WO1980000133A1

WO1980000133A1 - Method and installation for manufacturing multilayer pipes

Info

Publication number: WO1980000133A1
Application number: PCT/DE1979/000067
Authority: WO
Inventors: H Dietzel; W Mueffke
Original assignee: Mecano Bundy Gmbh; H Dietzel; W Mueffke
Priority date: 1978-06-28
Filing date: 1979-06-27
Publication date: 1980-02-07
Also published as: GB2039808B; DE2828960A1; IT7923924A0; IT1165124B; DE2828960C2; EP0016099A1; GB2039808A; JPS55500689A

Abstract

According to a known method for manufacturing such pipes which are used particularly as brake lines in motor vehicles, a steel strip provided with a copper coating is wound transversally and in a continuous manner so as to obtain an endless multilayer pipe which is then submitted to a heat treatment. According to this continuous heat treatment, the cold pipe is brought and kept at 1370 K. The copper coating melts and the different layers of the pipe are welded together. The quality of the pipe then obtained depends on several conditions which are difficult to satisfy; for example, this method requires a high mastery of the technic of production, perfectly adjusted machines and a steel strip with small thickness tolerances so as to avoid considerable manufacturing difficulties. In order to avoid too much production waste, the heat treatment of the multilayer pipe is carried out in two steps. Immediately after the formation of the pipe and combined with the first heating step, a final annealing temperature of 1200 K in order to eliminate the stress and to obtain the welding during the second heating step.

Description

METHOD AND SYSTEM FOR THE PRODUCTION OF MULTIPLE PIPES

The invention relates to a method and a plant for the production of multilayer pipes, wherein a steel strip provided with a copper coating is formed into an endless multilayer pipe body by continuously advancing rolling transversely to the strip length axis and the pipe body is subjected to a continuous heat treatment in which the initially cold pipe body is heated to around 1370 K is heated and temporarily held at this soldering temperature, the layers of the tube body being soldered to one another by melting the copper coating.

Such a method is known from DE-PS 75 11 70, and according to it, multilayer pipes, so-called "bundy" pipes, have been produced for a long time, which are used in particular in the motor vehicle industry as brake line pipes.

The process requires a great deal of technical skill, carefully adjusted and coordinated machines, as well as a metal strip with a narrow tolerance. Deviations in the strip thickness can lead to considerable malfunctions because when the strip is rolled in, an internal mandrel with a small caliber gap must be used.

In practice, the strip edges are first beveled by rolling in the production of multi-layer tubes. Then, in a first set of form rolls, a narrow strip is approximately lowered in the area of the later outer seam edge right-angled to serve as a stop and abutment for the curl that then begins from the other side of the belt. This bend is then removed in the last deformation process. This chamfering and the elimination of the chamfer lead to increased tensions in the chamfer area. So it is necessary to subject the newly formed tubular body to cold deformation in a corresponding set of rollers, also to give it a certain degree of stability. This cold deformation brings about a certain strain hardening and stabilization of the shape of the tubular body, so that the tubular body can be subdivided into individual lengths, the individual lengths can be collected and finally fed together in lots to a continuous furnace in which the individual layers are soldered.

The instability of the as yet unsoldered multi-layer tube, its sensitivity to mechanical influences and the difficulty in keeping the individual layers even closer together in individual lengths after soldering, limit the upper diameter of such tubes to approximately 12 mm. This relatively small diameter and the steel strips used with a thickness of about 0.35 mm in turn lead to the high influences, even in their absolute extent, small deviations from the strip material and equipment. It is also to be expected that strips of different production batches have different qualities, differ in the initial hardness and thus bring different springback into the tubular body. Even with slight differences in the starting strip thickness, the inner mandrel must be replaced today, via which the counterforce for the longitudinal expansion must be applied. Even the accuracy of the steel strip or copper-plated steel strip is a factor, as is the amount of oil carried along from the lubrication of the dome.

The object of the invention is to reduce the waste resulting from the aforementioned influences in the production of the Mehrla to reduce pipes, ie to improve the yield and to make the manufacturing process less sensitive.

According to the invention, it is therefore proposed to proceed according to the measures laid down in claim 1 in the manufacture of multilayer pipes.

Reference is made to configurations of the method according to the invention in accordance with subclaims 2 to 6.

It is suitable for practicing the method according to the invention. a system according to claim 7, which can be designed according to claims 8 and 9. Reference is made to the further subclaim 10.

The continuous production according to the invention ensures that the stable end. Strain hardening can be dispensed with. When rolling in, it is no longer necessary to pull over the mandrel as much. The number of mandrel changes is significantly reduced, the mandrel diameters can be stepped up and it is now easier to run tapes from different lots, even if they differ slightly in thickness, hardness and roughness.

If the method is used according to claim 2, there is at the same time a surprising advantage from the fact that faults can be identified even when the induction coil and the tube passing through it are observed. Manufacturing errors then lead to overheating of the outer layer and are thus so immediately recognizable that countermeasures can be taken immediately. The setting is made so much easier. Constant brightness means a perfect tube, which does not need to be confirmed by the subsequent quality control. So far, the first quality control results were only available when 3,000 m of pipe as a finished pipe had left the plant. If it is It was not a question of sporadic defects, but an incorrect setting of the machine, so this entire production of 3,000 m had to be sent to the scrap.

The invention is described below with reference to the figures. Each shows in a schematic representation:

1 is a plant for the production of multi-layer tubes,

2 shows a section through a wound tubular body,

Fig. 3 shows a plant for the production of multilayer pipes with a downstream stretch-reducing mill.

The plant shown in FIG. 1 for producing a multilayer pipe 2 from a metal strip 1 provided with a copper lining essentially consists of a strip store 3, a rolling device 4, a heating device 5, a heating device 6 and a cooling device 7. Behind the cooling device 7 is a Control device 8 and a device 10 are provided for winding the finished pipe. The prefabricated pipe can also be disassembled into individual lengths via a separating device 9. The separating device 9 is also used for cutting out pipe sections, which the control device 8 has recognized as deviating from a set standard.

The rolling device 4 consists of several roller sets 41, 42, 43, 4445, 46, which gradually form the steel strip 1 into a tubular body 12. The heating device 5 contains roller conductors 51 and 52 which are connected to a transformer 53. A further transformer 62 or a high-frequency generator is seen in the heating device 6, which feeds an induction coil 61. The heating device includes a diffusion annealing furnace 63 which holds the temperature reached via the induction coil 61 for a while. If necessary, work is carried out under protective gas. The system is operated as follows:

The steel strip 1 is fed from the strip storage device 3 to the rolling device 4, in which the roll sets 41 and 46 are used to form it into a multi-layer tubular body. At the end of the shaping, the tubular body 12 has approximately the shape shown in FIG. 2 with an inner layer 13 and an outer layer 14. The inner layer 13 ends with a beveled edge 15, the outer layer 14 with a beveled edge 16. The beveled Edges 15 and 16 overlap. In addition to the bevelled edge, there is point 17 in the cross section, which has undergone the alternating deformation by bending and bending back this area. In the heating device 5, the tubular body 12 is heated to a temperature of about 1200 K and thus annealed without stress. If the stress-relieved annealed tubular body were to be allowed to cool down again and disassembled into individual lengths, the shape of the tubular body would have been considerably stabilized and it would have been considerably more resistant to external mechanical influences. The system shown, however, shows that the tubular body 12 is now fed to a heating device in one pass, with induction heating to approximately 1370 K. This temperature can be maintained with a suitable arrangement and shielding until it enters the diffusion annealing furnace 63, until after the soldering has been carried out the finished tube runs into a cooling section 7 and is checked after leaving it.

In the schematic system according to FIG. 3, a device 18 for forming a pipe loop and a stretch-reducing mill are connected downstream. If there is little space available for the diffusion annealing furnace 63 from Baluich conditions, which would have to be much longer in continuous operation per se than the batch-wise fed diffusion annealing furnaces used so far, the resulting reduction in production speed can thereby be largely compensated for. Now a multi-layer pipe larger diameter than can be produced in the known systems, the desired final diameter can be generated via the stretch-reducing mill.

Claims

1.Method for the production of multilayer pipes, wherein a steel strip provided with a copper lining is formed into an endless multilayered tubular body by continuously progressively rolling in transversely to the strip length axis, and the tubular body is subjected to a continuous heat treatment in which the initially cold tubular body is heated to approximately 1370 K and temporarily heated up this soldering temperature is maintained, the layers of the tubular body being soldered to one another by melting the copper lining, characterized in that the heat treatment of the multilayer tubular body is carried out in two stages, the first heating stage immediately following the shaping of the tubular body and in one go with the same is operated with a final temperature of approximately 1200 K suitable for stress relief annealing and the soldering is carried out in the second heating stage.

2. The method according to claim 1, characterized in that the heat treatment of the first heating stage is carried out by resistance heating, the electrical current being supplied conductively to the tubular body.

3. The method according to any one of claims 1 and 2, characterized in that the heat treatment of the second heating stage is carried out by resistance heating, the electrical current being fed inductively to the tubular body.

4. The method according to any one of claims 1 to 3, characterized ge indicates that the endless tubular body passes through the second heating stage immediately after the first heating stage at the feed rate of the rolling process.

5. The method according to any one of claims 1 to 4, characterized in that the heat treatment is started shortly before the shaping of the tubular body is completed and the end temperature associated with the first heating stage is reached with the completion of the tubular body.

6. System for performing the method according to one of claims 1 to 5 with a Einrollvprrichtung, which contains several sets of rollers and a mandrel and a heating device for heating the tubular body to about 1370 K, characterized in that one in front of the heating device (6) Production line of the curling device (4) lying heating device (5) is arranged.

7. Plant according to claim 6 for carrying out the method according to claim 5, characterized in that for the conductive heating of the almost finished tubular body, the two last roller sets used to form the tubular body are constructed as conductors and are connected to an HF generator.

8. Plant according to one of claims 6 and 7, characterized in that the heating device (6) consists of an induction coil (61) connected to an HF generator (62) and a diffusion annealing furnace connected downstream thereof.

9. Plant according to one of claims 6 to 8, characterized in that a stretch-reducing mill is connected downstream.