EP0445899A1 - Method for manufacture of medium- and thinwalled seamless pipes and rolling device therefor - Google Patents

Abstract

The invention relates to a method for the manufacture of medium- and thin-walled seamless pipes from an elongate hollow body of limited length which is deformed by rollers to the desired finished dimensions. In order to specify a method for the manufacture of medium- and thin-walled seamless pipes (5) with a diameter/wall thickness ratio in the range from 15 : 1 to 50 : 1 by means of which it is possible to produce the desired finished dimensions while achieving good surface finish and remaining within the prescribed dimensional tolerances, starting from an elongate hollow body and with a minimum outlay on plant, it is proposed that the diameter of the hollow body be reduced to a significant extent in just one rolling pass and that the inner surface be smoothed using an internal tool (4) with only a slight change in the wall thickness and that the axis of the hollow body (14) should be in alignment with the rolling axis (14) during the rolling operation. <IMAGE>

Description

The invention relates to a method for producing medium and thin-walled seamless tubes according to the preamble of claim 1 and a rolling device for performing the method.

The need for seamless tubes in the diameter range 7 "(177.8 mm) to 26" (660 mm) with a diameter / wall thickness ratio in the range from 15: 1 to 50: 1 is extremely high. It should only be referred to the oil field pipe area, where mainly seamless pipes are used as drilling pipes, production pipes or casing pipes. The production of high-quality seamless tubes, ie with tight tolerances for wall thickness and diameter and a good surface, is relatively difficult and requires a corresponding outlay in terms of plant technology. This applies in particular to thin-walled pipes with a diameter / wall thickness ratio of greater than 25: 1. The rolling processes previously used to manufacture such seamless tubes are, on the one hand, the tamping rolling process and the pilger rolling process. Regarding the general plant design of the two rolling processes reference is made to the steel tube manual 10th edition, 1986, in particular pages 128 and 133.

A disadvantage of the plug rolling process is that the plug rolling mill has to be followed by two parallel smoothing mills (Reeler) and a sizing or reducing mill in order to equalize the wall thickness ridges resulting from longitudinal rolling and to achieve an acceptable roundness for performance reasons. In the last-mentioned rolling step, it is important that, by means of the reeling, it is possible to roll slightly on the enlarged front tube by a corresponding reduction in the diameter to the desired finished dimension. Since the decrease per stand in such a measuring mill is about 2 to 4%, the usual standardization of mother tubes requires a large number of stands to achieve the corresponding diameter decreases. However, many scaffolding places mean high investment costs and a corresponding inventory of rolling stands.

In the pilger rolling process, where the standardization of the mother pipes is usually dispensed with for cost reasons, the last forming step is only a calibration with a usual number of stands, but the surface quality, in particular the wall thickness tolerances of the piled pipe, no longer correspond to the increased ones in most cases Conditions.

The object of the invention is to provide a process for the production of medium and thin-walled seamless pipes with a diameter / wall thickness ratio in the range from 15: 1 to 50: 1, with which, starting from an elongated hollow body with the smallest possible system engineering outlay, the desired finished dimension for puter Surface quality and in compliance with the prescribed dimensional tolerances can be generated.

This object is achieved with the means specified in the characterizing part of claims 1 and 3. Refinements preferably result from the subclaims.

The main idea of the invention is to shape the elongated hollow body produced by various processes to the desired finished dimension by rolling in as little as possible with one roll pass, thereby significantly reducing the diameter and at the same time smoothing the inner surface using an inner tool. In practice, however, this ideal concept with only a single rolling unit can only be realized if the corresponding framework conditions are present, i. H. there must be a hollow body which is ideal as a starting material with regard to tolerances and surface quality, which is then rolled to a dimension which represents an optimum in terms of tolerances and roundness, so that a subsequent calibration can be dispensed with. Since the proposed rolling method is a combination of conventional smoothing (reeling) and diameter reduction, the rolling method according to the invention can also be referred to as reducing smoothing or reducing reel, which in principle can also be used for cold rolling.

Deviating from the ideal concept described above, one realistically has to assume that the reduction smoothing must be followed by a further rolling process. This rolling process is essentially a calibration in which, in addition to a rounding for the precise setting of the desired finished diameter, there is a slight reduction in diameter. But this variant of the method according to the invention also has great advantages over the conventional rolling methods. If you assume that, as already Rolling processes have great advantages. If one assumes that, as already mentioned, in a conventional dimensional reducing mill as the last stage, e.g. B. a plug rolling mill the diameter decrease per stand is about 2 to 4%, then with a diameter reduction of 20% during reduction smoothing, at least five stand positions together with the associated interchangeable stands would be saved. Another advantage can be seen in the fact that the degree of reduction can also be set in the case of reducing smoothing in such a way that the diameter decrease is almost zero or the incoming hollow body is widened as in conventional smoothing. This method is therefore very adaptable and can be used for the various requirements. The rolling method according to the invention is particularly advantageous when viewed in the rolling direction, the incoming hollow body is first reduced in diameter and the inner surface is smoothed immediately thereafter. This proposed sequence has the advantage that, depending on the utilization of the reducing part, it can both be reduced more or less and smoothed conventionally. In principle, one can also reverse the sequence without leaving the inventive idea, ie first smooth and then reduce. However, this has the disadvantage that there is no freedom in the degree of reduction and must always be smoothed and reduced at the same time.

In order to improve the quality of the inner surface, it is also proposed to continuously shift the inner tool in the longitudinal direction during the entire rolling process. This method has the advantage that during normal hot rolling, the scale that is formed cannot build up at a certain point and thus leads to malfunctions in the rolling process. Another variant is to move the inner tool only during a certain rolling phase. These specific rolling phases are preferably the rolling and rolling, which are particularly critical with regard to the distribution of forces in the roll gap and by which Moving the inner tool are supported.

The measure of shifting the inner tool when rolling on or off has the purpose of avoiding rolling or rolling plugs. If the process is limited to these phases, then during the remaining rolling time you have the condition of the stationary inner tool with the risk of scale build-up. If you want to avoid this, the inner tool must also be moved during the festive season. The design measures required for this are explained below.

The rolling device for carrying out the method is characterized in that, on the basis of a conventional smooth rolling mill with an internal tool, the run-in part of the rolls is designed as a reducing part with a reducing angle in the range from greater than 2 degrees to 10 degrees. The usual smoothing mills are designed in the inlet section either as a barrel or as a divergent cone with a reduction angle of up to approx. 2 degrees (Hutnicke listy 38 (1983) No. 11, pages 779 - 782). The inlet part of the roller according to the invention is followed by an almost cylindrical smoothing part with an arcuate transition with a difference angle to the working part of the inner tool of greater than 0 to less than 1.0 degree, which is then followed by the outlet part. The discharge part has the task of rounding the rolling stock. So that a reduction in diameter is possible in the reduction smoothing or reduction corrugation according to the invention, the rolling stock must additionally be supported by two guides lying opposite one another and the forming zone closed. The cylindrical or slightly conical working part of the inner tool extends axially over a larger area than the smoothing part of the rolls, the beginning of the working part of the inner tool lying in the rolling direction before the start of the smoothing part of the rolls. Due to the greater length of the working part of the inner tool compared to the smoothing part of the rollers, the inner tool does not need to be as precise be positioned. In addition, the wear of the inner tool is reduced, since by changing the position of the inner tool between two successive rolling periods, the load maximum is always in one place of the working part. With regard to a starting aid when the hollow body enters the rolling device according to the invention, it is further proposed to connect the reducing part with a drawing-in part with a drawing-in angle of approximately 1 degree. Particularly in the case of thin-walled tubes, an additional torque generated by the tapered pull-in part is desired, which helps to bring the high body to be rolled to the smoothing part without it getting stuck in the reducing part due to the ovality caused by the reduction. In the case of the method reversal that is possible in principle, that is to say only smoothing, when the end of the hollow body has left the smoothing part, no additional torque is available and end plugs can occur with thin-walled tubes. These end plugs can be avoided by providing a tapered rolling part on the inner tool, which, however, could not be moved against the rolling direction in order to avoid scale build-up during rolling.

As an alternative to the conventional internal tool, it is proposed to precede or follow a conical section before the cylindrical to slightly conical (divergent) working part. In the rolling or rolling phase, this section lies fully against the inner surface of the incoming hollow body. The angle of this section is almost equal to the reduction angle of the rollers. For the example of rolling on, the position of the inner tool is chosen so that the overlap from the rolling part to the working part of the inner tool lies in the same plane perpendicular to the rolling axis as the transition from the reducing part to the smoothing part of the rollers. After the beginning of the hollow body has exceeded this level and thus the hollow body is in full roll engagement, the inner tool is pushed against the rolling direction, so that the transition from the rolling part to the working part of the inner tool is in the area of the reducing part of the roller. The displacement of the inner tool against the rolling direction should be at least so great that there is no wall deformation by the inner tool in the reducing part.

In a further variant of the inner tool, the rolling part and the effective smoothing part of the inner tool do not follow one another directly. In between there is a section that does not perform any deformation tasks. This section is preferably designed as an extension of the smoothing part that is not effective in terms of deformation technology. This embodiment of the inner tool has the advantage that the exact match between the smoothing part of the roller and the smoothing part of the inner tool is not necessary. This gives you more leeway to set the position of the inner tool. Above all, differences in the circumferential material speed over the length, which cannot be avoided for every setting with the same working length in the reduction part of the roller and inner tool, are noticeably less noticeable. Put simply, this means that the risk of inadmissible torsion of the hollow body to be rolled around the longitudinal axis when reducing while in contact with the internal tool is significantly reduced.

The method according to the invention can be varied in such a way that the rollers of the roller device not only have the usual transport angle, but also an angle of spread against the roller axis. This variant is particularly advantageous if the point of intersection of the axes of the rolls with the roll axis lies behind the rolling mill, as viewed in the rolling direction, the transport angle being set to zero in the process. In this constellation, an optimum is achieved when the size of the spreading angle is chosen so that the circumferential speed of the rollers decreases in proportion to the decreasing hollow body diameter for the mean diameter of the given dimensional range in the reducing part. This results in zero slip and with a linear contact of roller and hollow body for the hollow body, the same angular velocity for each point on its axis. In other words, this preferably selected spreading angle optimizes the change in the circumferential speed of the roller over the length in such a way that the roller and the hollow body to be rolled, such as the gears of a gearbox, roll on one another, thereby twisting the rolling stock as little as possible about its longitudinal axis.

• beim Stopfenwalzverfahren nach dem Stopfengerüst als Ersatz der konventionellen Reeler
• beim Pilgerwalzverfahren nach dem Pilgergerüst als zusätzlicher Verfahrersschritt jedoch mit den genannten Vorteilen bezüglich der Oberfläche und der Toleranzen
• direkt nach einem Lochwalzwerk ohne weiteres Streckaggregat.

The following variants are preferred as possible uses for the method according to the invention:

• in the plug rolling process after the plug stand as a replacement for the conventional reeler
• in the pilger rolling process according to the pilger stand as an additional process step, however, with the advantages mentioned with regard to the surface and the tolerances
• directly after a piercing mill without further stretching unit.

In the drawing, the rolling device according to the invention and thus also the method are explained in more detail using several exemplary embodiments.

• Figur 1 einen hälftigen Längsquerschnitt durch die erfindungsgemäße Walzeinrichtung während des Walzprozesses
• Fig. 2a-c einen hälftigen Längsquerschnitt durch die Walzeinrichtung mit einem verschiebbaren Innenwerkzeug während verschiedener Walzphasen
• Figur 3 wie Figur 1 jedoch mit einer anderen Ausführungsform des Innenwerkzeuges

Show it:

• Figure 1 shows a half longitudinal cross section through the invention Rolling device during the rolling process
• 2a-c a half longitudinal cross section through the rolling device with a displaceable inner tool during different rolling phases
• Figure 3 as Figure 1 but with a different embodiment of the inner tool

1 shows the rolling device according to the invention during the rolling process in a half longitudinal cross section. The rolling device consists of two rollers 1, 2 driven in the same direction, which are inclined by a transport angle to the rolling axis. The second roller 2, as well as the guides, which are arranged in a plane rotated by 90 degrees to the roller plane, are not shown in this figure. In addition, the rolling device has an inner tool 4 fastened to a holding rod 3. The hollow body 5 to be rolled is fully engaged in the rolling in this illustration. The roller 1 according to the invention has various sections, which are explained in detail below. Seen in the rolling direction, which is indicated by the arrow 6, the roller 1 has at the beginning a feed part 7, which merges into the end face 8 of the roller 1 on the inlet side. In this exemplary embodiment, the retraction part 7 is of divergent conical design with a retraction angle of approximately 7 degrees. This feed part 7 serves as a starting aid and facilitates the rolling process. The pull-in part 7 is followed by a reducing part 9 with a reducing angle in the range from greater than 2 to 10 degrees. In this section, the diameter of the incoming hollow body 5 is significantly reduced. This is followed by an almost cylindrical smoothing part 11 with an arcuate transition 10. This smoothing part 11 closes with the working part 12 of the inner tool 4 a difference angle in the area from 0 to less than 1 degree. The length of the working part 12 of the inner tool is always greater than the length of the smoothing part 11 of the rollers 1, 2. The smoothing part 11 is followed by the already known outlet part 13, which has the task of rounding the outlet hollow body 5. As already mentioned, the guide is not shown, which in a known manner consists of two fixed guide rulers lying opposite one another in order to close the caliber. Not shown in this figure is the variant that the axes of the rollers 1, 2 have an angle of spread against the roller axis 14. In this variant, however, the position of the contour of the rollers 1, 2 with respect to the roller axis 14 would be retained.

Like FIG. 1, FIG. 2 shows a half longitudinal cross section through the rolling device, but with a displaceable inner tool during different rolling phases. The same reference marks are used for the same parts as in FIG. 1. The inner tool 15 shown in FIG. 2 in the partial images a - c has two different sections. As in the case of a conventional internal tool 4, the working part 12 is cylindrical, which, in contrast to FIG. 1, is preceded by a conical rolling part 16. The cone angle of this rolling part 16 is almost equal to the cone angle of the reducing part 9 of the roller 1. In the rolling phase according to partial image a), the inner tool 15 is adjusted relative to the roller 1 so that the transition from the working part 12 to the rolling part 16 of the inner tool 15 lies in the plane of the transition from the smoothing part 11 to the reducing part 9 of the roller 1. The rolling-on phase is ended according to sub-picture b) when the hollow body 5 reaches the transition plane described. Subsequently, according to partial image c), the inner tool 15 is advanced so far against the rolling direction 6 that the transition region of the inner tool 15 lies in the reducing part 9 of the roller and the incoming hollow body 5 on Anwalztpil 16 of the inner tool 15 no longer comes to rest.

A further exemplary embodiment of an inner tool 17 is shown in FIG. Here too, the same reference numerals are used for the same parts as in FIG. 1. In contrast to FIGS. 1 and 2, this inner tool 17 has a cylindrical working part 12 which is extended so far against the rolling direction that it is over half the length of the reducing part 9 of the roller 1 protrudes. This is followed by a radial jump with a conical rolling part 18, the cone angle of which is approximately the same as the cone angle of the reducing part 9 of the roller 1. This rolling part 18 extends in the longitudinal direction to the beginning of the reducing part 9 of the roller 1 or until the transition from reducing part 9 to feed part 7 of roller 1.

Claims (13)

Process for the production of medium and thin-walled seamless tubes starting from an elongated hollow body of limited length, which is formed to the desired finished dimension by rolling,
characterized by
that the diameter of the hollow body is significantly reduced with only one rolling pass and the inner surface is smoothed using only a small change in wall thickness using an inner tool and the axis of the hollow body is aligned with the rolling axis during rolling. Process for the production of medium and thin-walled seamless tubes starting from a heated elongated hollow body, which is formed by two successive different rolling processes to the desired finished dimension and then cooled, the reheated hollow body possibly being reheated between the two rolling processes,
characterized by
that the diameter of the hollow body is significantly reduced in the first rolling process with only one pass and the inner surface is smoothed with only a slight change in wall thickness using an inner tool, the axis of the hollow block being aligned with the rolling axis during rolling and the second rolling process being essentially a calibration. Method according to claim 1 or 2,
characterized by
that the incoming hollow body is first reduced in diameter in the rolling direction and immediately afterwards the smoothing of the Inner surface is done. Method according to claim 1 or 2,
characterized in
that the inner tool is continuously shifted in the longitudinal direction during the entire rolling process. Method according to claim 4,
characterized in
that the inner tool is shifted during a certain rolling phase. Rolling device for carrying out the method according to claim 1 or 2 in the form of an inclined rolling mill with two co-driven rollers having an inlet and an outlet part, which are inclined by a transport angle to the rolling axis, and in a guide arranged at a plane rotated by 90 degrees to the rolling plane and an inner tool fastened to a holding rod and having a working part,
characterized by
that, seen in the rolling direction (6), the inlet part of the rollers (1) is designed as a reducing part (9) with a reducing angle in the range from greater than 2 degrees to 10 degrees, and an almost cylindrical smoothing part (11) is attached to it with an arcuate transition (10) with a difference angle to the working part (12) of the inner tool (4, 15, 17) in the range from 0 degrees to less than 1.0 degree, which is then followed by the outlet part (13) for rounding and the guide has two opposite fixed guide rulers and the working part (12) of the inner tool (4, 15, 17) has a greater length than the smoothing part (11) of the rollers (1), the beginning of the working part (12) seen in the rolling direction (6) of the inner tool (4, 15, 17) before the start of the smoothing part (11) of the rollers (1). Rolling device according to claim 6,
characterized in
that the reduction angle in the reduction part (9) of the rollers (1) is 3-5 degrees. Rolling device according to claim 6,
characterized in
that seen in the rolling direction (6), the reducing part (9) is preceded by a pull-in part (7) with a pull-in angle of approximately 1 degree. Rolling device according to claim 6,
characterized in
that the axes of the rollers (1) have an angle of spread against the roller axis. Rolling device according to claim 9,
characterized in
that the point of intersection of the axes of the rolls (1) with the rolling axis in the rolling direction (6) is behind the rolling mill, the transport angle being set to zero in the process. Rolling device according to claim 10,
characterized in
that the size of the spreading angle is chosen so that the circumferential speed of the rollers (1) decreases in proportion to the decreasing hollow body diameter for the mean diameter of the given dimensional range in the reducing part (9). Rolling device according to claim 6, in particular for carrying out the method according to claim 5,
characterized in
that the inner tool (15) in addition to the cylindrical working part (12) has an adjoining conical section (16) which only abuts the inner surface of the hollow body (5) to be rolled during rolling or rolling and whose cone angle is almost the same the reduction angle of the rollers (1). Rolling device according to claim 12
characterized in
that the working part (12) of the inner tool (17) for smoothing has a continuation counter to the rolling direction (6), the continuation extending over half the length of the reducing part (9) of the roller (1) and being rounded with a rounded part Paragraph is followed by a converging tapered rolling part (18) which bears against the inner surface of the incoming hollow block (5) during rolling and whose cone angle is almost the same as the reducing angle and which extends into the initial region of the reducing part (9).

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