EP1466676A1 - Method and apparatus for producing a closed metal profile or metal pipe having a longitudinally varying wall thickness - Google Patents

Abstract

The method involves shaping a sheet metal band (7) with thickness varying along its length using roller shaping tools (3,5) to form a profile or pipe, calibrating the profile or pipe in at least one calibration pair of rollers to defined external dimensions and welding the abutting narrows sides of the band together to make a closed profile or pipe. An independent claim is also included for the following: (a) a roller shaping system.

Description

The invention relates to a method for producing a closed metal profile or metal pipe, the wall thickness of which varies along its longitudinal axis, and a roll forming system to carry out the process. Rollumformanlagen and methods for roll forming sheet metal strips are being manufactured of closed metal profiles or metal pipes for a long time and widely used; however, it was previously only possible to use metal profiles or To manufacture metal pipes whose wall thickness is constant along their longitudinal axis remains.

Especially for profiles and tubes made of high quality materials as well as for use in products that are to be constructed as lightly as possible and yet remain stable it is often desirable to have the walls of the profile or tube just there train thicker where it is necessary for reasons of stability.

Process for the production of profiles with varying over their cross-section Wall thicknesses using roll forming tools from a sheet metal strip are, for example from WO 00/29138 and from EP 1 210 998 A2 of the applicant known. In these writings, a sheet metal band is first produced, the thickness of which varies transversely to its longitudinal direction. After that, this becomes special manufactured sheet metal strip in a conventional roll forming system to a profile reshaped with varying wall thickness.

However, this principle is not easy on metal strips along their length Varying thickness transferable, from which then a metal profile or metal tube could be made. Aside from being a roll forming from According to conventional wisdom, metal strips are only for processing of sheets with a constant thickness in the longitudinal direction is suitable for roll forming a sheet metal strip with a varying thickness along its length a hardly weldable intermediate. Because the bend radii that the Roll forming of a sheet metal strip depends in particular on the thickness the same. The location of the neutral fiber when bending the sheet is located approximately in the middle between the top and bottom of the sheet metal strip. As a result, the neutral fiber in thick sheet metal strips is further from that Surfaces of the roll forming tools removed than with thin strips. Moreover there are pressures in the edge areas of the bending radii if a Sheet metal strip is passed through a pair of roll forming tools, the radii of which are designed for a thinner sheet metal strip. You only get on in the result the sections with a higher sheet thickness a profile or pipe, in which the Butt the narrow sides of the metal strip together. In the sections of the profile or pipe with a smaller sheet thickness remains a more or less large Gap between the narrow sides of the sheet metal strip, which is a conventional one Longitudinal welding for closing the profile or tube is very difficult or makes impossible.

The invention is therefore based on the object, not only profiles with constant Wall thickness or with wall thicknesses that only vary in cross section by roll forming, but also profiles and pipes with in the longitudinal direction varying wall thickness.

This problem is solved by a method with the features of the attached Claim 1 and by a roll forming system with the features of the attached claim 11.

Preferred developments of the method according to the invention result from claims 2 to 10; advantageous embodiments of the invention Roll forming equipment are set out in claims 12 to 20.

The core of the method according to the invention thus consists of the following Process steps: First, what is in the prior art considered impossible or at least very disadvantageous and undesirable a sheet metal strip with a thickness varying along its length was used and fed to a roll forming system with roll forming tools, where it becomes a Profile or tube is formed. Before that is made by the forming Profile or tube lengthways in a conventional manner in a welding station If a closed profile or pipe is processed further, the formed one is Profile or tube in a completely new intermediate step to given External dimensions calibrated using at least one pair of calibration rollers. This calibration can already be done on the profile or pipe bring the desired final dimensions, but this is not necessary is.

Compared to the prior art, calibration is known per se of the profile or pipe to specified external dimensions, which in the state of the Technology always takes place after the welding station, before the welding station Service. This enables that manufactured in a roll forming system Pipes and profiles in one conventional welding station closed profile or pipe can be welded. Because, like at the beginning addressed, the material of the sheet metal strip stretches when it is formed depending on the thickness of the metal strip in the circumferential direction, so that for the sections with a small wall thickness where the weld seam runs should, a crack remains open.

The roll forming system modified according to the invention for carrying out the The method described is accordingly characterized in that at least a pair of calibration rollers between the roll forming tools and the Welding station is arranged to enable the novel "intermediate calibration" conventional longitudinal welding.

In the context of the invention, it is not excluded that the Wall thickness of the metal strip used not only in the longitudinal direction, but additionally also varies along its cross section, so that the invention manufactured profiles and pipes in terms of material costs exactly for the respective application can be optimized.

The calibration rollers are preferably arranged in an unusual orientation. Usually a pipe or a closed profile runs during the final calibration after the welding station through the calibration rollers so that the The weld seam runs through one of the two calibration rollers. According to the present Invention this should not be the case; is particularly preferred rather an arrangement of the calibration rollers, in which the (according to the invention not yet available) weld seam in the edge area between the two Calibration rolls come to rest. In other words, the profile or tube should be like this through the calibration rollers that the connection level between the longitudinal center axis of the profile or tube and the center line between the Narrow sides of the metal strip differ from the plane of rotation of the calibration rollers is, preferably approximately at right angles to this. this has following advantages:

As the diameter of the roller becomes smaller, i.e. in the area of the groove base, the contact area between the calibration roller and the pipe is reduced or Profile, which increases the surface pressure. Now be a not yet welded Pipe or profile in a conventional arrangement using a pair of calibration rollers , the surface pressure is on the not yet welded belt edges particularly high, which leads to an elongation of the same. From this results however, there is a particular risk of the tube or profile buckling, in particular in the sections with thin walls and at the transition areas between a small and a thick wall. Likewise, yourself Waves form in the welding area, resulting in a poor welding result leads, and the pipe ends can spring open like a trumpet.

With the preferred, new arrangement of the calibration rollers, these effects prevented because the particularly high surface pressures no longer with the Band edges occur. Nevertheless, the calibration in the thin Sections of the pipe or profile existing gaps on the strip edges closed, so that a subsequent longitudinal welding no problems More force.

A sheet metal strip is preferably used, in which the sections differ Band thickness are put together so that the band centers of the different sections are adjacent to each other. The neutral fiber in Forming is then always in the middle of the material, which is the shear stress between the different sheet thicknesses advantageously minimized. By intermediate calibration the outer dimensions are equalized, so that the thickness jump then ultimately lies inside the tube or profile.

The sheet metal strip can be shaped using roll-forming tools that work together in pairs to form a roll gap, where the clear width of the roll gap corresponds to the strip thickness of the current section of the sheet metal strip located therein is varied. This can by changing the position of one of two working together in pairs Roll forming tools can be achieved, this preferably is moved perpendicular to the longitudinal direction of the sheet metal strip. Through this adjustment the roll gap at varying sheet thicknesses is avoided, that either the roll gap is too large for thin sections of the sheet metal strip, which would result in an undefined deformation of the band, or for thick sections of the band is too tight, which is caused by pressures on the one hand lead to poor production results and on the other hand the bearings of the Rollforming tools would endanger.

The positions for varying the roll gap are particularly preferably changed in position trained roll forming tools with a motor, hydraulic or pneumatic adjustment mechanism or they are spring-loaded variable in position so that it automatically adjusts to the thickness of the section of the sheet metal strip currently in it.

The movements of the rollforming tools which can be changed in storage can be correspondingly the course of the thickness of the sheet metal strip can be actively controlled, for example by means of a computer in which the thickness of the sheet metal strip is stored, while the production progress preferably over a path length measuring device is reported to the computer, or for example corresponding to that of a sensor unit for strip thickness measurement measured values; the movements of the rollforming tools that change their position can also be passive due to spring loading or for example by means of an overpressure limitation of a hydraulic adjustment mechanism can be achieved: The variable roll forming tool then gives against the Spring force or due to the overpressure limitation after the sheet metal strip thickened in the roll gap, while the roll gap then also automatically narrowed again when the intermediate strip thickness decreased. hereby can, even if the above-mentioned active control of the roll gap nevertheless can also be provided, the roll forming system of each sheet metal topography adjust automatically without the need for any Store data in the control system or install complex sensors.

Figur 1

eine schematische Darstellung eines Gestells mit Rollformwerkzeugen in erfindungsgemäßer Ausführung nebst schematischer Darstellung eines hydraulischen Verstellmechanismus;

Figur 2

eine schematische Darstellung eines durch Rollumformen hergestellten zylindrischen Rohrs mit drei Abschnitten unterschiedlicher Wanddicke;

Figur 3

eine schematische Darstellung eines Kalibrierrollenpaars mit durchlaufendem Rohr.

The invention is further explained by way of example with reference to the accompanying drawings. Show it:

Figure 1

a schematic representation of a frame with roll forming tools in the inventive design together with a schematic representation of a hydraulic adjustment mechanism;

Figure 2

a schematic representation of a cylindrical tube produced by roll forming with three sections of different wall thickness;

Figure 3

a schematic representation of a pair of calibration rollers with a continuous tube.

Figure 1 shows schematically the view of a frame 1, in which an upper Drive shaft 2 an upper roll forming tool 3 and on a lower drive shaft 4 a lower roll forming tool 5 are mounted. In that by interacting Roll forming tools 3, 5 formed nip 6 is an already partially profiled sheet metal strip 7 can be seen. A roll forming system according to the invention usually consists of a large number of such, one after the other arranged frames, the roll forming tools the respective forming step are adapted differently.

The peculiarity of the frame 1 shown is that the upper drive shaft 2 does not sit firmly on the frame 1, but is mounted at different heights is. For this purpose, two hydraulic cylinder units 8a and 8b are provided, which on the one hand on the frame 1 and on the other hand on the bearings 9a, 9b of the upper one Support drive shaft 2. These are double-acting hydraulic cylinders, with which a defined change in height of the upper drive shaft 2 and thus a defined setting of the roll gap 6 can be achieved.

The hydraulic connection of the hydraulic cylinders 8a, 8b is schematic in FIG. 1 shown. The hydraulic cylinders 8 are driven by a pump 10 a check valve 11 and a two-way valve 12 are supplied with hydraulic oil. The Two-way valve 12 enables the hydraulic cylinders 8 to be reversed the line A is pressurized, the upper drive shaft 2 adjusts itself up to an upper stop and thus to a maximum opening of the roll gap 6; is activated by actuating the two-way valve 12, as shown in FIG. 1, the line B is pressurized, the drive shaft 2 lowers to one lower stop, so that the roll gap 6 to its smallest extent closes. The two-way valve 12 thus enables in cooperation with the double-acting hydraulic cylinders 8 the active control described above of the roll gap 6, which is particularly sufficient if only two different sheet metal strip thicknesses can be processed.

In addition to the two-way valve 12, there is also one in the hydraulic circuit diagram of FIG To recognize pressure relief valve 13, which is actuated by a pressure measuring device 14 as soon as the hydraulic pressure in the hydraulic system Threshold exceeds. This simple measure enables the interaction automatic control with a suitably powerful pump 10 of the rolling pressure between the upper roll forming tool 3 and the lower one Roll forming tool 5 to a constant value, regardless of the Size of the roll gap 6 and thus regardless of the thickness of the metal strip 7. Because as soon as a thicker section of the sheet metal strip 7 gets into the roll gap 6, the rolling pressure increases and thus the pressure in line B. Now Pressure relief valve 13 opened, the upper roll forming tool 3 yields by the upper drive shaft 2 moves up until the hydraulic pressure in line B again below the threshold for actuation of the pressure relief valve 13 drops. The pump 10 then ensures that the hydraulic pressure does not drop further and thus the rolling pressure between the Rollforming tools 3 and 5 is maintained. If the other way around Sheet metal strip 7 becomes thinner in the roll gap 6, which is provided by the pump 10 hydraulic pressure in line B for the upper drive shaft 2 is immediately moved downward, so that the roll gap 6 between the upper roll forming tool 3 and the lower roll forming tool 5 accordingly closes.

The hydraulic adjustment mechanism shown in FIG. 1 thus combines active control of the roll gap opening by means of the two-way valve 12 with an automatic control of the rolling pressure by means of the pressure relief valve 13. In the case of abrupt changes in the thickness of the metal strip 7, it can be quite advantageous to change the roll gap 6 via an active reversal to carry out the two-way valve 12, if necessary also additionally for automatic rolling pressure control. Conversely, the pressure relief valve takes over 13 in active control mode regardless of the possibility of one Regulation of the rolling pressure a safety function against impermissible pressures in the hydraulic system.

Figure 2 shows schematically a roll forming from a sheet metal strip cylindrical tube 18 produced in three different thickness sections. A first section 15 has a thicker wall, so that the band edges to lie on the bump. A second section 15 'that merges with the first section 15 is welded in the middle, has a smaller wall thickness, which is why the Band edges do not lie on butt, but a gap remains, which is a simple Longitudinal welding to close the tube 18 makes it impossible. At the other A third section 15 ″ is welded onto the end of the second section 15 ′ again has the same wall thickness as the first section 15.

Figure 2 shows the situation before the calibration and Longitudinal welding to complete tube 18.

A calibration roller pair 16, 17 is shown schematically in FIG the tube 18 from Figure 2 is intercalibrated before welding. The butt edge 19, that is to say the subsequent weld seam, lies between in the edge region the two calibration rollers 16 and 17; the connection plane between the butt edge 19 and the longitudinal central axis of the tube 18 is perpendicular to the Plane of rotation of the two calibration rollers 16 and 17. As already described, there are the greatest surface pressures on the tube 18 in the plane of rotation two calibration rollers 16, 17, so here advantageously not in the area of Butt edge 19. On the contrary: Since the butt edge 19 is in the contact area of the two calibration rollers 16, 17, there is hardly any elongation of the To calculate pipe material, so that there is indeed the gap shown in Figure 2 closes, but no waviness or buckling of the material on the Butt edge 19 is to be feared. The subsequent longitudinal welding for completion the tube 18 can thus be done in a conventional manner. Possibly can of course also be a final calibration after the welding station be carried out in addition.

LIST OF REFERENCE NUMBERS

1

frame

2

Drive shaft (upper)

3

Roll forming tool (upper)

4

Lower drive shaft

5

Roll forming tool (lower)

6

nip

7

metal strip

8th

hydraulic cylinders

9

Stock (of 2)

10

pump

11

check valve

12

Two-way valve

13

Pressure relief valve

14

Pressure measuring device

15, 15 ', 15 "

Section (of 18)

16

calibrating

17

calibrating

18

pipe

19

impact edge

Claims (20)

Method for producing a closed metal profile or metal tube, the wall thickness of which varies along its longitudinal axis, with the following method steps: Forming a sheet metal strip with a strip thickness varying along its length using roll forming tools to form a profile or tube, Calibrate the profile or tube in at least one pair of calibration rollers to the specified external dimensions, Welding the narrow sides of the sheet metal strip lying against each other by forming and calibrating to complete a closed profile or tube. Method according to claim 1,
characterized in that the profile or tube is guided through the calibration rollers so that the connection plane between the longitudinal center axis of the profile or tube and the center line between the edges of the sheet metal strip is different from the plane of rotation of the calibration rollers. Method according to claim 2,
characterized in that the connection plane between the longitudinal center axis of the profile or tube and the center line between the edges of the sheet metal strip is placed approximately at right angles to the plane of rotation of the calibration rollers. Method according to one of claims 1 to 3,
characterized in that a sheet metal strip is used, in which the sections of different strip thickness are put together so that the strip centers of the different sections each lie against one another. Method according to one of claims 1 to 4,
characterized in that the forming of the sheet metal strip into a profile or tube is carried out by means of roll-forming tools, which cooperate in pairs and each form a roll gap, the clear width of which is varied according to the strip thickness of the section of the sheet metal strip currently located therein. Method according to claim 5,
characterized in that , due to the use of roll forming tools, in which at least one of two roll forming tools interacting in pairs, the roll gap is automatically adjusted to the thickness of the section of the sheet metal strip currently located therein, in a motorized, spring-loaded, hydraulic or pneumatic manner. Method according to claim 6,
characterized in that the variable roll forming tools are pneumatically or hydraulically preloaded and / or adjusted. Method according to claim 6,
characterized in that the movements of the variable-position roll forming tools are actively controlled in accordance with the course of the thickness of the sheet metal strip. A method according to claim 8,
characterized in that the movement is controlled by means of a computer in which the thickness profile of the sheet metal strip is stored, the progress of production being reported to the computer via a path length measuring device. Method according to one of claims 8 or 9,
characterized in that the movement of the positionally variable roll forming tools is controlled in accordance with the values measured by one or more sensor units for measuring the strip thickness. Roll forming system for carrying out the method according to claim 1,
with a plurality of roll forming tools (3, 5) for forming a sheet metal strip (7) into a metal profile or metal tube (18),
with a welding station for longitudinal welding of the formed sheet metal strip (7) to a closed metal profile or metal tube (18),
and with at least one pair of calibration rollers (16, 17) for calibrating the profile or tube (18) to predetermined external dimensions,
characterized in that the calibration rollers (16, 17) are arranged between the roll forming tools (3, 5) and the welding station. Roll forming system according to claim 11,
characterized in that the calibration rollers (16, 17) are arranged such that the connection plane between the longitudinal center axis of the profile or tube (18) and the center line between the edges (19) of the sheet metal strip (7) from the plane of rotation of the calibration rollers ( 16, 17) is different. Roll forming system according to claim 12,
characterized in that the connecting plane between the longitudinal center axis of the profile or tube (18) and the center line between the edges (19) of the sheet metal strip (7) is substantially perpendicular to the plane of rotation of the calibration rollers (16). Roll forming system according to one of claims 11 to 13,
characterized in that at least some of the roll-forming tools (5, 6) are arranged in pairs, so that they each form a roll gap (6) for simultaneous action on the sheet metal strip (7) guided by the roll-forming tools (3, 5), whereby each at least one of two roll forming tools (3) interacting in pairs for adapting the roll gap (6) to a varying thickness of the sheet metal strip (7) during the forming process is designed to be positionally variable relative to the respectively assigned roll forming tool (5). Roll forming system according to claim 14,
characterized in that the positionally variable roll-forming tools (3) are designed to be positionally spring-loaded. Roll forming system according to one of claims 14 or 15,
characterized in that the positionally variable roll forming tools (3) are provided with a motorized, hydraulic or pneumatic adjustment mechanism (8). Roll forming system according to claim 16,
characterized in that the adjusting mechanism (8) is provided with an overpressure limitation (13) for the rolling pressure. Roll forming system according to one of claims 16 or 17,
characterized in that the adjusting mechanism (8) is provided with a control for adjusting the roll gap (6) as a function of the varying thickness of the sheet metal strip (7). Roll forming system according to claim 18,
characterized in that the control comprises a memory in which the thickness profile of the sheet metal strip (7) is stored. Roll forming system according to claim 18,
characterized in that the control of the adjustment mechanism (8) is connected to a sensor unit for measuring the strip thickness.

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