The invention concerns a method and a continuous casting device for the dynamic adjustment of roller segments that support and/or guide both sides of a continuously cast strand made of metal, especially steel, with at least two successive pairs of rollers, which are adjusted relative to each other by piston-cylinder units, which are acted upon with both position control and pressure control, and the pairs of rollers are then adjusted to the continuously cast strand by position control, and the hydraulic pressure is switched from position-controlled operation to pressure-controlled operation when the hydraulic pressure in a piston-cylinder unit reaches a predetermined value.
A method of this type a described in EP 1 062 066 B1. The method was previously used on driver stands of bloom and billet continuous casting machines, in which the hydraulic piston-cylinder units are position-controlled and pressure-controlled. However, the method found no acceptance in other operations, except for slab and thin-slab continuous casting machines.
The objective of the invention is to expand the previous objective, which was to develop an adjustment method that would avoid damage of the roller segments due to excessive forces and to eliminate bulging of the continuously cast strand as far as possible, by making the method accessible to a larger number of types of continuous casting operations.
In accordance with the invention, this objective is achieved by applying the method to roller segments of continuous bloom and billet casting machines, such that the roller segments are installed in the cold bar zone, the hot bar zone, and/or the soft reduction zone. This allows gentle adjustment of roller segments that is adapted to the given type of operation, even in the case of continuously cast bloom and billet cross sections.
In an advantageous refinement, integrated, driven rollers arranged on the segment entrance side and/or on the segment exit side of swiveling and/or parallel-adjustable roller segments are switched from position-controlled operation to pressure-controlled operation, depending on the phase of the process. This guarantees force or pressure states individually adjusted to the given type of operation.
A continuous casting device for casting continuous bloom or billet sections has a containment roll stand, which is arranged after the continuous casting mold, and a bending-straightening unit.
In accordance with the invention, the process-engineering objective of expanding the method to a larger number of different types of operations is achieved with respect to the equipment by arranging a device at least partially in front of the bending-straightening unit or completely behind the bending-straightening unit, with several hydraulically operated piston-cylinder units with position-controlled or pressure-controlled, adjustable roller segments, each of which has at least one driven roller.
In accordance with other features of the invention, power is transmitted to the continuously cast strand by providing the driven rollers on the segment entrance side and/or on the segment exit side. In this way, with appropriate angular positioning of a roller segment also provided, force is intensively transmitted to the continuously cast strand or the cold bar.
In accordance with other features of the invention, the drives for the driven rollers are designed in such a way that the drive motor for a driven roller is arranged, together with a transfer case, on one side of the segment frame with a vertical drive shaft orientation. In this way the power transmission is direct, and the accessibility of the motors is advantageously simple.
The hydraulic piston-cylinder units and the drive motors for driven rollers are each operated in such a way that the adjustment and automatic regulation concept for the dynamic adjustment is divided into automatic segment control and basic automation.
In this regard the open-loop and/or closed-loop control is further designed in such a way that the automatic segment control comprises at least the given operation strategy, roll spring compensation, a maximum force regulator, a minimum force regulator, and a positioning system. The hydraulic piston-cylinder units optimally adjust the guiding and conveying force for the hot bar, the cold bar (starting bar), and the soft reduction.
Furthermore, in accordance with other features of the invention, the basic automation system comprises at least the given type of operation, a torque controller, and a speed controller. Each driven roller is adjusted to its optimum speed or optimum torque in this way.
In addition, the automatic control of the process is advantageously designed by providing each piston-cylinder unit with two pressure sensors spaced some distance apart for different piston positions and a position sensor for the piston of a piston-cylinder unit. The pressure sensors and position sensor are connected with the automatic segment control system.
Finally, the closed-loop and/or open-loop control is completed by providing for communication between the drive motor for the driven roller and the basic automation system.
The drawings show embodiments of the continuous casting device, which is described in greater detail below and on the basis of which the method of the invention is also described.
Molten steel flows from a tundish 1 into a cooled continuous casting mold 2, which is oscillated by an oscillation unit 3 to produce shell solidification of the continuously cast strand 4 leaving the continuous casting mold 2 and prevent sticking. The continuously cast strand 4, which is liquid on the inside and is guided in containment roll stands 5 passes in succession through cooling zones 6, 7, 8, 9, and 10 and then enters a bending-straightening unit 11. Moving in the direction of strand movement 12, the continuously cast strand 4, which has now cooled further, enters roller segments 13, 14, 15, 16, and 17 (
Each roller segment 13 to 17 has at least two pairs of rollers 18. Each roller segment 13 to 17 is equipped with a pair of piston-cylinder units 19, which, however, are successively arranged on a center line within a roller segment 13 to 17 and adjust only an upper part of the corresponding roller segment, while the lower part is rigidly mounted on the segment frame 13a (to 17a).
The roller segments 13 to 17, which lie opposite each other in pairs, are adjusted towards each other by the piston-cylinder units 19 under automatic control, and this adjustment is made with both position control and pressure control. In this regard, the pairs of rollers 18 are first set on the continuously cast strand 4 by position control. The contact force is switched from position-controlled operation to pressure-controlled operation as soon as the hydraulic pressure in a piston-cylinder unit 19 has reached a predetermined value.
The method is applied to the roller segments 13 to 17 of bloom and billet continuous casting devices 20, said roller segments 13 to 17 being arranged in the cold bar zone, hot bar zone, and/or soft reduction zone. On the segment entrance side 21 and/or on the segment exit side 22 of the swiveling or parallel-adjustable roller segments, driven rollers 23 integrated in the given segment can be switched from the position-controlled operation to the pressure-controlled operation in the piston-cylinder units 19, depending on the phase of the process or on the type of operation.
The continuous casting device with the containment roll stand 5, which is arranged after the continuous casting mold 2, and with the bending-straightening unit 11 then has several roller segments 13 to 17, which carry the driven rollers 23 and the piston-cylinder units 19 (
Each roller segment 13 to 17 has the piston-cylinder unit 19 on an upper roller conveyor 24, which lies opposite a lower, fixed roller conveyor 25. On one side 26, a drive motor 29 with transfer case 30 is arranged with a vertical drive shaft orientation 28 (
The basic automation system 33 comprises at least the given type of operation 34, a torque controller 39, and a speed controller 40.
Pressure sensors 41 spaced some distance apart for piston positions and a position sensor 42 for the piston 43 of a piston-cylinder unit 19 are provided on each piston-cylinder unit 19. The pressure sensors and position sensor are connected with the automatic segment control system.
The drive motor 29 for a driven roller 23 communicates with the basic automation system 33 (
Number | Date | Country | Kind |
---|---|---|---|
102 36 367 | Aug 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP03/07463 | 7/10/2003 | WO | 00 | 9/26/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/018129 | 3/4/2004 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3358743 | Adams | Dec 1967 | A |
6102101 | Hanazaki et al. | Aug 2000 | A |
6386268 | Weyer et al. | May 2002 | B1 |
20030178171 | Weyer et al. | Sep 2003 | A1 |
Number | Date | Country |
---|---|---|
196 27 336 | Sep 1997 | DE |
101 60 636 | Jul 2002 | DE |
0 804 981 | Nov 1997 | EP |
9946071 | Sep 1999 | WO |
0189742 | Nov 2001 | WO |
0218077 | Mar 2002 | WO |
Number | Date | Country | |
---|---|---|---|
20060151144 A1 | Jul 2006 | US |