EP0049798A2 - Rolling mill - Google Patents

Abstract

In the case of a rolling mill 1, the shape of the roll gap 8 is to be influenced practically exclusively by axial displacement of the rolls 3, 4 provided with a curved contour, and the edge pressure of the rolled strip 9 is to be reduced without any particular effort. For this purpose, the curved contour extends over the entire bale length of both rollers 3, 4 and has a shape in which the two bale contours complement each other only in a certain relative axial position of these rollers 3, 4 (FIG. 1).

Description

The invention relates to a rolling mill with work rolls, which are optionally supported on back-up rolls and / or intermediate rolls, the work rolls and / or back-up rolls and / or intermediate rolls being axially displaceable relative to one another and each roll having at least one of these pairs of rolls running towards a bale end , curved contour is provided, which extends on the two rollers in each case on opposite sides over part of the width of the rolling stock.

Rolling mills of this type are already part of the prior art due to US Pat. No. 2,776,586 and DE-OS 2 919 105. They are so designed that in the rolling operation by the axial displacement of the curved contour having rollers and a DC zeiti ^g for acting brought bending stress, the shape of the roll gap and the profile of the rolled strip can werdn affected on it.

A disadvantage of such a known rolling mill is that, in addition to the device for the axial displacement, additional rolls bending devices must be assigned to the rolls having a curved contour over part of their bale length. On the one hand, roll bending devices are required in order to be able to bend the ends of the rolls provided with the curved contour away from the roll gap or from the roll strip (positive bending), and on the other hand there are also roll bending. Devices necessary that the bending of the ends of the rollers provided with the curved contour against the roll gap or the rolled strip guarantees (negative bending). In one case this reduces the rolling pressure on the strip edges, while in the other case an increase in the rolling pressure in the area of the strip edges can be achieved.

A change in the roll gap contour is only possible to a limited extent in the known rolling mill without roll bending devices and only in the sense of a concave strip shape.

It is obvious that a rolling mill designed in this way not only requires a high level of investment in the plant, but also that the correct setting of the roll gap or rolled strip contour is difficult because the axial adjustment of the rollers having the curved contour and their bending deformation are coordinated with one another have to

Moreover, it turns out to be disadvantageous in the case of the known type of scaffolding that, even with a positive work roll bend, the strip edge pressure is still relatively high.

The present invention aims to eliminate this after. parts. It is therefore the goal of her to create a rolling mill of the type ^q in which the shape of the roll gap and thus the rolled strip ^q influence practically exclusively through the axial displacement of the rollers provided with the curved contour and reduce the strip edge pressure without effort leaves.

The solution to these problems can be realized in a simple manner in that the curved contour extends over the entire bale length of both rollers and has a shape in which the two bale contours complement each other only in a certain relative axial position of these rollers.

It is particularly advantageous that the measures according to the present invention can also be implemented in duo rolling mills, that is, they are not limited to rolling mills with supporting and / or intermediate rolls, as is the case in DE-OS 2 919 105.

Furthermore, the advantage has been shown that the shape of the roll gap and thus the cross-sectional shape of the rolled strip can be influenced even by small displacement paths of the rollers having the curved contour and that no direct adjustment of the position of the movable rollers to the width of the rolling stock has to take place, as is the case for example is the case with another known rolling mill according to DE-AS 2 260 256.

The effective crowning of the roller set to the rolling force and the width of the rolling stock can be set quickly and specifically due to the small displacement paths, whereby rectangular, concave and convex rolling stock cross-sections can be achieved depending on the displacement direction and degree. A particularly simple construction of a rolling mill according to the invention can be achieved by the features of claim 2. The design of the rollers specified in claim 3 has proven particularly useful.

On the other hand, it is also possible according to the invention to equip a rolling mill with rolls which have the features specified in claims 4, 5 and 6.

A particularly simple construction of a rolling mill according to the invention, by use of the features specified in claim 7 ISIN zeichnun ^g sFeatures achieved. Irrespective of or simultaneously with this configuration, the features of claim 8 can also be used in practice.

The shape of the roll gap and thus the roll strip cross section can also be influenced by the measures that are shown in claims 9 and 10.

It is advantageous in a rolling mill according to the invention that the shape of the rollers having the curved contour can be freely selected so that the effective crowning can be adapted to the respective requirements. The axial displacement of these rollers can, if necessary, be carried out in the same or in opposite directions. The axial displacement paths of the two rollers can be the same or different.

Finally, it is also no problem at all to use the inventive design of a rolling mill in cooperation with conventional methods of influencing the strip profile, for example to work with strip thickness and inclined position adjustment and also with thermal measures.

Although the invention shows a way to change the roll gap contour within wide limits without using a roll bend, it is nevertheless not excluded to implement the invention on a roll mill with roll bending devices.

• Fiqur 1 in Walzrichtung gesehen ein Duo-Walzwerk nach der Erfindung,
• Figur 2 eine der Fi^g. 1 entsprechende Darstellung eines Quarto-Walzwerks,
• Figur 3 ebenfalls in Walzrichtung gesehen ein erfindungsgemäßes Sexto-Walzwerk,
• Figur 4 eine bevorzuqte Ausführungsform für die Walzenkontur bei einem erfindungsgemäßen Walzwerk,
• Figur 5 eine mögliche Einstellung des Walzenpaares nach Fig. 4 für einensich nach den Bandkanten hin verengenden Walzspalt,
• Figur 6 eine Einstellung des Walzenpaares nach Fig. 4 für einen sich nach den Bandkanten hin erweiternden Walzspalt und
• Figur 7 eine andere mögliche Konturgestaltung für ein Walzenpaar eines erfindungsgemäßen Walzwerks.

Further features and advantages of rolling mills according to the invention are explained in detail below using exemplary embodiments shown in the drawing. Show here

• Fig. 1 seen in the rolling direction a duo rolling mill according to the invention,
• Figure 2 shows one of the Fi ^g. 1 corresponding representation of a four-high rolling mill,
• FIG. 3, also seen in the rolling direction, a six-high rolling mill according to the invention,
• FIG. 4 shows a preferred embodiment for the roll contour in a rolling mill according to the invention,
• FIG. 5 shows a possible adjustment of the pair of rollers according to FIG. 4 for a roll gap narrowing towards the strip edges,
• 6 shows an adjustment of the pair of rollers according to FIG. 4 for a roll gap widening towards the strip edges and
• 7 shows another possible contour design for a pair of rolls of a rolling mill according to the invention.

In Fig. 1, a duo-roll mill 1 is shown, in the roll stands 2 of which a pair of work rolls 3, 4 are each guided by means of chocks 5, 6. Using conventional adjusting devices 7, the work rolls ^p aar 3, 4 can be set against the rolling strip 9 running through the roll gap 8.

Both work rolls of the pair of work rolls 3, 4 are mounted axially displaceably in the chocks 5, 6 via their pins 10, 11, the devices for axial adjustment each engaging one of the roll pins 10 and 11, respectively.

From Fi ^g . 1 shows that the roll bales 12 of both work rolls 3 and 4 of the work roll pair 3, 4 have a curved contour over their entire length, for example of such a type that this contour in the case of the upper work roll 3 over the left half of the Roll bale 12 is convex and concave over the right half thereof, while in the lower work roll 4 it is concave over the left half of the roll bale 12 and convex over the right half of the same. Both sections of the rolled bales 12 are determined by the same curvature curves.

From Fig. 1, is readily apparent that both work rolls 3 and 4 of the working roll pair 3, 4 of identical - having the form of the roll barrel 12 and 1 relative to each other are provided around 180 ⁰ turned-over installation position in the roll stand of the Duowalzwerkes - bottle-like here.

In Fig. 1, the average axial setting of both work rolls 3 and 4 of the work roll pair 3, 4 is shown, and it can be seen that with this axial setting the roll gap 8 at least over the width of the roll belt 9, but preferably over the entire bale length, a constant Cross-sectional height, although it runs slightly S-shaped.

2 shows a four-high rolling mill 21 according to the invention, in which the two backup rolls 23 and 24 of a pair of backup rolls 23, 24 are guided in the roll stands 22 via chocks 25, 26.

Between the support roller pair 23, 24, as is usual in a four-high rolling mill, a pair of work rollers 23 ', 24' is provided, which delimits the roll gap 28 for the rolled strip 29. The adjustment of the work rolls 23 'and 24' to determine the height of the roll gap 28 is carried out by adjusting devices 27 which act on the chocks 25 and 26 of the support rolls 23 and 24.

In the four-high rolling mill 21 according to FIG. 2, both support rollers 23 and 24 of the support roller pair 23, 24 are held axially displaceably in the chocks 25 and 26 via their roller journals 30 and 31, respectively, with the devices not shown on each of the roller journals 30 and 31 attack for axial adjustment.

From Fig. 2 it can be seen that in the four-high rolling mill 21, the roll bales 32 of the two support rolls 23 and 24 have the curved contour over their entire length, in the same way as the work rolls 3 and 4 in the work roll pair 3, 4 of the duo rolling mill 1 after Fig. 1. The left half of the roll barrel 32 of the upper support roller 23 thus has the corvex curved contour, while the right half of the same is provided with the concave curved contour. Conversely, points the left half of the roll barrel 32 of the lower support roller 24 has the concavely curved contour and the right half of the same has the convexly curved contour. Here, too, both bale sections are determined by the same curvature curves.

It can also be seen from FIG. 2 that the roll bales of the work rolls 23 'and 24' are cylindrical in themselves, but are given a slightly S-shaped bend due to the interaction with the support rolls, so that also the roll gap 28, which the roll band 29 passes through, receives a correspondingly slightly S-shaped cross-sectional shape.

3 shows a six-high rolling mill 41 in which in the roll stands 42 the two support rolls 43 and 44 of the support roll pair 43, 44 and the two work rolls 43 'and 44' of the work roll pair 43 ', - 44' have two intermediate rolls 43 on the outside "and 44" of an intermediate roller pair 43 ", 44" are arranged. The support rollers 43 and 44 of the support roller pair 43, 44 are guided by chocks 45 and 46 in the roller stands 42, while the intermediate rollers 43 "and 44" of the intermediate roller pair 43 ", 44" in turn are stored in insert pieces 45 "and 46", respectively be guided in the chocks 45 and 46 for the support rollers 43 and 44.

In the six-high rolling mill 41, only the intermediate rolls 43 "and 44" are arranged axially displaceably, while the support rolls 43 and 44 of the support roll pair 43, 44 and the work rolls 43 'and 44' of the work roll pair 43 ', 44' are immovably mounted. For this purpose, corresponding adjusting devices (not shown) act on a roll neck of the intermediate rolls 43 ″ and 44 ″.

Both the support rollers 43 and 44 of the support roller pair 43, 44 and the work rollers 43 ', 44' of the work roller pair 43 ', 44 'have cylindrical rolled bales. On the other hand, the intermediate rolls 43 "and 44" of the pair of intermediate rolls 43 ", 44" are equipped with roll bales which have a curved contour over the entire length of the bale. The bale contour of the intermediate rolls 43 "and 44" can basically correspond to that of the two work rolls 3 and 4 of the duo rolling mill 1 according to FIG. 1 or that of the backup rolls 23 and 24 of the four-high rolling mill 21 according to FIG. 2. However, it can be limited by curvature curves with larger radii, because the intermediate rolls 43 "and 44" are supported on the cylindrical roll balls of the support rolls 43 and 44, respectively. As a result, the intermediate rolls 43 ″ and 44 ″ are subjected to a deformation, which results in a greater curvature of the bale contour in the direction of the work rolls 43 ′ and 44 ′. With the help of the intermediate rolls 43 "and 44", a slightly S-shaped curvature is then forced onto the cylindrical roll bales of the work rolls 43 'and 44', which in turn determines the shape of the roll gap 48 for the rolled strip 49.

1, the shape of the roll gap 8 is determined directly by axial displacement of one or both work rolls 3 and 4. In the four-high rolling mill 21 according to FIG. 2, however, a corresponding axial displacement of one or both support rolls 23 and 24 takes place to change the shape of the roll gap 28. In the six-high rolling mill 41 according to FIG. 3, the shape of the roll gap 48 is finally influenced solely by axial displacement of one or both intermediate rolls 43 "and 44".

The operation of a rolling mill according to the invention will now be explained with reference to FIGS. 4-6, regardless of whether it is a duo rolling mill 1 according to FIG. 1, a four-high rolling mill 21 according to FIG. 2 or a sexto rolling mill 41 according to FIG. 3 . It only matters for the mode of action to the pair of rollers which has a curved contour over the entire length of the bale, in such a way that the two bale contours complement each other only in a certain relative axial position of the rollers.

For the sake of simplicity, it should be assumed in connection with FIGS. 4 to 6 that the curved bale contour is open ^! pointing pair of rolls is the work rolls 3 and 4 of the duo rolling mill 1 according to FIG. 1.

FIG. 4 shows the mean axial sliding position for both rollers 3 and 4 of the pair of rollers 3, 4, which corresponds to that of FIG. 1. Here, the roll gap 8 between the two rolls 3 and 4 has a constant height over the entire length of the bale, so that the roll strip 9 is rolled out over its entire width with a uniform thickness, although the roll gap 8 has a slightly S-shaped curve.

4, the height of the roll gap 8 between the two curved contoured bales 12 of the work rolls 3 and 4 results as

If one or both of the rolls 3 and 4 are moved in the axial direction by the amounts v and v ₂ (FIG. 6), then the shape of the roll gap 8 changes accordingly

It is therefore possible to continuously influence the shape of the roll gap 8 in such a way that, for example, the rolling pressure on the longitudinal edges of the rolled strip 9 is increased when the setting shown in FIG. 5 is made. On the other hand, the setting of the two rolls 3 and 4 according to FIG. 6 results in a reduction in the rolling pressure on the longitudinal edges of the rolled strip 9.

The particular advantage of the configuration of the roller set 3, 4 shown in FIGS. 4 to 6 is that both rollers 3 and 4 are designed completely identically and their shape can be freely selected so that the effective crowning optimally suits the respective requirements can be adjusted.

The axial displacement of the two rollers 3 and 4 of the pair of rollers 3, 4 can take place in the same direction or in opposite directions, as required, and the axial displacement paths can also be the same or different.

The simplest way is to determine the contour curved over the entire bale length on the rollers 3 and 4 mechanically, in particular by grinding. However, it is also possible to support the curved contour by thermally influencing the roll bale, namely by partial heating or cooling thereof. The shape of the roll gap 8 can of course also be influenced by the fact that the axes of the cooperating pair of rolls 3, 4 are installed with respect to one another in the roll plane. An additional influence on the shape of the roll gap 8 can also be achieved if the axes of the cooperating pair of rolls are set inclined to one another transversely to the roll plane. It is essential, however, that the shape of the roll gap 8 can be determined mainly by axial displacement of the two rolls of the pair of rolls, the roll bales of which have the curved contour over their entire length.

Fig. 7 is intended to illustrate that the invention is not fundamentally limited to the bottle-like curved contour of the rolled bales shown in Figs. 4 to 6, in which the course of curvature is convex over one half of the bale and concave over the other half of the bale, but also it is possible to use a pair of rollers 3, 4, in which the bales of both rollers 3 and 4 have different shapes, but also here in such a way that the two bale contours complement each other only in a certain relative axial position of the rollers 3 and 4.

It is possible, for example, deviating from FIGS. 4 to 6, that the roll bale 12 'of one roll 3 is convex-concave-convex in multiple alternation and the roll bale 12 "of the other roll 4 is accordingly concave-convex-concave 7, it is also quite conceivable to contour the roll bale 12 of one roll 3 convexly over its entire length and the roll bale 12 of the other roll 4 concavely over its entire length.

The procedure according to the invention for determining the shape of the roll gap has the considerable advantage that it can be used in two- and multi-roll stands as well as in cold and hot rolling. Furthermore, the application possibilities are just as good for one-way scaffolding and reversing scaffolding as for tandem and reversing lines.

Claims (10)

1. Rolling mill with work rolls, which are optionally supported on support rolls and / or intermediate rolls, the work rolls and / or support rolls and / or intermediate rolls being axially displaceable relative to one another and each roll of at least one of these roll pairs with a curved one running towards a bale end Contour is provided, which extends on the two rollers on opposite sides over part of the width of the rolling stock,
characterized ,
that the curved contour extends over the entire bale length of both rollers (3, 4 or 23, 24 or 43 ", 44") and has a shape in which the two bale contours are only in a certain relative axial position (e.g. Fi ^g . 4) of these rollers (3, 4 or 23, 24 or 43 ", 44") complement each other. 2. Rolling mill according to claim 1,
characterized,
that both rollers (3 and 4; 23 and 24; 43 "and 44") of the pair of rollers (3, 4; 23, 24; 43 ", 44") have identical shapes and are arranged so that they are turned by 180 ° in relation to one another ( Fiq. 1, 2 and 3). 3. Rolling mill according to claim 1 or 2,
characterized,
that the rolled bales (12, 23 ', 24', 43 ', 44' or 32, 43, 44 or 43 ", 44") over one half of the bale length one have a convexly curved contour and a concavely curved contour over the other half of the bale length and both bale sections are determined by the same curvature curves (FIGS. 4 to 6). 4. Rolling mill according to claim 1,
characterized,
that both rollers of the pair of rollers have different shapes (12 ', 12 "; Fig. 7). 5. Rolling mill according to claim 1 or 4,
characterized,
that the roller bale (12 ') of one roller (3) is convexly curved over its entire length and the roller bale (12 ") of the other roller (4) is concavely curved over its entire length. 6. Rolling mill according to claim 1 or 4,
characterized,
that the roller bale (12 ') of one roller (3) is contoured convex-concave-convex in multiple alternation and the roller bale (12 ") of the other roller (4) is accordingly concave-concave-convex-concave contoured (FIG. 7). 7. Rolling mill according to at least one of claims 1 to 6, characterized in
that the contour of the rolled bales (12; 12 ', 12 "; 32) is determined mechanically, for example by profile grinding. 8. Rolling mill according to at least one of claims 1 to 7, characterized in that
that the contour of the rolled bales (12; 12 ', 12 "; 32) is influenced thermally, for example by heating and / or cooling. 9. Rolling mill according to at least one of claims 1 to 8, characterized in that
that the axes of the roller gap (8; 28; 48) determining the roller pair (3, 4; 23 ', 24'; 43 ', 44') can be pivoted against each other in the roller plane. 10. Rolling mill according to at least one of claims 1 to 9, characterized in
that the axes of the rollers of the pair of rollers (3, 4; 23, 24; 43 ", 44") having the curved bale contour can be inclined relative to one another transversely to the roller plane.

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