the metal sheet (6) in such a way that the height (H) of the structure (8 ') after the calibration unit (9) has a predetermined desired structure height (SH) corresponds.

16. The apparatus according to claim 15, characterized in that the structuring unit (1) has at least two intermeshing profile rollers (2, 3).

17. The apparatus according to claim 15 or 16, characterized in that the calibration unit (9) at least two calibration tools (10, 11) has, between which the metal sheet (6, 16) can be placed, and the calibration tools (10, 11) limit a gap (12) whose gap height (h) is smaller than the profile height (PH) of the profile tools (2, 3).

18. The apparatus according to claim 17, characterized in that the calibration tools are two axially parallel rollers (10, 11).

19. Device according to one of claims 15 to 18, characterized in that the calibration unit (9) is a measuring unit (1, 3), determined by the spring property of the metal sheet (6, 16), and a separating unit (14), by the the metal sheet (6, 16) is cut to length according to the spring characteristic, is arranged downstream.

20. Device according to one of claims 15 to 19, characterized in that the gap height (h) of the calibration unit (9) is adjustable.