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| Parameters determination of coal-rock HJC model and research on blasting characteristics by liquid CO2 |
| ZHANG Jiafan,GAO Zhuang,CHENG Shufan,ZHANG Huimei |
| (College of Science,Xi'an University of Science and Technology,Xi'an,Shaanxi 710054,China) |
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Abstract Holmquist-Johnson-Cook(HJC) constitutive model is widely used in numerical simulation of impact explosion engineering. In order to explore reasonable model parameters for coal-rock mass,furthermore to determine actual effect and related cracking range by liquid CO2 blasting,this article is relied on CO2 blasting project in a mining area in Shenmu of northern Shaanxi,based on static mechanical characteristics test and a split Hopkinson pressure bar(SHPB) impact test,the basic physical and mechanical parameters of coal-rock are obtained. By orthogonal experiment and numerical simulation methods,the entire process of the SHPB impact compression test is reproduced on LS-DYNA3D platform. According to Person correlation coefficient,this research judges the fitting degree between experiment and simulated strain signal,then backward deduces the main sensitive parameter B and N of HJC model. Introducing *MAT-ADD-EROSION failure condition and using compressive and tensile failure criteria,it truly reproduces the whole process of crack initiation,expansion and penetration,until a fissure zone is formed for CO2 blasting,which effectively simulates the fragmentation characteristics of blasting rock mass,and reflects the geometric nonlinear characteristics of rock mass in working face. Moreover,this study analyses crack propagation characteristics and blasting effect of CO2 blasting compared with traditional explosive blasting. Subsequently,the stress wave attenuation laws are analyzed,which give the crushing and fissure range. The results show that the process of stress wave attenuation and the energy release slopes relatively gently during liquid CO2 blasting,and the energy mainly produces elongated cracks in fissure area,which is much larger than the traditional explosive blasting. Under the same equivalence,comparing with traditional explosive blasting case,the effective range of liquid CO2 blasting is larger,meanwhile the crushing range is decreased,and the cracking range is increased. Correspondingly,coal rock is felled apart into massive fragmentations. The research results are applied to the industrial test of CO2 blasting in this mine,considering the simultaneous action of four crack devices,blasting holes are set in a square shape with a spacing of 0.7 meters which determined by calculating. The test results show that the actual blasting effect is good,lump coal rate is increases by 38.5% compared with tradition case.
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| [1] 刘国军,鲜学福,周军平,等. 超临界CO2致裂页岩实验研究[J]. 煤炭学报,2017,42(3):694–701.(LIU Guojun,XIAN Xuefu,ZHOU Junping,et al. Experimental study on the supercritical CO2 fracturing of shale[J]. Journal of China Coal Society,2017,42(3):694–701.(in Chinese))
[2] 王海柱,石鲁杰,李根生,等. 超临界CO2岩石致裂机制分析[J]. 岩土力学,2018,39(10):3 589–3 596.(WANG Haizhu,SHI Lujie,LI Gensheng,et al. Analysis of mechanisms of supercritical CO2 fracturing[J]. Rock and Soil Mechanics,2018,39(10):3 589–3 596. (in Chinese))
[3] 张东明,白 鑫,尹光志,等. 低渗煤层液态CO2相变射孔破岩及裂隙扩展力学机理[J]. 煤炭学报,2018,43(11):208–222.(ZHANG Dongming,BAI Xin,YIN Guangzhi,et al. Mechanism of breaking and fracture expansion of liquid CO2 phase change jet fracturing in low-permeability coal seam[J]. Journal of China Coal Society,2018,43(11):208–222.(in Chinese))
[4] 刘 杰,冯世国,李天斌,等. 冲击荷载作用下岩石动态响应预测研究[J]. 岩土工程学报,2018,40(11):2 022–2 030.(LIU Jie,FENG Shiguo,LI Tianfu,et al. Prediction of dynamic response of rock under impact loads[J]. Chinese Journal of Geotechnical Engineering,2018,40(11):2 022–2 030.(in Chinese))
[5] 李晓锋,李海波,刘 凯,等. 冲击荷载作用下岩石动态力学特性及破裂特征研究[J]. 岩石力学与工程学报,2017,36(10):2 393–2 405.(LI Xiaofeng,LI Haibo,LIU Kai,et al. Dynamic properties and fracture characteristics of rocks subject to impact loading[J]. Chinese Journal of Rock Mechanics and Engineering,2017,36(10):2 393–2 405.(in Chinese))
[6] QI C,WANG M,BAI J,et al. Mechanism underlying dynamic size effect on rock mass strength[J]. International Journal of Impact Engineering,2014,68(3):1–7.
[7] LIU H Y,LV S R,ZHANG L M,et al. A dynamic damage constitutive model for a rock mass with persistent joints[J]. International Journal of Rock Mechanics and Mining Sciences,2015,75:132–139.
[8] TAYLOR L M,CHEN E P,KUSZMAUL J S. Micro-crack induced damage accumulation in brittle rock under dynamic loading[J]. Journal of Computer Methods in Applied Mechanics and Engineering,1986,55 (3):301–320.
[9] HOLMQUIST T J,JOHNSON G R,COOK W H. A computational constitutive model for concrete subjected to large strains,high strain rates and high pressure[C]// Proceedings of the 14th International Symposium on Ballistics. Qubec,Canada:[s. n.],1993:591–600.
[10] RIEDEL W,THOMA K,HIERMAIER S,et al. Penetration of reinforced concrete by BETA-B-500 numerical analysis using a new macroscopic concrete model for hydrocodes[C]// Proceedings of the 9th International Symposium on Interaction of the Effects of Munitions with Structure. Berlin:[s. n.],1999:315–322.
[11] 曹 峰,凌同华,李 洁,等. 循环爆破荷载作用下小净距隧道中夹岩的累积损伤特征分析[J]. 振动与冲击,2018,37(23):141–148.(CAO Feng,LIN Tonghua,LI Jie,et al. Cumulative damage feature analysis for shared rock in a neighborhood tunnel under cyclic explosion loading[J]. Journal of Vibration and Shock,2018,37(23):141–148.(in Chinese))
[12] 胡学龙,璩世杰,李克庆. 基于统一强度理论的岩石弹塑性损伤模型研究[J]. 中国矿业大学学报,2019,48(2):305–312.(HU Xuelong,QU Shijie,LI Keqing. Study of rock elastoplastic constitutive damage model based on the unified strength theory[J]. Journal of China University of Mining and Technology,2019,48(2):305–312.(in Chinese))
[13] 张凤国,李恩征. 混凝土撞击损伤模型参数的确定方法[J]. 弹道学报,2001,13(4):12–16.(ZHANG Fengguo,LI Enzheng. Modeling and dynamic analysis of nitrogen launching system[J]. Journal of Ballistics,2001,13(4):12–16.(in Chinese))
[14] 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-johnson-cook consitiutive model parameters of rock[J]. Engineering Mechanics,2014,31(3):197–204.(in Chinese))
[15] LARSON D B,ANDERSON G D. Plane shock wave studies of porous geological media[J]. Journal of Geophysical Research,1979,84(B9):4 592–4 600.
[16] 石祥超,陶祖文,孟英峰,等. 致密砂岩Johnson-Holmquist损伤本构模型参数求取及验证[J]. 岩石力学与工程学报,2015,38(增2):3 750–3 758.(SHI Xiangchao,TAO Zuwen,MENG Yingfeng, et al. Calculation and verification for johnson-holmquist constitutive model parameters of tight sandstone[J]. Chinese Journal of Rock Mechanics and Engineering,2015,38(Supp.2):3 750–3 758.(in Chinese))
[17] 闻 磊,李夕兵,吴秋红,等. 花岗斑岩Holmquist-Johnson-Cook本构模型参数研究[J]. 计算力学学报,2016,33(5):725–731. (WEN Lei,LI Xibing,WU Qiuhong,et al. Study on parameters of holmquist-johnson-cook model for granite porphyry[J]. Chinese Journal of Computational Mechanics,2016,33(5):725–731.(in Chinese))
[18] 李成武,王金贵,解北京,等. 基于HJC本构模型的煤岩SHPB实验数值模拟[J]. 采矿与安全工程学报,2016,33(1):158–164.(LI Chengwu,WANG Jingui,XIE Beijing,et al. Numerical simulation of SHPB tests for coal by using HJC model[J]. Journal of Mining and Safety Engineering,2016,33(1):158–164.(in Chinese))
[19] 宋 力,胡时胜. SHPB数据处理中的二波法与三波法[J]. 爆炸与冲击,2005,25(4):368–373.(SONG Li,HU Shisheng. Two-wave and three-wave method in SHPB data processing[J]. Explosion and Shock Waves,2005,25(4):368–373.(in Chinese))
[20] 陈建林,李旭东,刘凯欣. 素混凝土本构模型参数的实验研究[J]. 北京大学学报:自然科学版,2008,44(5):689–694.(CHEN Jianlin,LI Xudong,LIU Kaixin. Experimental research on parameters of constitutive model for a cement mortar[J]. Acta Scientiarum Naturalium Universitatis Pekinensis,2008,44(5):689–694.(in Chinese))
[21] 刘瑞江,张业旺,闻崇炜,等. 正交试验设计和分析方法研究[J]. 实验技术与管理,2010,27(9):52–55.(LIU Ruijiang,ZHANG Yewang,WEN Chongwei,et al. Study on the design and analysis methods of orthogonal experiment[J]. Experimental Technology and Management,2010,27(9):52–55.(in Chinese))
[22] 董庆祥,王兆丰,韩亚北,等. 液态CO2相变致裂的TNT当量研究[J]. 中国安全科学学报,2014,24(11):84–88.(DONG Qinxiang,WANG Zhaofeng,HAN Yabei,et al. Research on TNT equivalent of liquid CO2 phase-transition fracturing[J]. China Safety Science Journal,2014,24(11):84–88.(in Chinese)) |
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2021, Vol. 40 
