Characterisation for spatial distribution of mining-induced stress through deep learning algorithm on SHM data

ABSTRACT The study of mining-induced stress is essential to ensure the safety production of coalmine. Due to the limited number of monitoring points and local monitoring area, the perception of structure status is insufficient. This study aims to present a deep learning (DL) model to derive the stress distribution characteristics of the overall coalmine roof. First, the framework of spatial deduction model termed as transferring convolutional neural network (TCNN) is presented, where the convolutional neural network is transferred on different datasets. According to this framework, the spatial correlations of structural mechanical responses at different heights above roadway roof are learned through numerical simulation. Subsequently, the learned results are transferred to monitoring data to derive the actual state of the overall roof. In order to verify the reliability of the TCNN model, the stress sensor is installed in the derived plane to collect the actual data, and two indicators are adopted to evaluate the reasonability of deduction results. Experimental results indicated that 92.25% features of mining-induced stress distribution are captured by the TCNN model and the deduction error is 2.037 MPa. Therefore, the presented model is reliable to obtain the overall mechanical state of the coalmine roof, and it is supposed to promote the application of DL in underground construction.

[1]  Wei-zhong Chen,et al.  Spatial deduction of mining-induced stress redistribution using an optimized non-negative matrix factorization model , 2023, Journal of Rock Mechanics and Geotechnical Engineering.

[2]  Jessica W. A. Azure,et al.  A review and case study of Artificial intelligence and Machine learning methods used for ground condition prediction ahead of tunnel boring Machines , 2022, Tunnelling and Underground Space Technology.

[3]  K. Phoon,et al.  Future of machine learning in geotechnics , 2022, Georisk: Assessment and Management of Risk for Engineered Systems and Geohazards.

[4]  Abhay M. S. Aradhya,et al.  Autonomous CNN (AutoCNN): A data-driven approach to network architecture determination , 2022, Inf. Sci..

[5]  Yaojun Wang,et al.  Identifying microseismic events using a dual-channel CNN with wavelet packets decomposition coefficients , 2022, Comput. Geosci..

[6]  Jianping Yang,et al.  Temporal–spatial coupled model for multi-prediction of tunnel structure: using deep attention-based temporal convolutional network , 2022, Journal of Civil Structural Health Monitoring.

[7]  J. Vallejos,et al.  Evaluation of the seismic rock mass response to mining and the impact of preconditioning using an epidemic-type aftershock model , 2022, International Journal of Rock Mechanics and Mining Sciences.

[8]  Shiping Zhang,et al.  Time-domain elasto-dynamic model of a transversely isotropic, layered road structure system with rigid substratum under a FWD load , 2021, Road Materials and Pavement Design.

[9]  S. Duzgun,et al.  Interpretable deep learning for roof fall hazard detection in underground mines , 2021, Journal of Rock Mechanics and Geotechnical Engineering.

[10]  Bowen Du,et al.  Development of load-temporal model to predict the further mechanical behaviors of tunnel structure under various boundary conditions , 2021 .

[11]  Bowen Du,et al.  Analysis for full face mechanical behaviors through spatial deduction model with real-time monitoring data , 2021, Structural Health Monitoring.

[12]  Chao Zhou,et al.  Characterising the resilient behaviour of pavement subgrade with construction and demolition waste under Freeze–Thaw cycles , 2021 .

[13]  Yongqin Li,et al.  Application of deep learning algorithms in geotechnical engineering: a short critical review , 2021, Artificial Intelligence Review.

[14]  A. Saeidi,et al.  An improved methodology for applying the influence function for subsidence hazard prediction , 2021, Georisk: Assessment and Management of Risk for Engineered Systems and Geohazards.

[15]  Jun-hui Zhang,et al.  Performance Evaluation of Strengthening Recycled Coarse Aggregate in Cement Stabilized Mixture Base Layer of Pavement , 2020, Advances in Civil Engineering.

[16]  Yuequan Bao,et al.  Machine learning paradigm for structural health monitoring , 2020, Structural Health Monitoring.

[17]  Luyu Wang,et al.  A structural health monitoring system for data analysis of segment joint opening in an underwater shield tunnel , 2020, Structural Health Monitoring.

[18]  Wusheng Zhao,et al.  A Fiber Bragg Grating Borehole Deformation Sensor for Stress Measurement in Coal Mine Rock , 2020, Sensors.

[19]  G. Walton,et al.  Understanding roof deformation mechanics and parametric sensitivities of coal mine entries using the discrete element method , 2020 .

[20]  Han-long Liu,et al.  Soft computing approach for prediction of surface settlement induced by earth pressure balance shield tunneling , 2020 .

[21]  Jianping Yang,et al.  The impact of various crack geometrical parameters on stress field over tip under different mixed loading conditions and inclination angles , 2019, Theoretical and Applied Fracture Mechanics.

[22]  Zhen-lei Li,et al.  Disaster-inducing mechanism in a roadway roof near the driving face and its safety-control criteria , 2019, Safety Science.

[23]  Wang Jianqiang,et al.  Quantitative determination of mining-induced discontinuous stress drop in coal , 2018, International Journal of Rock Mechanics and Mining Sciences.

[24]  Abbas Majdi,et al.  Development of a time-dependent energy model to calculate the mining-induced stress over gates and pillars , 2015 .

[25]  Praveen Patel,et al.  Assessment of Roof Fall Risk During Retreat Mining in Room and Pillar Coal Mines , 2013 .

[26]  Kourosh Shahriar,et al.  Assessment of roof fall risk during retreat mining in room and pillar coal mines , 2012 .

[27]  K. Terzaghi Theoretical Soil Mechanics , 1943 .

[28]  Wengang Zhang,et al.  Prediction of undrained shear strength using extreme gradient boosting and random forest based on Bayesian optimization , 2021 .

[29]  Zhang Yong,et al.  Mining-induced mechanical behavior in coal seams under different mining layouts , 2011 .

[30]  S. K. Palei,et al.  Logistic regression model for prediction of roof fall risks in bord and pillar workings in coal mines: an approach. , 2009 .

[31]  Yoshua Bengio,et al.  Gradient-based learning applied to document recognition , 1998, Proc. IEEE.

[32]  Hermann Kastner,et al.  Statik des Tunnel- und Stollenbaues , 1971 .

[33]  J. Kérisel,et al.  Tables for the calculation of passive pressure, active pressure and bearing capacity of foundations , 1948 .

[34]  R. Fenner,et al.  Untersuchungen zur Erkenntnis des Gebirgsdrucks , 1938 .