A composite rock mass quality evaluation model based on G1-CV-TOPSIS and its application

doi:10.16265/j.cnki.issn1003-3033.2025.S2.0016

Abstract

Abstract:

To address the issues of strong subjectivity in weight allocation and the limitations of single-weighting methods in traditional rock mass evaluation, a composite rock mass quality assessment model was developed. This model integrated the G1 method, the CV method, and the TOPSIS. In this framework, subjective weights were assigned to evaluation indicators using the G1 method based on their importance ranking. Concurrently, objective weights were calculated by the CV method according to the dispersion of the data. The Euclidean distance was then applied to optimize and integrate these subjective and objective weights, resulting in a comprehensive weight index. Based on this integrated index, the TOPSIS method was used to calculate the distance between each sample and the positive/negative ideal solutions. The quantitative ranking and classification of rock mass quality were achieved by assessing the relative proximity. When applied to an open-pit mine in Sichuan Province and compared with four other evaluation methods, the rock mass quality in the surveyed area was primarily classified as Grade Ⅱ by the G1-CV-TOPSIS model, with localized areas identified as Grade Ⅲ and Grade Ⅴ. It is demonstrated through comparison that the proposed G1-CV-TOPSIS model effectively integrates subjective experience with objective data, thereby significantly improving the accuracy and scientific rigor of rock mass quality assessment.

Key words: method of order relation (G1), coefficient of variation (CV), technique for order preference by similarity to an ideal solution (TOPSIS), rock mass evaluation, combined weighting

CLC Number:

TD315岩石力学性质试验

XIANG Ping, WU Panzhi, YONG Chaoyuan, QIN Lujun, WANG Ke, YUAN Yunxing. A composite rock mass quality evaluation model based on G1-CV-TOPSIS and its application[J]. China Safety Science Journal, 2025, 35(S2): 73-79.

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References 20

[1]	谢学斌, 闫泽正. 加权距离的D-S证据理论在岩体评价中的应用[J]. 中国安全科学学报, 2016, 26(6): 135-140.
	XIE Xuebin, YAN Zezheng. Application of weighted distance based D-S theory of evidence in evaluating rock quality[J]. China Safety Science Journal, 2016, 26(6): 135-140.
[2]	王瑞红, 李建林, 蒋昱州, 等. 考虑岩体开挖卸荷边坡岩体质量评价[J]. 岩土力学, 2008, 29(10): 2 741-2 746.
	WANG Ruihong, LI Jianlin, JIANG Yuzhou, et al. Quality evaluation of unloaded slope rock mass[J]. Rock and Soil Mechanics, 2008, 29(10): 2 741-2 746.
[3]	苏龙, 刘爱华. 考虑岩体质量分级的地下采场稳定性研究[J]. 中国安全科学学报, 2014, 24(12): 9-15.
	SU Long, LIU Aihua. Study on underground mining stope stability based onquality classification of rock masses[J]. China Safety Science Journal, 2014, 24(12): 9-15.
[4]	陈赞成, 余斌, 解联库, 等. 大型地下铁矿工程地质调查与岩体质量评价[J]. 中国安全生产科学技术, 2013, 9(6): 63-68.
	CHEN Zancheng, YU Bin, XIE Lianku, et al. Engineering geological investigation and evaluation of rockmass quality in large underground iron mine[J]. Journal of Safety Science and Technology, 2013, 9(6): 63-68.
[5]	张良喜, 韩刚. 秀水河铁矿露天采场边坡岩体质量评价[J]. 四川地质学报, 2023, 43(4): 674-682.
	ZHANG Liangxi, HAN Gang. Quality evaluation of slope rock mass in the Xiushuihe iron mine open pit[J]. Acta Geologica Sichuan, 2023, 43(4): 674-682.
[6]	尹会永, 赵涵, 徐琳, 等. 岩体质量分级的改进模糊综合评价法[J]. 金属矿山, 2020(7): 53-58.
	YIN Huiyong, ZHAO Han, XU Lin, et al. Classification of rock mass in mine based on improved fuzzy comprehensive evaluation method[J]. Metal Mine, 2020(7): 53-58.
[7]	葛伟杰, 刘艳章, 秦绍兵, 等. 考虑采动影响的ACI-RMR法矿山巷道围岩质量分级研究[J]. 有色金属工程, 2023, 13(9): 121-129.
	GE Weijie, LIU Yanzhang, QIN Shaobing, et al. Quality classification for roadway surrounding rock by ACI-RMR method considering the influence of mining[J]. Nonferrous Metals Engineering, 2023, 13(9): 121-129.
[8]	周晏渔, 豆龙, 林卫星, 等. 基于IAHP-GRA和多维联系云的岩体质量评价和应用[J]. 矿业研究与开发, 2024, 44(8): 173-181.
	ZHOU Yanyu, DOU Long, LIN Weixing, et al. Rock mass quality evaluation and application based on IAHP-GRA and multidimensional connection cloud[J]. Mining Research and Development, 2024, 44(8): 173-181.
[9]	单梁, 刘艳章, 孙明伟, 等. 基于EWGR-DSTE的巷道围岩质量分级可信度研究[J]. 金属矿山, 2023(10): 53-59.
	SHAN Liang, LIU Yanzhang, SUN Mingwei, et al. Credibility study of roadway surrounding rock quality classification based on EWGR-DSTE[J]. Metal Mine, 2023(10): 53-59.
[10]	蒋英礼, 崔杰, 张兰峰, 等. 基于权重融合-改进可拓云模型的岩体质量评价方法与应用[J]. 矿业研究与开发, 2023, 43(8): 84-90.
	JIANG Yingli, CUI Jie, ZHANG Lanfeng, et al. Rock mass quality evaluation method and application based on weight fusion-improved extension cloud model[J]. Mining Research and Development, 2023, 43(8): 84-90.
[11]	王茹, 郑雨洁, 梁琼, 等. 基于博弈论-价值模型的设计方案决策[J]. 大连理工大学学报, 2025, 65(4): 391-397.
	WANG Ru, ZHENG Yujie, LIANG Qiong, et al. Design scheme decision-making based on game theory-value model[J]. Journal of Dalian University of Technology, 2025, 65(4): 391-397.
[12]	赵彬. 边坡稳定性评价的组合赋权博弈论云化物元模型[J]. 矿业研究与开发, 2022, 42(6): 60-67.
	ZHAO Bin. Combination weighting game theory cloud matter-element model for slope stability evaluation[J]. Mining Research and Development, 2022, 42(6): 60-67.
[13]	吴峰, 张海云, 方前程. 基于岩体质量分级的地下矿山巷道支护设计[J]. 矿业研究与开发, 2021, 41(6): 84-88.
	WU Feng, ZHANG Haiyun, FANG Qiancheng. Support design for underground mine roadways based on rock mass classification[J]. Mining Research and Development, 2021, 41(6): 84-88.
[14]	黄旭, 叶聪林, 陈家钊, 等. 基于G1法和云化物元模型的充填体稳定性评价[J]. 矿业研究与开发, 2024, 44(1): 13-18.
	HUANG Xu, YE Conglin, CHEN Jiazhao, et al. Stability evaluation of backfill based on G1 method and cloud matter-element model[J]. Mining Research and Development, 2024, 44(1): 13-18.
[15]	严嘉伦, 林俊光, 楼可炜, 等. 基于AHP-变异系数法的楼宇型综合能源系统评价体系[J]. 热力发电, 2019, 48(12): 25-30.
	YAN Jialun, LIN Junguang, LOU Kewei, et al. Evaluation system for building integrated energy systembased on AHP-CV method[J]. Thermal Power Generation, 2019, 48(12): 25-30.
[16]	冯书顺, 武强. 基于AHP-变异系数法综合赋权的含水层富水性研究[J]. 煤炭工程, 2016, 48(增2): 138-140.
	FENG Shushun, WU Qiang. Research on water-richness of aquifer using comprehensive weightmethod based on AHP and variation coefficient[J]. Coal Engineering, 2016, 48(S2): 138-140.
[17]	邱梅, 施龙青, 滕超, 等. 基于灰色关联-FDAHP法与物探成果相结合的奥灰富水性评价[J]. 岩石力学与工程学报, 2016, 35(增1): 3 203-3 213.
	QIU Mei, SHI Longqing, TENG Chao, et al. Water-richness evaluation of ordovician limestone based on grey correlationanalysis,FDAHP and geophysical exploration[J]. Chinese Journal of Rock Mechanics and Engineering, 2016, 35(S1): 3 203-3 213.
[18]	吴灿, 江科, 刘立辉, 等. 基于AHP-TOPSIS评判模型的尾砂浓密装置优选[J]. 矿业研究与开发, 2025, 45(5): 79-85.
	WU Can, JIANG Ke, LIU Lihui, et al. Optimal selection of tailings thickening devices based on the AHP-TOPSIS evaluation model[J]. Mining Research and Development, 2025, 45(5): 79-85.
[19]	覃美满, 寇向宇, 鄢德波, 等. 基于组合赋权-TOPSIS的地下矿山安全风险评价研究[J]. 矿冶工程, 2025, 45(1): 35-40.
	QIN Meiman, KOU Xiangyu, YAN Debo, et al. Safety risk assessment for underground mines based on combination weighting-TOPSIS[J]. Mining and Metallurgical Engineering, 2025, 45(1): 35-40.
[20]	徐先锋, 邢鹏飞, 王岁红, 等. 基于博弈论G1-EW-TOPSIS法的岩体质量评价和应用[J]. 黄金科学技术, 2022, 30(5): 704-712. doi: 10.11872/j.issn.1005-2518.2022.05.148
	XU Xianfeng, XING Pengfei, WANG Suihong, et al. Rock mass quality evaluation and application based on game theory G1-EW-TOPSIS method[J]. Gold Science and Technology, 2022, 30(5): 704-712. doi: 10.11872/j.issn.1005-2518.2022.05.148

岩石质量等级	X₁/%	X₂/MPa	X₃	X₄	X₅/[L·min^-1·(10 m)^-1]
Ⅰ级	90~100	120~200	0.75~1.00	0.8~1.0	0~5
Ⅱ级	75~90	60~120	0.45~0.75	0.6~0.8	5~10
Ⅲ级	50~75	30~60	0.30~0.45	0.4~0.6	10~25
Ⅳ级	25~50	15~30	0.20~0.30	0.2~0.4	25~125
Ⅴ级	0~25	0~15	0.00~0.20	0~0.2	125~300
指标属性	效益型	效益型	效益型	效益型	成本型

r_k	含义
1.0	指标x_k_-1与指标x_k具有同样重要性
1.2	评价指标x_k_-1的重要程度与评价指标x_k相比稍微重要
1.4	评价指标x_k_-1的重要程度与评价指标x_k相比明显重要
1.6	评价指标x_k_-1的重要程度与评价指标x_k相比非常重要
1.8	评价指标x_k_-1的重要程度与评价指标x_k相比极度重要

测点	指标
测点	X₁/%	X₂/MPa	X₃	X₄	X₅/[L·min^-1·(10 m)^-1]
1	12	8.4	0.18	0.15	28.6
2	46	75.7	0.29	0.25	22.8
3	65	107.5	0.59	0.47	17.5
4	77	110	0.69	0.56	12.6
5	86	101.1	0.63	0.53	15.2

专家编号	指标顺序	r₂	r₃	r₄	r₅	ω_min
1	X₂>X₃>X₄>X₁>X₅	1.6	1.5	1.4	1.3	0.09
2	X₂>X₄>X₁>X₃>X₅	1.7	1	1.2	1.1	0.14
3	X₂>X₃>X₅>X₄>X₁	1.7	1.2	1.3	1	0.13
4	X₃>X₂>X₄>X₅>X₁	1.6	1.4	1.2	1.1	0.12

专家编号	X₁	X₂	X₃	X₄	X₅
1	0.12	0.39	0.24	0.16	0.09
2	0.19	0.32	0.16	0.19	0.14
3	0.13	0.21	0.13	0.17	0.35
4	0.12	0.22	0.36	0.16	0.13
主观权重系数ω₁	0.14	0.29	0.22	0.17	0.18