Resonance Analysis of Non-sinusoidal Oscillations of Continuous Casting Mold

doi:10.12068/j.issn.1005-3026.2019.09.011

Abstract

Abstract: According to the harmonic resonance theory， when the continuous casting mold is non-sinusoidal oscillation and the vibration frequency is lower than the natural frequency of the oscillator in the mold， partial harmonics with a higher amplitude can lead to resonance because the harmonic frequencies is an integer multiple of the oscillation frequency， which can directly affect the quality of slab. Using Fourier transformation， the acceleration curve of non-sinusoidal oscillation of the mold is analyzed and the relationships between harmonic amplitude and other factors， such as initial amplitude， oscillation frequency， non-sinusoidal oscillation factor and harmonic order are obtained. Then， a theoretical method of restraining resonance can be given. When the natural frequency of the oscillator in the mold is known， the harmonic order of resonance under different oscillation frequencies is determined. The harmonic amplitude corresponding to the combination of different oscillation parameters can be given by the relationship between the harmonic amplitude and the variation of each oscillation parameter. Consequently， selecting an oscillation parameter combination with a smaller harmonic amplitude can reduce the adverse effect of resonance phenomenon on the oscillator in the mold， resulting to reduce the deflection of mold， maintain liquid level stabilizing and improve the working conditions of continuous casting machine.

Key words: continuous casting, mold, non-sinusoidal oscillation, resonance, harmonic analysis

CLC Number:

TF341.6

MENG Xiang-ning， CUI Yu， LYU Ze-sheng， PENG Xiu-xing. Resonance Analysis of Non-sinusoidal Oscillations of Continuous Casting Mold[J]. Journal of Northeastern University Natural Science, 2019, 40(9): 1273-1278.

References

[1]李宪奎，朱清香，郑学然，等.结晶器非正弦振动波形及参数研究［J］.钢铁，1998，33(11):28-31.(Li Xian-kui，Zhu Qing-xiang，Zheng Xue-ran，et al.Research on non-sinusoidal oscillation waveform and parameters of mold ［J］. Iron and Steel，1998，33(11):28-31.)
[2]方一鸣，郑会成，王宏斌，等.伺服电动机驱动的连铸结晶器非正弦振动控制系统［J］.冶金自动化，2016，40(6):12-18，29.(Fang Yi-ming，Zheng Hui-cheng，Wang Hong-bin，et al.Non-sinusoidal oscillation control system of continuous casting mold driven by servo motor ［J］.Metallurgical Industry Automation，2016，40(6):12-18，29.)
[3]Sotnikov A L，Kikin A B.Theoretical foundations of the design of a lever mechanism of oscillations of the mold of a sorting machine for the continuous casting of billets ［J］.Metallurgist，2018，61(11/12):1075-1083.
[4]Park Y H，Park H.Dynamic characteristic analysis of mold oscillator including improved gear mesh model and cam profile for eccentric shaft ［J］. Journal of Mechanical Science and Technology，2014，28(11):4465-4473.
[5]仲红刚.连铸坯凝固过程热模拟研究［D］.上海:上海大学，2013.(Zhong Hong-gang.Thermal simulation study on solidification process of continuous casting billet ［D］.Shanghai:Shanghai University，2013.)
[6]Park J Y，Sohn I.Evaluating the heat transfer phenomena and the interfacial thermal resistance of mold flux using a copper disc mold simulator［J］.International Journal of Heat and Mass Transfer，2017，109:1014-1025.
[7]Arunkumar S，Rao K V S，Kumar T S P.Spatial variation of heat flux at the metal-mold interface due to mold filling effects in gravity die-casting［J］.International Journal of Heat and Mass Transfer，2008，51(11):2676-2685.
[8]Rywotycki M，Malinowski Z，Gielecki J，et al.Modelling liquid steel motion caused by electromagnetic stirring in continuous casting steel process［J］.Archives of Metallurgy and Materials，2014，59(2):487-492.
[9]Opiela M，Grajcar A.Modification of non-metallic inclusions by rare-earth elements in microalloyed steels［J］.Archives of Foundry Engineering，2012，12(2):129-134.
[10]Lipiński T，Wach A.Size of non-metallic inclusions in high-grade medium carbon steel［J］.Archives of Foundry Engineering，2014，14(4):55-60.
[11]Lamut J，Falkus J，Jurjevec B，et al.Influence of inclusions modification on nozzle clogging［J］.Archives of Metallurgy and Materials，2012，57(1):319-324.
[12]孟祥宁，朱苗勇.连铸结晶器非正弦振动波形构造及参数研究［J］.中国机械工程，2007，18(15):1779-1782.(Meng Xiang-ning，Zhu Miao-yong.Non-sinusoidal oscillation waveform conformation and parametrical research for continuous casting mold ［J］.China Mechanical Engineering，2007，18(15):1779-1782.)
[13]杨红普，李宪奎，张兴中，等.结晶器非正弦振动谐波共振［J］.机械工程学报，2007，43(7):207-212.(Yang Hong-pu，Li Xian-kui，Zhang Xing-zhong，et al.Harmonic resonance in non-sinusoidal oscillation of mold ［J］.Journal of Mechanical Engineering，2007，43(7):207-212.)
[14]吴晓明.连铸结晶器非正弦振动控制的研究［D］.秦皇岛:燕山大学，2001.(Wu Xiao-ming.Study on non-sinusoidal oscillation control used in continuous casting mold ［D］.Qinhuangdao:Yanshan University，2001.)
[15]孟祥宁，朱苗勇.高拉速连铸结晶器非正弦振动同步控制模型［J］.钢铁研究学报，2007，19(7):19-23.(Meng Xiang-ning，Zhu Miao-yong.Non-sinusoidal oscillation synchro-control model for continuous casting mold at high casting speed ［J］.Journal of Iron and Steel Research，2007，19(7):19-23.)(上接第1244页)
[8]Kips J G，Schutte A E，Vermeersch S J，et al.Comparison of central pressure estimates obtained from SphygmoCor，Omron HEM-9000AI and carotid applanation tonometry ［J］.Journal of Hypertension，2011，29(6):1115-1120.
[9]Hahn J O，Reisner A T，Asada H H.Blind identification of two-channel IIR systems with application to central cardiovascular monitoring ［J］.Journal of Dynamic Systems Measurement & Control，2009，131(5):545-553.
[10]Qiu W，Hua Y.Performance comparison of three methods for blind channel identification［C］// IEEE International Conference on Acoustics.［S.l.］:ICASSP，1996:2423-2426.
[11]Xu G，Liu H，Tong L，et al.A least-squares approach to blind channel identification ［J］.IEEE Transactions on Signal Processing， 1995，43(12):2982-2993.
[12]Hua Y B.Fast maximum likelihood for blind identification of multiple FIR channels ［C］//Proceedings of 1994 28th Asilomar Conference on Signals， Systems and Computers.Pacific Grove，1994:471-478.
[13]Patel A，Li J，Finegan B，et al.Aortic pressure estimation using blind identification approach on single input multiple output non-linear Wiener systems ［J］. IEEE Transactions on Biomedical Engineering，2018，65(6):1193-1200.
[14]Mayyala Q，Meraim K A，Zerguine A.Structure-based subspace method for multi-channel blind system identification ［J］.IEEE Signal Processing Letters，2017，24(8):1183-1187.
[15]Moulines E，Duhamel P，Cardoso J F，et al.Subspace methods for the blind identification of multichannel FIR filters ［J］.IEEE Transactions on Signal Processing， 1995，43(2):516-525.
[16]Diamantaras K I，Papadimitriou T.An efficient subspace method for the blind identification of multichannel FIR systems ［J］.IEEE Transactions on Signal Processing，2008，56(12):5833-5839.
[17]方崇智.过程辨识［M］.北京:清华大学出版社，1998.(Fang Chong-zhi.Process identification ［M］.Beijing:Tsinghua University Press，1998.)
[18]马春华.基于子空间的盲辨识和盲均衡算法［D］.西安:西安电子科技大学，2005.(Ma Chun-hua.Subspace-based methods for blind identification and blind equalization ［D］.Xi′an:Xidian University of Electronic Technology，2005.)