KR101068460B1 - Method and device for producing a metal strip by continuous casting - Google Patents

Abstract

The present invention relates to a manufacturing method for producing a metal strip (1) through continuous casting. According to the method herein, first in the casting machine 2, a slab 3, preferably a thin slab, is cast, and the cast slab is turned from the vertical direction V to the horizontal direction H. The slab 3 is then milled at the milling machine 4, at the rear of the casting machine 2, in the feed direction F of the slab 3, and at least one rolling train 5, 6. In at least one rolling process). In order to improve the quality of the strip, according to the invention, the rolling and milling cutting process takes place directly following the slab 3 casting in the casting machine 2, where the rolling process is part of the first rolling train 5. It is divided into a rolling process and a partial rolling process in the second rolling column 6, and the milling cutting process in the milling machine 4 takes place immediately before the first rolling process or between two rolling processes. The invention also relates to a manufacturing apparatus for producing the metal strip 1 through continuous casting.

Continuous casting, metal strip, slab, milling machine, rolling mill.

Description

METHOD AND DEVICE FOR PRODUCING A METAL STRIP BY CONTINUOUS CASTING}

The present invention relates to a manufacturing method for producing a metal strip through continuous casting. According to the method of the present invention, a slab, in other words a thin slab, is first cast in a casting machine, and the cast slab is turned from the vertical direction to the horizontal direction. The slab is then subjected to a milling cutting process in the milling machine and at least one rolling process in at least one rolling sequence, as seen in the feed direction of the slab. The invention also relates to a manufacturing apparatus for producing a metal strip through continuous casting.

In the continuous casting of slabs in a continuous casting machine, surface defects such as vibration traces, casting powder defects or surface cracks extending in the longitudinal and transverse directions may occur. Such surface defects occur in conventional thin slab casting machines. Therefore, in accordance with the respective purpose of use of the final strip, it is partially removed from the conventional slab. Many slabs generally have to be flawed according to customer requirements. In this regard, the demand for surface quality of thin slab casting lines continues to increase.

For surface machining, flame descaling, grinding or milling cutting is provided.

Flame descaling has the disadvantage that the molten material cannot be melted again without treatment on the basis of the high oxygen content. In grinding, metal debris mixes with the grinding wheel dust and therefore has to deal with the abrasive powder.

Thus, a surface machining process through milling is provided. In other words, in this case the milling chips are collected and transported into bundles, completely melted again without treatment and fed back into the manufacturing process. The method and corresponding apparatus of the invention are therefore particularly concerned with milling cutting.

Methods and apparatus of the first mentioned type using a milling cutting process or a milling machine, which are disclosed or arranged behind a continuous casting machine, are known. Reference is made to CH 584 085 and DE 199 50 886 A1.

Similar devices are disclosed in DE 71 11 221 U1. This citation document shows that the machine is connected to the casting line and the aluminum strip is machined using the casting heat.

In addition, the point of material removal of the surface of the thin slab in series (flame descaling, milling cutting, etc.) on the top and bottom surfaces, or only on one side just before the rolling sequence has already been proposed. Reference is made to EP 1 093 866 A2.

Further embodiments of surface milling machines are known from DE 197 17 200 A1. In this case, in particular, the variability of the milling cutting contour of the milling apparatus disposed behind the continuous casting machine or in front of the rolling train is described.

Another arrangement and configuration of a tandem milling machine provided in a conventional hot rolling strip mill for processing pre strips has been proposed from EP 0 790 093 B1, EP 1 213 076 B1 and EP 1 213 077 B1. Similar or other solutions are known from EP 0 648 431 A1, US 3 702 329, EP 1 097 764 A2 and DE 1 508 952 A1.

In the surface machining of thin slabs in a so-called CSP system, about 0.1-2.5 mm on one side and on both sides should be removed from the hot slab surface depending on the surface defects detected in the machining line ("serial"). In order not to reduce the production too strongly, thick foil slabs as much as possible are recommended (H = 60 to 120 mm).

Tandem milling machines are not usually used for all products of rolling programs, but only for those products that require relatively higher surface requirements. This is desirable in terms of yield, which reduces milling machine wear and is therefore of significant value.

In this regard, there is a need for a more efficient and therefore more economical use of the known technology. Therefore, efforts are being made to produce faster and better quality, non-exclusive thin slabs.

The production method of the invention is particularly aimed at producing high quality tubes. In this regard, the slab surface shall be absolutely free of cracks. In addition, for metallurgical reasons, a group of predeformers is needed in the first rolling sequence.

It is therefore an object of the present invention to improve the manufacturing method and apparatus thereof in such a way that, in the manufacturing method and apparatus thereof of the type mentioned above, an improved manufacturing process or processing process can be achieved while providing high economics. have. It is an object of the present invention to achieve optimization, particularly with regard to the supply of heat required for casting strands or manufacturing processes, while at the same time providing crack-free surfaces and desirable metallurgical and mechanical properties.

A solution of the object according to the invention is, in connection with a manufacturing method, a rolling process and a milling cutting process immediately following the slab casting in the casting machine, wherein the rolling process comprises a partial rolling process and a first rolling process in the first rolling sequence. It is divided into a partial rolling process in two rolling rows, and between the two partial rolling processes, a milling cutting process in a milling machine is performed.

Preferably the slab is heated in front and / or rear of the first rolling train and the milling machine, for example in a roller hearth furance furnace.

Further, in front of the first rolling train, the slab may be cleaned in the cleaning and descaling apparatus.

1. A manufacturing apparatus for producing a metal strip through continuous casting, comprising: a casting machine on which a slab, that is, a thin slab is cast, is arranged, in which the milling machine and at least one rolling train are arranged at the rear of the casting machine when viewed in the conveying direction of the slab. According to the invention, the manufacturing apparatus is characterized in that, in the conveying direction, a first rolling mill row and a second rolling row are disposed immediately after the casting machine, and a milling machine is disposed between the two rolling rows. do.

If the system used is a two-strand CSP system, the milling machine and the first rolling train are arranged behind the furnace traversing mechanism in order to be able to machine the two strands.

Preferably the furnace is arranged between the first and second rolling rows. In addition, the cleaning and descaling apparatus may be disposed in front of the first rolling train. An additional furnace may be disposed in front of the first rolling train. Each rolling sequence may each include at least one roll stand. In this connection in particular the first row of rolls comprises one or two roll stands, which roll stands are formed as two or four stage roll stands.

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The manufacturing apparatus of the present application may also include means for adjusting the arrangement of the milling cutter of the milling machine according to the pressing position, the thickness position and / or the rotational value of the roll stand or driver disposed in front of the milling machine.

Milling cutting of the slab in the milling machine is such that, according to an embodiment of the invention, the slab top face and the slab bottom face are milled at the same position in the feed direction. According to an alternative method, the milling cutting of the slab in the milling machine may also be made in such a way that the slab top face and the slab bottom face are milled at two positions which are continuous in the feed direction.

The pass carried out in the first rolling sequence may be a smoothing pass, which applies especially when a rolling sequence consisting of a single stand is used. By doing so, preferably the milling cut is already made under the conditions in which the profiling of the slab has been defined and can thus be carried out more effectively (the specific value for the rolling force to be determined depends on the width of the slab). Bottom roller marks, vibration traces and similar surface defects are already partially smoothed by the rolling process in the first rolling train. Thereby, in order to achieve a relatively cleaner slab surface after milling cut, it is only necessary to eliminate the relatively smaller oversize that occurs during milling cut.

With the proposal of the present invention, the transverse bending of the slab, which is present in some cases, is also eliminated.

Relatively little chip removal in milling cuts can produce straight slabs that are not skid.

The proposal of the invention can also be used when water is splashed into the slab head prior to milling cutting, preferably to facilitate the inflow into the milling machine.

Roll roll speeds in roll stands can be different at the top and bottom of the slab.

Overall the manufacturing quality of the slabs, in particular thin slabs, is improved.

Embodiments of the present invention are shown in the drawings.

1 to 4 are side views schematically showing the manufacturing apparatus in which a casting machine, in particular a rolling sequence and a milling machine, is arranged in a manufacturing apparatus for manufacturing a metal strip through continuous casting.

Description of the main parts of the drawings

1: metal strip 2: casting machine

3: slab 4: milling machine

5: first rolling column 6: second rolling column

7: second furnace / roller table capsule portion 8: cleaning and descaling apparatus

9: first furnace 10: cleaning agent

12: Horizontal feeder 13: Measuring device

14: milling cutter 15: support roller

16: Descaler F: Feed direction

V: vertical direction H: horizontal direction

1 shows a manufacturing apparatus for producing a metal strip 1 through continuous casting. The metal strip 1 or the corresponding slab 3 are continuously cast in a known manner in the casting machine 2. The slab 3 is preferably a thin slab. The strand cast in the strand guide (casting segment) is turned or curved in the horizontal direction H in its own vertical direction V in a known manner. After turning in the horizontal direction H, slab cleaning is performed with the cleaning agent 10, followed by profile measurement and surface inspection, respectively, by the measuring device 11. Thereby, not only the surface properties of the slab, but also the geometrical shape of the slab can be detected.

In the conveying direction F, the furnace 9 is first arranged, and then the horizontal feeder 12 is arranged.

After the profile measurement 13, just behind the heated traverse 12, the surface machining of the milling machine 4 takes place at high slab temperatures and thus low load conditions. In the milling machine 4 the slab 3 is milled on its top and bottom surfaces.

In this connection the milling cuts of the top and bottom of the slab 3 are made at two consecutive positions (as viewed in the feed direction F), and two milling cutters 14 formed in the shape of a roll are used. . At this time, the slab 3 is supported by the support roller 15, respectively.

Particularly preferably the feed rate through the milling machine 4 can be determined irrespective of the casting speed (in the casting machine 2) and the second rolling train 6 (finishing rolling). In other words, the milling machine 4 provided in front of the rolling train 5 determines the feed rate of the slab 3. The first rolling train 5 is adjusted to suit the conveying speed.

After the milling cutting process, an optional slab descaling process 8 is provided. Viewed from the conveying direction F, the rolling sequence 5 is arranged following the descaling process, which is composed of two roll stands according to this embodiment. With both roll stands, high quality deformations can be carried out.

The temperature losses incurred by the milling cutting and rolling process in the first rolling train can be compensated for most by the second furnace 7 which is subsequently placed, so that the subsequent deformation in the second rolling train 6 is preferably It can be started under the condition that the temperature sufficiently high is maintained in the second rolling train 6. The second furnace 7 can also be formed as a roller table capsule. This roller table capsule reduces the temperature loss of the deformed slab 3. At the rear of the furnace 7, the descaling apparatus 16 and the aforementioned rolling sequence 6 are arranged.

The rolling train 6 may consist of at least one roll stand (reversible stand). However, usually four to seven roll stands are integrated in the rolling train 6. Further processing by cooling and winding of the metal strip 1 carried out behind the rolling train 6 or by lamination of relatively thicker metal plates is not described in more detail herein.

Additional embodiments of the invention are shown in FIG. 2. Similar to FIG. 1, the casting of the slab 3 takes place in the casting machine 2, and the heating of the slab 3 takes place in the furnace 9 and the transverse feeder 12. Behind the transverse feeder 12, a cleaning and descaling device 8 is arranged, and the slab 3 supplied in this cleaning and descaling device is cleaned and descaled. The slab then reaches the first rolling train 5. The first rolling sequence includes a roll stand that can be formed herein as a two or four stage roll stand. In the first rolling sequence 5, a smoothing mold is achieved, and the geometric non-uniformity on the surface of the slab can be eliminated with this smoothing mold. In addition, almost the desired thickness removal can be carried out in the first rolling train 5. The slab 3 is then conveyed from the first rolling train 5 into the milling machine 4.

In this connection the first rolling train 5 provided in front of the milling machine 4 can also be formed as a powerful driver, in order to ensure a reliable transport of the slab 3 through the milling machine 4. . In the rear of the milling machine 4, further processing takes place in the second furnace 7, the descaling device 16 and the rolling train 6, similar to FIG. 1, whereby the finished product 1 is produced.

A further alternative embodiment of the manufacturing apparatus of the present application is shown in FIG. 3. The arrangement and configuration is the same as in the system according to FIG. 2. However, according to this embodiment, the surface treatment by the milling cutting of the 1st rolling process 5 and the milling machine 4 is carried out (the 1st furnace apparatus 9, the horizontal feeder 12, and the 2nd furnace apparatus. Executed at the rear of the furnace (consisting of 7). In such an application, reheating of the slab 3 made in front of the second rolling train 6 is excluded.

According to the system configuration according to FIG. 4, the system consists of two rolling trains. After casting in the casting machine 2 and heating in the first furnace 9 and the horizontal feeder 12, the first rolling process 5 is started. And in the case of the present embodiment, after the deformed slab 3 in the second furnace 7 is reheated, the surface treatment takes place just before the finishing line.

In other words, FIG. 4 shows a further variant of the apparatus for producing metal strip 1 through continuous casting. The metal strip 1 or the corresponding slab 3 are also continuously cast in a known manner in the casting machine 2. After the slab 3 is turned in the horizontal direction H, slab cleaning using the cleaning agent 10 is performed, followed by profile measurement or surface inspection by the measuring device 11. Accordingly, according to the present embodiment, not only the surface properties of the slab but also the geometrical shape of the slab can be detected.

In the conveying direction F, firstly the furnace 9 is arranged, and then the horizontal conveying apparatus 12 is followed.

Behind the transverse feeder 12, a cleaning and descaling device 8 is disposed in which the supplied slab 3 is cleaned and descaled. The slab is then fed to the first rolling train 5. This first rolling sequence 5 comprises a roll stand which can be formed as a two or four stage roll stand in accordance with this embodiment. In the first rolling sequence 5, a smoothing mold is made, in which the geometric non-uniformity on the surface of the slab can be eliminated. In addition, the thickness removal already targeted in the first rolling sequence 5 may also be performed.

The slab 3 is fed to the holding furnace 7 after the first rolling train 5 and then to the milling machine 4. Between the holding furnace 7 and the milling machine 4 a measuring device 13 for profile measurement is arranged according to the present embodiment.

In the milling machine 4 the slab 3 is milled on its top and bottom surfaces.

In this connection, the milling cuts of the top and bottom of the slab 3 are made at two consecutive positions (as viewed in the feed direction F), and two milling cutters 14, which are formed in a roll shape, Is used. At this time, the slab 3 is supported by the support roller 15, respectively.

Behind the milling machine 4 is arranged a second row of rolling mills 6 which may comprise a plurality of roll stands. In the second rolling train 6 the slab 3 is processed into the final form of the desired metal strip 1.

In essence, the rolling and milling cutting process takes place immediately following the casting of the slab 3 in the casting machine 2 (in other words, in a series transfer manner), in which the rolling process consists of a partial rolling process in the first rolling train row 5 and It is divided into the partial rolling process in the 2nd rolling column 6, and the milling cutting of the slab 3 in the milling machine 4 is performed between these two partial rolling processes.

In other words, the deformation of the slab 3 is started before the milling cut.

In addition, the first rolling train 5 may be disposed in front of or behind the second furnace 7. Surface machining may also be done in front of or behind the furnace 7.

In sum, the suggestions herein can be summarized as follows:

The cutting surface machining takes place immediately before the first deformation step or between two deformation steps (roll stand group), depending on the method being replaced. According to the diagram of FIG. 1, the milling machine and the rolling mill 5 have residual deformations to the desired final thickness in the finishing line 6 just in front of the second furnace 7, that is to say with an input condition of good surface quality. Is placed in the position before the start. In addition, the rolling train 5 may be arranged at the rear of the holding furnace 7. In addition, it is conceivable to carry out a direct cutting surface machining between the rolling column 5 and the holding furnace 7, whereby reheating can be carried out after preliminary deformation and surface machining.

According to the illustrated embodiment, the plane milling cutter can be identified on the upper and lower surfaces, respectively. It is also conceivable to arrange two milling units in succession on each of the upper and lower surfaces when the degree of milling removal is high for each surface or the material is very hard.

According to an embodiment alternative to the use of a plain milling cutter, another milling cutter, such as a face cutter, or a grinding tool, or another surface cutting tool (such as removing flame scale from the surface) at a given location Also available. In other words, instead of using a plane milling cutter or a face cutter, another cutting tool can be used.

Examples of the cutting material for the cutting edge of the milling cutter include HSS; Uncoated or preferably coated hard materials; ceramic; Polycrystalline cutting material may be provided. Usually, conventional indexable cutting inserts can be used.

The milling machine may consist of two or more milling units, which may be arranged in series per slab surface.

The milling machine can adjust the feed rate of the slab in front of the first roll stand regardless of the casting machine and the second rolling train.

The furnace disposed behind the milling machine primarily serves to compensate for the temperature loss occurring in the milling machine and the first rolling sequence.

By means of the first rolling sequence, splashing of the slab head is preferably performed as desired.

In addition to the measurement of the slab geometry, in addition to the measurement of the slab geometry, the position of the roll stand, ie driver, placed in front of the milling machine can be adjusted to optimally adjust the milling machine to the input conditions (particularly slab thickness and slab wedge shape). In other words, for the adjustment of the milling cutter, in particular the plane milling cutter, the height corresponding to the slab thickness of the roll stand as a driver and the angle of rotation with respect to the conveying direction of the slab are considered. And, for example, when an inclined position is detected, it is possible to determine whether to mill the slab or to mill the slab wedge shape uniformly over the width by adjusting appropriately to the inclined position.

Claims (16)

First the slab 3 is cast in the casting machine 2, which is cast from the vertical direction V to the horizontal direction H and then viewed in the conveying direction F of the slab 3. In the rear of the casting machine 2, the slab 3 is subjected to a milling cutting process in the milling machine 4 and at least one rolling process in at least one rolling train 5, 6. In the manufacturing method for manufacturing the metal strip 1 through The rolling and milling cutting process is carried out immediately after the slab 3 casting in the casting machine 2, in which the rolling process is performed in the partial rolling process in the first rolling train 5 and in the second rolling train 6. And a milling cutting process in the milling machine (4) is carried out between the two rolling processes. 2. The metal strip according to claim 1, wherein heating of the slab 3 in the furnace 7 takes place between the first row of rows 5 and the second row of rows 6. Manufacturing method for manufacturing 1). The metal strip (1) according to claim 1 or 2, characterized in that the cleaning of the slab (3) in the cleaning and descaling device (8) takes place in front of the first rolling train (5). Manufacturing method for manufacturing 1). The metal strip 1 according to claim 1 or 2, characterized in that the temperature of the slab 3 is controlled in the furnace 9 in front of the first rolling train 5. Manufacturing method for manufacturing. A manufacturing apparatus for producing a metal strip 1 through continuous casting, which is provided with a casting machine 2 on which a slab 3 is cast, in order to carry out the manufacturing method according to claim 1. As seen in the feed direction F of the slab 3, at least one rolling train 5, 6, as well as a milling machine 4, is arranged behind the casting machine 2. In the manufacturing apparatus for manufacturing 1), In the transport direction F, behind the casting machine 2, a first rolling train row 5 and a second rolling train row 6 are disposed immediately after the casting machine, and the two rolling train rows 5, 6. A manufacturing device for producing a metal strip (1) by continuous casting, characterized in that a milling machine (4) is arranged between the elements. 6. A manufacturing apparatus for producing a metal strip (1) by continuous casting as claimed in claim 5, characterized in that a furnace (7) is arranged between the first row of rolling mills (5) and the second row of rolling mills (6). . 7. A manufacturing apparatus for producing a metal strip (1) by continuous casting as claimed in claim 6, characterized in that the furnace (7) is formed as a roller table capsule which reduces the temperature loss of the deformed slab (3). . 6. A manufacturing apparatus for producing a metal strip (1) according to claim 5, characterized in that a cleaning and descaling device (8) is arranged in front of the first rolling train (5). 6. Manufacturing apparatus for producing a metal strip (1) according to claim 5, characterized in that the furnace (9) is arranged in front of the first row of rolling mills (5). 6. Manufacturing apparatus for producing a metal strip (1) according to claim 5, characterized in that each rolling sequence (5, 6) comprises at least one roll stand respectively. 6. The metal strip (1) is produced by continuous casting as claimed in claim 5, characterized in that the first rolling train (5) comprises one or two roll stands which are formed as two or four stage roll stands. Manufacturing apparatus for 6. Manufacturing apparatus for producing a metal strip (1) by continuous casting as claimed in claim 5, characterized in that the milling machine (4) comprises a plain milling cutter. 13. Apparatus according to claim 12, characterized in that the milling machine (4) comprises one or more plain milling cutters per slab surface. 6. Manufacturing apparatus for producing a metal strip (1) according to claim 5, characterized in that the milling machine (4) comprises a face cutter. 6. The milling cutter (14) of the milling machine (4) according to claim 5, wherein the milling cutter (14) of the slab (3) has a height corresponding to the thickness of the slab (3) of the roll stand as a driver provided in front of the milling machine (4). A manufacturing apparatus for producing a metal strip (1) through continuous casting, characterized in that it is adjusted based on at least one of the rotation angle with respect to the conveying direction (F). delete

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