Nonlinear evolution of rock movement in ultra-large-scale block caving mining

doi:10.16265/j.cnki.issn1003-3033.2025.07.0058

Abstract

Abstract:

In order to enhance mine safety management, a ultra-large refined three-dimensional numerical model for an oversea ultra-large-scale block caving mine was established. The spatiotemporal evolution patterns of underground cave bodies and surface rock movement throughout the mining were simulated using FLAC^3D, and the safety of surface infrastructures was evaluated according to composite surface subsidence criteria. Results demonstrate that caving morphology development exhibits discontinuous, intermittent and leapfrogging characteristics. A definitive transition threshold exists in propagation modes - vertical caving dominates prior to surface breakthrough, shifting to lateral propagation afterwards. Caving crater expansion follows bimodal evolutionary patterns: initial rapid large-scale caving due to weak superficial strata, transitioning to velocity attenuation in mid-late stages through debris infill, ultimately forming cave zones with high spatial correlation to undercut areas and location. Evaluations based on composite subsidence criteria confirm that critical surface infrastructures remain outside the subsidence limit throughout the mining. Furthermore, the "priority exceedance" characteristic of curvature parameters proves effective as an early warning indicator for surface breakthrough.

Key words: ultra-large-scale, block caving, surface subsidence criteria, nonlinear evolution, cave zone, subsidence limit

CLC Number:

HUANG Mingqing, LI Zhaolan, LIU Qingling, SHEN Yiling, GUO Xiaoqiang. Nonlinear evolution of rock movement in ultra-large-scale block caving mining[J]. China Safety Science Journal, 2025, 35(7): 67-74.

Figures/Tables 11

Fig.1

Fig.2

Table 1

Fig.3

Table 2

Fig.4

Fig.5

Fig.6

Fig.7

Fig.8

Fig.9

References 20

[1]	JIN Changyu, LI Guang, LIU Huiyang, et al. Development of directional hydraulic fracturing technology based on guided grooves and its application to block caving mining[J]. Mining, Metallurgy & Exploration, 2024, 41:3211-3223.
[2]	GE Qifa, FAN Wenlu, ZHU Weigen, et al. Application and research of block caving in Pulang copper mine[J]. IOP Conference Series: Earth and Environmental Science, 2018, 108(4): DOI:10.1088/1755-1315/108/4/042006.
[3]	MORALES K, SUORINENI F, HEBBLEWHITE B. Orebody cavability prediction challenges in block caving mining:a review[J]. Bulletin of Engineering Geology and the Environment, 2024, 83(1): DOI:10.1007/s10064-023-03516-6.
[4]	XIA Kaizong, CHEN Congxin, LIU Xuanting, et al. Ground collapse and caving mechanisms in strata overlying sublevel caving mines: a case study[J]. Bulletin of Engineering Geology and the Environment, 2024, 83(1): DOI:10.1007/s10064-023-03529-1.
[5]	MA Kai, YANG Tianhong, ZHAO Yong, et al. Mechanical model for calculating surface movement related to open-pit and underground caving combined mining[J]. Minerals, 2023, 13(4):DOI:10.3390/min13040520.
[6]	BARYAKH A, FEDOSEEV A, LOBANOV S. Deformations and fracture of rock strata during deep level potash mining[J]. Procedia Structural Integrity, 2021, 32:109-116.
[7]	CUMMING-POTVIN D, WESSELOO J, JACOBSZ S, et al. Physical modelling of cave breakthrough into an overlying cave[C]. MassMin 2020: Proceedings of the Eighth International Conference & Exhibition on Mass Mining, 2020:478-488.
[8]	陆玉根, 孙国权, 徐刚, 等. 崩落法开采岩移及塌陷规律相似材料模拟试验[J]. 金属矿山, 2015(增1):1-6.
	LU Yugen, SUN Guoquan, XU Gang, et al. Similar material simulation experiment of the law of rock movement and collapse[J]. Metal Mine, 2015(S1):1-6.
[9]	ÁLVAREZ C, GÓMEZ P, ORREGO C, et al. Calibration of structurally controlled caving propagation using 3DEC:the esmeralda block 1 case study[C]. Proceedings of the Eighth International Conference & Exhibition on Mass Mining, 2020: 418-427.
[10]	RAFIEE R, ATAEI M, KHALOOKAKAIE R, et al. Numerical modeling of influence parameters in cavabililty of rock mass in block caving mines[J]. International Journal of Rock Mechanics and Mining Sciences, 2018, 105:22-27.
[11]	郭鑫, 鲁义, 施式亮, 等. 高流态注浆材料膨胀及蠕变特性试验研究[J]. 中国安全科学学报, 2024, 34(10):143-151. doi: 10.16265/j.cnki.issn1003-3033.2024.10.0636
	GUO Xin, LU Yi, SHI Shiliang, et al. Experimental study on expansion and creep characteristics of high flow sealed grouting material[J]. China Safety Science Journal, 2024, 34(10):143-151. doi: 10.16265/j.cnki.issn1003-3033.2024.10.0636
[12]	刘迪, 杨辉, 卢才武, 等. 基于MISSA-CNN-BiLSTM模型的尾矿坝位移预测[J]. 中国安全科学学报, 2024, 34(9):145-154. doi: 10.16265/j.cnki.issn1003-3033.2024.09.1091
	LIU Di, YANG Hui, LU Caiwu, et al. Prediction of displacement of tailings dams based on MISSA-CNN-BiLSTM model[J]. China Safety Science Journal, 2024, 34(9):145-154. doi: 10.16265/j.cnki.issn1003-3033.2024.09.1091
[13]	SJÖLANDER M, JONSSON L, FIGUEIREDO B, et al. Analysis of caving and ground deformations in Malmberget using a coupled CAVESIM-FLAC^3D model[C]. Proceedings of the Fifth International Conference on Block and Sublevel Caving, 2022: 781-796.
[14]	FUENZALIDA M, ORREGO C, GHAZVINIAN E, et al. Application of rock mass strength scale effect at Cadia East mine[C]. Proceedings of the Fifth International Conference on Block and Sublevel Caving, 2022: 951-962.
[15]	HEBERT Y, SHARROCK G. Three-dimensional simulation of cave initiation, propagation and surface subsidence using a coupled finite difference-cellular automata solution[C]. Proceedings of the Fourth International Symposium on Block and Sublevel Caving, 2018: 151-166.
[16]	WANG Feifei, REN Qingyang, JIANG Xueliang, et al. Engineering geology and subsidence mechanism of a mountain surface in the Daliang lead-zinc ore mine in China[J]. Bulletin of Engineering Geology and the Environment, 2022, 81(11): DOI:10.1007/s10064-022-02983-7.
[17]	GARZA-CRUZ T, GHAZVINIAN E, FUENZALIDA M, et al. Surface subsidence analysis associated with caving at La Encantada Silver mine[C]. Proceedings of the Fifth International Conference on Block and Sublevel Caving, 2022: 733-748.
[18]	王伟澄, 黄明清, 刘青灵, 等. 自然崩落法拉底参数对矿岩初始与持续崩落的影响机制[J]. 金属矿山, 2024(8):1-9.
	WANG Weicheng, HUANG Mingqing, LIU Qingling, et al. Mechanism of initial caving and propagative caving induced by undercutting parameters of block caving method[J]. Metal Mine, 2024(8):1-9.
[19]	SHI Yungang, WANG Huaijian, TAN Xin, et al. A stability analysis of an abandoned gypsum mine based on numerical simulation using the itasca model for advanced strain softening constitutive model[J]. Applied Sciences, 2023, 13(23): DOI: 10.3390/app132312570.
[20]	黄明清, 张厚缘, 郭晓强, 等. 硬岩矿体自然崩落过程成拱特征及其边界弱化[J]. 金属矿山, 2024(5): 84-91.
	HUANG Mingqing, ZHANG Houyuan, GUO Xiaoqiang, et al. Arching characteristics and boundary weakening in block caving of hard orebodies[J]. Metal Mine, 2024(5):84-91.

岩性	容重γ/ (kN·m^-3)	单轴抗拉强度 σ_t/MPa	地质强度指标	Hoek- Brown 常数m_i	弹性模量 E_i/GPa
砾岩	25.63	0.070	47	20.394	24.30
矿岩	28.76	0.832	65	9.543	48.10
安山岩	26.41	0.489	67	21.697	46.23
泥岩	27.38	0.053	30	6.000	29.68
断层	25.63	0.090	41	6.000	2.49
废石堆	18.82	0.000 1	40	19	4.88

数值模拟步骤	生产进度	累计拉底面积/m²
1	基建	30 000
2	基建结束后第1年	60 000
3	基建结束后第2年	90 000
4	基建结束后第3年	120 000
5	基建结束后第4年	144 000
6	基建结束后第5年	144 000
7	基建结束后第6年	168 000
8	基建结束后第7年	193 500
9	基建结束后第8年	220 500
10	基建结束后第9年	241 500
11	基建结束后第10年	262 500
12	基建结束后第11年	283 500
13	基建结束后第12年	307 500
14	基建结束后第13年	331 500
15	基建结束后第14年	355 500
16	基建结束后第15年	379 500
17	基建结束后第16年	409 500
18	基建结束后第17年	439 500
19	基建结束后第18年	469 500
20	基建结束后第19年	491 700