Patent Grant
8267153
The present application is a 371 of International application PCT/EP2009/006788 filed Sep. 21, 2009, which claims priority of DE 10 2008 048 488.1, filed Sep. 23, 2008, and DE 10 2008 057 888.6, filed Nov. 18, 2008, the priority of these applications is hereby claimed and these applications are incorporated herein by reference.
The invention concerns a continuous casting mold for the continuous casting of a metal strand, especially a steel strand, with opposite broad-side walls and with opposite narrow-side walls, which are arranged in such a way that they can be clamped between the broad-side walls and can be displaced along the broad-side wane transversely to the direction of casting and which taper in wedge-like fashion in the direction of casting, wherein the broad-side walls have a funnel-shaped pouring region, which extends to the end of the mold in the direction of casting, wherein the narrow-side walls are interchangeably arranged according to the thickness to be set for the metal strand to be cast, and wherein the positions of the narrow sides can each be adjusted, with respect to the center axis of the metal strand to be cast, by means of a narrow-side adjustment system that comprises an upper and a lower adjusting device.
Especially in the recent past, in the production of metal strands, especially steel slabs, there has been an increasing trend towards the use of slab molds whose dimensions can be varied according to the desired width and height of the steel strand. In this connection, the width of the steel strand can be adjusted by varying the distance between the two narrow sides. If the thickness of the slab is to be varied, this requires that preferably one of the broad sides of the casting mold be designed as a movable side and adjusted relative to the stationary side. Correspondingly, narrow sides with a different format must be clamped in between the broad sides. This is known, for example, from U.S. Pat. No. 6,973,957.
Depending on the width of the necessary narrow-side plate element, this must be operated by a control device to move it towards the center of the mold or in the opposite direction according to the width of the slab to be cast. The control device comprises an upper and a lower adjusting element to make it possible to squeeze the side wall downward between the two broad sides according to the necessary inclination of the mold center. In this connection, if the control device does not act at least essentially centrally on the side wall, lateral tilting moments are exerted on the side wall, which take the side wall out of the desired position and cause damage.
The center axis of the narrow-side adjustment system is aligned on the center position of the given casting thickness in a well-known way in the workshop with the aid of screwed connections that are arranged parallel to the center axis. In this regard, the narrow-side wall is fixed between the broad sides by frictional engagement in the clamping joint. However, there are also embodiments in which the adjusting device cannot be brought to the given center axis of the side wall, because the guide tubes of the control device are permanently welded in the frame of the mold.
To adjust the mold to a new casting thickness, the parts of the frame of the mold often must be broken down into their individual parts, or individual water tanks are removed. When a new casting thickness is to be adjusted, it is always necessary to exchange parts, including, for example, water-conveying elements, which in many cases do not have the mobility that would be required to allow compensation of the displacements of the water tank of the movable side that result from the change in the thickness of the slab.
All together, the assembly and alignment work involved in the adjustment of the position of the center axis proves to be very time-consuming. The adjustment and exact alignment often require complicated measurement and alignment of pistons moving in cylinders or guide pins of the adjustment system among themselves and relative to the theoretical stationery-side reference plane. This also requires that many replaceable parts be kept on hand for different casting thicknesses. When a change in casting thickness is made, it is often necessary to install and later uninstall bellows expansion joints for compensating differences in path length as well as assigned parts that depend on casting thickness. To achieve ideal adjustment of the center of the narrow-side adjustment system, it is even necessary under certain circumstances to uninstall and later reinstall the water tanks on the movable side.
The objective of the invention is to improve a continuous casting mold in such a way that the position of the center axis of a narrow-side adjustment system for molds with different casting thicknesses can be adjusted in a simple way to the given ideal position of the center axis for the given thickness format of a slab.
In regard to a continuous casting mold of the aforementioned type, the solution to this problem is characterized in that the narrow-side adjustment system has at least one control element, which acts in common on the adjusting devices at least essentially transversely to the center axis, and an alignment device for aligning the positions of the upper and lower control devices with respect to a specified reference position, which positions are adjusted by the one or more control elements. The use of the invention makes it possible to convert molds to a new casting format mite quickly than is the case with conventional methods. Due to the good accessibility of the control elements, the water tank on the movable side does not have to be uninstalled. A continuous casting mold equipped with the narrow-side adjustment system is subject to less risk of misalignment by pushing or pulling on machined reference surfaces or by, a position measuring device integrated in the control element or the control device.
Advantageous modifications of the invention are disclosed in the dependent claims.
An advantageous provision of the invention is that the alignment device comprises connecting means and/or a format piece for producing a connection to at least one mechanical reference surface or for setting to an exact reference position for establishing the casting thickness.
In an advantageous modification, the control elements comprise two hydraulically or pneumatically operated cylinders arranged transversely to the center axis and/or drives operated by electric motor, especially spindle drives.
Preferably, the cylinders and/or the electric drives can be operated under automatic position control.
It can also be provided that the control elements comprise cup spring units and hydraulic plunger cylinders. In the case of manual setting, the control elements form a screw system, in which the positions of the screws can be fixed by counter nuts.
It is advantageous if the control elements are formed sufficiently long that they are accessible from the outside of the continuous casting mold.
In another advantageous refinement of the invention, it is provided that a displaceable water tank arranged on the movable broad side is at least partially integrated in a lateral frame region formed by the continuous casting mold by a water-conveying element that receives the water tank's displacement and is arranged in the lateral frame region and supported there and/or that the displaceable water tank is freely arranged above a cheek of the continuous casting mold.
It is advantageous if the water-conveying element comprises a lateral bellows expansion joint and/or a hose, especially in conjunction with a rigid length of pipe, where especially the ends of the length of pipe are spherically formed, especially in conjunction with sealing elements that provide a radial seal. Moreover, this system also requires fewer special steel plate parts compared to the prior art.
The invention will now be explained in greater detail on the basis of a specific embodiment.
A continuous casting mold (
The support frame 1 supports a copper plate 4, which forms the stationary broad side of the pouring funnel. Copper plates 5 belonging to the respective narrow-side parts 12 are arranged on the narrow sides. Each copper plate 5 is mounted on a beam 6. The illustrated copper plate 5 corresponds to a selected casting thickness a. The support frame 3 supports a copper plate 4.
A narrow-side adjustment system 7 is present, which preferably comprises an upper adjusting element 8 and a lower adjusting element 9 located beneath it. These two adjusting elements 8, 9 serve to adjust the width of the cast strand, i.e., to move the copper plate 4′ in the direction of arrow C, and at the same time to maintain the inclination of the copper plate 5 necessary to form the pouring funnel.
To allow synchronous adjustment that preserves the inclination of the copper plate 5, the adjusting element 8 and the adjusting element 9 located below it are coupled with each other by a connecting part 10 (
The control elements 12, 13 each comprise hydraulic or pneumatic cylinders or have a threaded spindle operated by an electric motor. The control elements 12, 13 preferably also have displacement pickups or are equipped with other means for detecting distances and/or positions and for suitably controlling an adjusting element. The control elements 12, 13 adjust each of the narrow sides 2 relative to the reference marks 14. In addition, format pieces 15 that depend on the casting thickness can be used to facilitate alignment. The reference marks 14 and the format pieces 15 together constitute an alignment device or are part of an alignment device.
The entire narrow-side adjustment system 7 is preferably integrated in a lateral frame region 16, which extends to the side of the casting mold and does not extend beyond the front edge of the support frame 1, i.e., the edge in the casting direction, or at least does not extend substantially beyond it. In connection with the displaceability of the control elements 12, 13, a water-conveying element 17 can also be moved together with them, which offers the necessary mobility to be able to compensate the displacements of the water tank of the movable side that result from the differences in casting thickness. The water-conveying element 17 comprises a lateral bellows expansion joint and a movable hose, for example, also in conjunction with a rigid length of pipe. In this regard, spherically shaped ends can be provided on the connecting elements in conjunction with sealing elements that provide a radial seal. O rings, for example, can be used as the sealing elements. This gives the lengths of pipe, for example, a “dog bone shape”.
The mold is supported on a lift system by fixation points 18.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2008 048 488 | Sep 2008 | DE | national |
| 10 2008 057 888 | Nov 2008 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP2009/006788 | 9/21/2009 | WO | 00 | 7/6/2011 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2010/034444 | 4/1/2010 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20110259543 A1 | Oct 2011 | US |
