出 处:《Journal of Rock Mechanics and Geotechnical Engineering》2019年第3期527-534,共8页岩石力学与岩土工程学报(英文版)
摘 要:Block and panel caving methods are increasingly used for mining of large and strong orebodies at large depths below the ground surface (>1 km). This paper focuses on the production phase of caving when the extraction level is fully developed and subjected to the weight of overlying caved material. A limit equilibrium solution for estimation of cave loads is critically reviewed and combined with existing empirical tools in order to forecast extraction level performance under cave loading. The analysis results, presented in nomogram form, suggest that the risk of severe squeezing of extraction level tunnels does not increase with cave depths below 500-1000 m due to the beneficial effects of arching. Under normal extraction ratios (ER = ~50%), severe squeezing experienced from cave loads in deep mines appears to be unlikely in all but the weakest rock masses (σcm < 5 MPa, where σcm is the rock mass global strength), even with poor draw control or low drawpoint availability. The likelihood of severe squeezing is greater when large draw areas (HR = 50-75 m, where HR is the hydraulic radius) are combined with low drawpoint availability or poor draw control and locally higher extraction ratios (ER = ~75%), even in better quality rock (σcm = 5-10 MPa). The analysis results are back-analyzed with the extraction level performance before and after a doubling production of rate and draw area at the deep ore zone (DOZ) mine in Indonesia. The extraction level conditions predicted by the nomograms correlate well with the experience at the DOZ, in which extraction level damage increases significantly over the production rampup, accompanied by a significant drop in drawpoint availability.Block and panel caving methods are increasingly used for mining of large and strong orebodies at large depths below the ground surface(>1 km). This paper focuses on the production phase of caving when the extraction level is fully developed and subjected to the weight of overlying caved material. A limit equilibrium solution for estimation of cave loads is critically reviewed and combined with existing empirical tools in order to forecast extraction level performance under cave loading. The analysis results,presented in nomogram form, suggest that the risk of severe squeezing of extraction level tunnels does not increase with cave depths below 500 e1000 m due to the beneficial effects of arching. Under normal extraction ratios(ER ? w50%), severe squeezing experienced from cave loads in deep mines appears to be unlikely in all but the weakest rock masses(sc m< 5 MPa, where s cmis the rock mass global strength),even with poor draw control or low drawpoint availability. The likelihood of severe squeezing is greater when large draw areas(HR ? 50 e75 m, where HR is the hydraulic radius) are combined with low drawpoint availability or poor draw control and locally higher extraction ratios(ER ? w75%), even in better quality rock(sc m? 5 e10 MPa). The analysis results are back-analyzed with the extraction level performance before and after a doubling production of rate and draw area at the deep ore zone(DOZ)mine in Indonesia. The extraction level conditions predicted by the nomograms correlate well with the experience at the DOZ, in which extraction level damage increases significantly over the production rampup, accompanied by a significant drop in drawpoint availability.
关 键 词:Block CAVING Panel CAVING Extraction level DRAW control SQUEEZING
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