基于光滑粒子动力学和有限元法(smoothed particle hydrodynamics-finite element method,SPH-FEM)耦合算法,建立了截断式脉冲水射流冲蚀煤岩的数值计算模型。通过对比数值模拟结果与相同工况下的实验结果,验证了该模型的有效性。在此基础上,探究了在截断式脉冲水射流冲击作用下,煤岩沿射流轴向的损伤演化过程,分析了煤岩围压、脉冲长度、脉冲间距及射流速度对煤岩冲蚀深度及速度的影响规律。结果表明:煤岩的冲蚀深度随着围压增大而减小;随着脉冲长度的增加,煤岩的冲蚀深度逐渐减小,冲蚀速度经历了先增大后减小的过程;脉冲间距对冲蚀深度的影响较小,煤岩的冲蚀速度随脉冲间距的增大呈现出线性减小的变化趋势;脉冲速度对冲蚀深度及速度影响较为显著,且随着脉冲速度的增加,冲蚀深度及速度整体呈增长趋势。
Abstract
Based on a coupling algorithm of smoothed particle hydrodynamics (SPH) and finite element method (FEM), a numerical calculation model for the erosion of coal rock by an interrupted pulse water jet was established.The feasibility of the model was verified by comparing the results of the numerical simulation with the experimental results under the same working conditions.Based on this, the axial damage evolution process of coal rock under the impact of truncated pulse water jet was explored, and the influences of coal rock confining pressure, pulse length, pulse spacing and jet velocity on the coal rock erosion depth and speed were analyzed.The results show that the greater the confining pressure of coal rock, the smaller the erosion depth and the slower the erosion speed.As a result,with the increase of pulse length, the erosion depth gradually decreases, and the erosion speed will successively undergo growth phase and reduction phase.The pulse interval has little effect on the erosion depth, and the erosion speed decreases linearly with the increase of the pulse interval.The pulse velocity has a significant effect on the erosion depth and speed, and as the pulse velocity increases, the erosion depth and speed generally increase.
关键词
截断式脉冲水射流 /
脉冲长度 /
脉冲间距 /
脉冲速度 /
煤岩冲蚀特性
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Key words
confining pressure /
pulse length /
pulse interval;pulse velocity /
coalrock breaking characteristics
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参考文献
[1]王耀锋,何学秋,王恩元,等.水力化煤层增透技术研究进展及发展趋势[J].煤炭学报,2014,39(10):1945-1955.
WANG Yaofeng, HE Xueqiu, WANG Enyuan,et al.Research progress and development tendency of the hydraulic technology for increasing the permeability of coal seams[J].Journal of China Coal Society,2014,39(10):1945-1955.
[2]王珊,高德东,郭菁莘,等.水射流在荒漠光伏电站电池清洁中的应用[J].太阳能学报,2015,36(3):556-561.
WANG Shan, GAO Dedong, GUO Jingshen, et al.Application of water for cleaning and dust on photovoltaic panel in high altitude deseart area[J].Acta Engergiae Solaris Sinica,2015,36(3):556-561.
[3]曹昊翔,张正学.水射流清洗技术应用现状及其前景[J].矿业研究与开发,2006, 26(B10):76-80.
CAO Haoxiang, ZHANG Zhengxue.State of arts of application of water jet cleaning technology and its future[J].Mining Research and Development,2006,26(B10):76-80.
[4]曹国强,张睿.高压水射流研究现状及应用[J].沈阳航空航天大学学报,2017,34(3):1-16.
CAO Guoqiang, ZHANG Rui.Review on high pressure water jet[J].Journal of Shenyang Aerospace University,2017, 34(3):1-16.
[5]BROOK N, SUMMERS D A.The penetration of rock by high-speed water jet[J].International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts,1969,6(3):249-258.
[6]VIJAY M M, REMISZ J, SHEN X.Potential of pulsed water jets for cutting and fracturing of hard rock formations[J].International Journal of Surface Mining Reclamation and Environment,1993,7(3):121-132.
[7]陆朝晖,卢义玉,Michael Hood,等.截断式脉冲射流流场结构模拟与冲蚀硬岩能力分析[J].振动与冲击,2017,36(19):180-185.
LU Zhaohui, LU Yiyu, Michael Hood,et al.Numerical simulation and analysis on flow field structure and hard rock erosion potential of disc-slotted pulse water jet[J].Journal of Vibration and Shock ,2017,36(19):180-185.
[8]LIU Y, WEI J P,REN T,et al.Experimental study of flow field structure of interrupted pulsed waterjet and breakage of hard rock[J].International Journal of Rock Mechanics and Mining Sciences,2015,78(1):253-261.
[9]XUE Y, SI H, HU Q T.The propagation of stress waves in rock impacted by a pulsed water jet[J].Powder Technology, 2017,320(1):179-190.
[10]DEHKHODAN S, HOOD M.The internal failure of rock samples subjected to pulsed water jet impacts[J].International Journal of Rock Mechanics and Mining Sciences,2014,66(1):91-96.
[11]DEHKHODAN S, HOOD M.An experimental study of surface and sub-surface damage in pulsed watezxcvbnr-jet breakage of rocks[J].International Journal of Rock Mechanics and Mining Sciences,2013,63(1):138-147.
[12]JIANG H X, LIU Z H, GAO K D.Numerical simulation on rock fragmentation by discontinuous water-jet using coupled SPH/FEA method[J].Powder Technology,2017,312(1):248-259.
[13]WANG Z A, KANG Y, WANG X C, et al.Effects of modulation position on the impact performance of mechanically modulated pulsed water jet[J].Journal of Manufacturing Processes,2020, 56(1):510-521.
[14]POLYAKOV A, ZHABIN A, AVERIN E, et al.Generalized equation for calculating rock cutting efficiency by pulsed water jets[J].Journal of Rock Mechanics and Geotechnical Engineering, 2019,11(4):867-873.
[15]DEHKHODA S.Experimental and numerical study of rock breakage by pulsed waterjet [D].Brisbane: University of Queensland,2011.
[16]宫能平,张朋朋.煤岩Holmquist-Johnson-Cook本构模型参数研究[J].安徽理工大学学报,2018,38(3):1-6.
GONG Nengping, ZHANG Pengpeng.Study on parameters of Holmquist-Johnson-Cook constitutive modle for coal[J].Journal of Anhui University of Science and Technology,2018,38(3):1-6.
[17]凌天龙,吴帅峰,刘殿书,等.砂岩Holmquist-Johnson-Cook模型参数确定[J].煤炭学报,2018,43(8):2211-2216.
LING Tianlong, WU Shuaifeng, LIU Dianshu, et al.Determination of Holmquist-Johoson-Cook model parameters for sandstone[J].Journal of China Coal Society, 2018,43(8):2211-2216.
[18]方秦,孔祥振,吴昊,等.岩石Holmquist-Johnson-Cook模型参数的确定方法[J].工程力学,2014,31(3):197-204.
FANG Qin,KONG Xiangzhen, WU Hao, et al.Determination of Holmquist-Johoson-Cook consitiutive model parameters of rock[J]. Engineering Mechanics, 2014,31(3):197-204.
[19]任根茂,吴昊,方秦,等.普通混凝土HJC本构模型参数确定[J].振动与冲击,2016,35(18):9-16.
REN Genmao, WU Hao, FANG Qin, et al.Determination of HJC consitiutive model parameters for normal strength concrete[J].Journal of Vibration and Shock,2016,35(18):9-16.
[20]汤文辉,张若棋.物态方程理论及计算概论:第2版[M].北京:高等教育出版社,2018.
[21]薛永志.高压水射流冲击下煤岩损伤诱导机制及分布特性研究[D].重庆:重庆大学,2018.
[22]刘佳亮.高压水射流冲击煤岩力学特性研究[D].重庆:重庆大学,2013.
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