The present invention relates, in general, to apparatuses and methods for controlling the horizontal oscillation of edge dams of twin roll strip casters and, more particularly, to an apparatus and method for controlling the horizontal oscillation of an edge dam of a twin roll strip caster which can prevent a casting roll and the edge dam from being damaged while oscillating the edge dam to reduce edge skull.
Generally, twin roll strip casting is a process including supplying molten steel to two rolls that are rotating, and continuously producing a strip having a thickness of several mms directly from the molten steel.
As shown in
Two edge dam refractories 150 are respectively provided on opposite ends of the pair of casting rolls 110 to prevent molten steel from flowing out of the space between the casting rolls 110. Both high temperature molten steel that has been supplied between the casting rolls 110 and the casting rolls 110 that are being cooled by water are simultaneously put in contact with the active surfaces of the edge dam refractories 150 that have been preheated before casting. Hence, of the surfaces of the edge dam refractories 150, portions that make contact with the casting rolls 110 cool rapidly, causing heat loss in the vicinity thereof, thereby forming conditions under which molten steel can easily solidify.
Therefore, as shown in
In an effort to overcome the above problems, a technique of injecting an inert gas into the molten steel through the lower portion of the edge dam and preventing the molten steel from solidifying, and a technique of oscillating the edge dam refractories at a predetermined amplitude and physically removing the skull were proposed.
The inert gas injection method of the skull removal techniques is a technique in which a thin metal tube is installed on the lower portion of each edge dam refractory and an inert gas is injected into the molten steel through the metal tube, thus preventing the molten steel from solidifying, and reducing skull. This technique is comparatively effective at reducing skull of the lower portion of the edge dam, but there still remains the problems of the generation and growth of surface skull on the inner surface of the edge dam and of edge skull on junction surfaces between the casting rolls and the active surface of the edge dam.
As shown in
However, this technique pertains to a mechanical oscillating method using an oscillation cam 302, which is fixed in amplitude. Thus, when it is necessary to change the amplitude, it is required to replace the eccentric shaft 330, an eccentric ring or others with new ones before casting, and depending on a worker, the amplitude may be different. Hence, even if edge skull forms during the casting, it is impossible to control the amplitude, forcing the casting operation to be interrupted. Moreover, because the edge dam refractory oscillates in the same manner as that of a pendulum, the upper and lower portions of the edge dam reliably oscillate, but as it becomes closer to the center of the edge dam, the amplitude reduces, and a dead zone 200 that does not oscillate is eventually formed at the center of the edge dam. In the dead zone, skull is still formed and grown, causing the problem of mixing with a casting strip. Meanwhile, although it is possible to increase the amplitude to prevent the occurrence of the dead zone, this may damage the edge dam, and fragments of the damaged edge dam may mix with a casting strip.
Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide an apparatus and method for controlling the horizontal oscillation of an edge dam of a twin roll strip caster which can rapidly remove edge skull that is formed by stagnation and solidification of molten steel, and can effectively suppress the generation and growth of skull, thus preventing a component such as a casting roll or an edge dam from being damaged, thereby ensuring the stability of casting, and improving the quality of a casting strip.
In order to accomplish the above object, in an aspect, the present invention provides an apparatus for controlling horizontal oscillation of an edge dam of a twin roll strip caster, the apparatus including an oscillation unit horizontally oscillating an oscillation plate in accordance with an oscillation waveform so that an edge dam refractory coupled to the oscillation plate horizontally oscillates, a servo valve outputting the oscillation waveform to the oscillation unit to perform the horizontal oscillation, and a control unit applying the oscillation waveform to the servo valve, thus controlling the horizontal oscillation of the oscillation unit.
The oscillation unit may include a main body installed with a hydraulic line, a hydraulic cylinder fastened to the main body, a cylinder rod placed through the hydraulic cylinder so as to be movable to opposite sides of the hydraulic cylinder, and a support connecting opposite ends of the cylinder rod to opposite ends of the oscillation plate.
The apparatus for controlling the horizontal oscillation of the edge dam of the twin roll strip caster may further include an oscillation-unit-displacement measuring device transmitting information about a real time position of the oscillation unit to the control unit.
The control unit may include an oscillation information collector collecting from an HMI (Human Machine Interface) information about an ON/OFF status of the oscillation, and an amplitude, a frequency and a waveform of the oscillation, an oscillation waveform generator generating, using the information received from the oscillation information collector, a reference of the oscillation waveform having an amplitude and a frequency that are required to control the horizontal oscillation, and a horizontal oscillation controller controlling the servo valve both using the information about the oscillation waveform received from the oscillation waveform generator and using information about a position of the oscillation unit that is received from the oscillation-unit-displacement measuring device, thus controlling the horizontal oscillation of the oscillation unit.
The control unit may further include a ramping unit varying at constant rates the amplitude and the frequency of the reference of the oscillation waveform generated from the oscillation waveform generator.
The control unit may further include an oscillation-unit-center measuring device transmitting information about a center position of the oscillation unit to the horizontal oscillation controller.
The oscillation waveform may comprise a sine wave, a rectangular wave or a triangular wave.
The amplitude of the oscillation waveform may range from 10 μm to 1,500 μm, and the frequency may range from 0.1 Hz to 20 Hz.
In another aspect, the present invention provides a method for controlling horizontal oscillation of an edge dam of a twin roll strip caster, the method including horizontally oscillating an oscillation plate using a servo valve and a cylinder in accordance with an oscillation waveform so that an edge dam refractory coupled to the oscillation plate horizontally oscillates, thus eliminating a zone which does not oscillate, and reducing edge skull.
The horizontally oscillating may comprise horizontally oscillating the oscillation plate such that at an initial stage of casting, an amplitude of the oscillation is maintained within a range from 500 μm to 1,200 μm, and after the initial stage has passed, the amplitude is maintained within a range from 200 μm to 600 μm, and at a final stage of the casting, the amplitude is maintained within a range from 400 μm to 700 μm.
The method for controlling the horizontal oscillation of the edge dam of the twin roll strip caster may include reducing the frequency of the oscillation waveform or changing the oscillation waveform from a sine wave into a rectangular or triangular wave, thus minutely controlling the amplitude of the oscillation waveform.
The method for controlling the horizontal oscillation of the edge dam of the twin roll strip caster may include an operation of selecting information about an ON/OFF status of the oscillation, and an amplitude, a frequency and a waveform of the oscillation using an HMI (Human Machine Interface) monitor, a slow loop operation of collecting the information selected using the HMI monitor and transmitting the information to a medium loop, a medium loop operation of generating, using the information received from the slow loop, a reference of the oscillation waveform having an amplitude and a frequency that are required to control the horizontal oscillation, and transmitting the reference to a fast loop, and a fast loop operation of controlling the servo valve both using the information about the reference of the oscillation waveform received from the medium loop and using information about a position of an oscillation unit received from an oscillation-unit-displacement measuring device, thus controlling horizontal oscillation of the oscillation unit.
The medium loop operation may include varying the amplitude and frequency of the reference of the oscillation waveform at constant rates, and transmitting the information about the reference of the oscillation waveform to the fast loop.
The fast loop operation may include controlling the horizontal oscillation of the oscillation unit in a period of 0.001 or less.
The present invention variably controls the amplitude, frequency and waveform of the oscillation depending on casting conditions, and horizontally oscillates an edge dam using a servo valve and a hydraulic cylinder. Therefore, the present invention can rapidly remove edge skull and suppress generation and growth of skull, thus preventing a casting roll or the edge dam from being damaged, thereby ensuring the stability of casting, and improving the quality of a casting strip.
a) is a front view of a conventional edge dam oscillating device, and
a) is a schematic view showing an oscillation form of the conventional edge dam oscillating device, and
Hereinafter, an apparatus for controlling horizontal oscillation of an edge dam of a twin roll strip caster according to the present invention will be described in detail with reference to the attached drawings.
As shown in
As shown in
As shown in
The oscillation control apparatus according to the present invention includes the control unit 501 which applies an oscillation waveform having a predetermined amplitude and oscillation frequency to the servo valve 509, thus controlling horizontal oscillation of the oscillation unit 400.
As shown in
Further, an oscillation waveform generator 512 of the control unit generates an oscillation waveform having an amplitude and oscillation frequency that are required to control horizontal oscillation, in response to the information received from the oscillation information collector 511. The generated oscillation waveform information is transmitted to the horizontal oscillation controller 508 of the fast loop 503.
Given information about a real-time position of the oscillation unit 400 that has been received from an oscillation-unit-displacement measuring device 460 which is coupled to the upper end of the oscillation plate 410, the horizontal oscillation controller 508 applies the oscillation waveform information from the oscillation waveform generator 512 to the servo valve 509 and controls the hydraulic pressure in the hydraulic cylinder 420 based on a positional value of a center of the oscillation unit 400 that is transmitted from an oscillation-unit-center measuring device 507, so that such control makes the edge dam refractory 150 horizontally oscillate to the left and right at high speed.
Here, the oscillation-unit-displacement measuring device 460 checks in real time the positional information of the oscillation unit 400 and transmits it to the control unit 501. The oscillation-unit-center measuring device 507 transmits the positional value of the center of the oscillation unit 400 to the horizontal oscillation controller of the fast loop 503 so that the oscillation unit 400 can horizontally oscillate to the left and right based on the center between both casting rolls 110.
The control unit 501 further includes a ramping unit 504 which smoothly varies at constantly increasing rates the amplitude and oscillation frequency of a reference of an oscillation waveform generated from the oscillation waveform generator 512 so as to prevent the apparatus from being exposed to the impacts which may be generated by drastically changing the amplitude and oscillation frequency of the reference of the oscillation waveform. In other words, the ramping unit 504 controls the reference values of the amplitude and oscillation frequency of the oscillation waveform transmitted from the oscillation waveform generator 512 such that the reference values slowly vary at a constant rate, before transmitting the reference values to the horizontal oscillation controller 508.
In the oscillation control apparatus of the present invention, the oscillation waveform is a sine wave, a rectangular wave or a triangular wave. As shown in
Furthermore, the amplitude of the oscillation waveform used in the oscillation control apparatus of the present invention ranges from 10 μm to 1,500 μm, and the oscillation frequency ranges from 0.1 Hz to 20 Hz. The oscillation control apparatus is designed such that depending on casting conditions and the kind of a mixed skull, the amplitude and the oscillation frequency are controlled to within the above ranges.
Hereinafter, the method for controlling horizontal oscillation of the edge dam of the twin roll strip caster according to the present invention will be described in detail with reference to the attached drawings.
The method for controlling the horizontal oscillation of the edge dam of the twin roll strip caster according to the present invention includes a real time feedback control. Under the control of the control unit 501 which successively conducts the steps of a slow loop 506, the medium loop 505 and the fast loop 503, the servo valve 509 and the hydraulic cylinder 420 horizontally oscillate the oscillation plate 410 in accordance with an oscillation waveform having a predetermined amplitude and oscillation frequency that is applied from the control unit 501. Thereby, the refractory 150 of the edge dam that is coupled to the oscillation plate 410 is horizontally oscillated, thus eliminating a dead zone 200 that is a portion which is not affected by the oscillation, and reducing edge skull.
The steps of controlling the horizontal oscillation of the edge dam will be explained in detail. As shown in
At step S2 (the step of the slow loop 506), the information about the oscillation of the edge dam that has been selected by the HMI monitor is received and transmitted to the medium loop 505.
At step S3 (the step of the medium loop 505), based on the information about the oscillation of the edge dam that has been received from the slow loop 506, reference values of the oscillation waveform having a predetermined amplitude and oscillation frequency that are required to control the horizontal oscillation of the edge dam are created in a period of 0.01 second. The reference values of the oscillation waveform are transmitted to the fast loop 503. At the step of the medium loop, to mitigate the impact that is caused by drastic changes in the amplitude and oscillation frequency of the reference generated in the oscillation waveform generator 512, oscillation waveform, the amplitude and oscillation frequency of the reference of the oscillation waveform are smoothly varied at constant rates, and then information about the reference of the oscillation waveform is transmitted to the fast loop 503.
At step S4 (the step of the fast loop 503), using both the information about the reference of the oscillation waveform that has been transmitted from the medium loop 505 and the information about the real-time position of the oscillation unit 400 that has been received from the oscillation-unit-displacement measuring device 460, an oscillation waveform having a predetermined amplitude and oscillation frequency that are required for the horizontal oscillation is applied to the servo valve 509 in a period of 0.001 second or less, thus controlling the hydraulic pressure in the hydraulic cylinder 420 of the oscillation unit 400. Thereby, the horizontal oscillation of the edge dam refractory is controlled based on the center as determined by the oscillation-unit-center measuring device 507 of the medium loop 505. Therefore, feedback control is conducted 1000 times or more per second, thus enhancing the precision of the oscillation control.
The operation of the oscillation unit of the oscillation control apparatus of the present invention will be described in detail. As shown in
Meanwhile, as shown in
After the initial stage of the casting has passed, and the stage is one in which the casting has stabilized, it is required to suppress the generation and growth of skull. If the amplitude of oscillation is kept large so as to achieve the above purpose, there is the likelihood of the edge dam being damaged by excessive oscillation during the casting. Further, if the amplitude of oscillation is large for a comparatively long time, abnormal wear of the edge dam is caused, thus deteriorating the quality of the edges of the casting strip, or reducing the lifetime of the edge dam refractory. Hence, after the initial stage of the casting has passed, at the stage in which most of skull that had been at the initial stage of the casting has been removed, the amplitude of oscillation must be maintained to be as small as possible within a range that can prevent damage or abnormal wear of the edge dam and mitigate the generation and growth of skull. To achieve this, after the initial stage of casting, the amplitude of oscillation must be maintained within a range from 200 μm to 600 μm because if the amplitude of oscillation is less than 200 μm, the generation and growth of skull cannot be effectively suppressed, and if the amplitude of oscillation is greater than 600 μm, there may be abnormal wear of the edge dam.
At a final stage of the casting, the temperature of the molten steel decreases, thus increasing the possibility of skull generation and growth. Therefore, it is required to increase the amplitude of oscillation to suppress the generation and growth of skull. Given this, at the final stage of the casting, it is preferable for the amplitude of oscillation to be maintained within a range from 400 μm to 700 μm. The reason for this is because if the amplitude of oscillation is less than 400 μm, it is difficult to suppress the generation of skull which may be caused by a decrease in the temperature of the molten steel, and if the amplitude of oscillation is greater than 700 μm, a lower portion of the edge dam is worn, causing damage, such as a deep nick, to the edge.
As stated above, if the amplitude of oscillation is increased, there is a likelihood of the edge dam being damaged. Given this, as shown in
Actually, in the results of the most general three kinds of tests on the extent of mixture of skull as functions of the ON/OFF status of the oscillation of the edge dam and the oscillation method, as shown
Eventually, in the method of controlling the horizontal oscillation of the edge dam according to the present invention, the servo valve and the hydraulic cylinder horizontally oscillate the edge dam refractory in accordance with an oscillation waveform having a predetermined amplitude and oscillation frequency that is applied thereto from the control unit, thus eliminating the dead zone 200 which is a portion that does not oscillate. Further, depending on casting conditions, the amplitude, oscillation frequency and the oscillation waveform are variably controlled. Therefore, skull that has been formed at the initial stage of the casting can be rapidly removed, the generation and growth of skull can be suppressed, and damage to the casting roll or edge dam can be prevented, so that the stability of casting can be ensured and the quality of a produced casting strip can be improved.
Number | Date | Country | Kind |
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10-2009-0131829 | Dec 2009 | KR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/KR2010/009005 | 12/16/2010 | WO | 00 | 6/5/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/081332 | 7/7/2011 | WO | A |
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Number | Date | Country | |
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20120235314 A1 | Sep 2012 | US |