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Numerical modeling of earthen dam breach due to piping failure 被引量:8

Numerical modeling of earthen dam breach due to piping failure
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摘要 Based on model tests of earthen dam breach due to piping failure, a numerical model was developed.A key difference from previous research is the assumption that the cross-section of the pipe channel is an arch, with a rectangle at the bottom and a semicircle at the top before the collapse of the pipe roof, rather than a rectangular or circular cross-section.A shear stress-based erosion rate formula was utilized, and the arched pipe tunnel was assumed to enlarge along its length and width until the overlying soil could no longer maintain stability.Orifice flow and open channel flow were adopted to calculate the breach flow discharge for pressure and free surface flows, respectively.The collapse of the pipe roof was determined by comparing the weight of the overlying soil and the cohesion of the soil on the two sidewalls of the pipe.After the collapse, overtopping failure dominated, and the limit equilibrium method was adopted to estimate the stability of the breach slope when the water flow overtopped.In addition, incomplete and base erosion, as well as one-and two-sided breaches were taken into account.The USDAARS-HERU model test P1, with detailed measured data, was used as a case study, and two artificially filled earthen dam failure cases were studied to verify the model.Feedback analysis demonstrates that the proposed model can provide satisfactory results for modeling the breach flow discharge and breach development process.Sensitivity analysis shows that the soil erodibility and initial piping position significantly affect the prediction of the breach flow discharge.Furthermore, a comparison with a well-known numerical model shows that the proposed model performs better than the NWS BREACH model. Based on model tests of earthen dam breach due to piping failure,a numerical model was developed.A key difference from previous research is the assumption that the cross-section of the pipe channel is an arch,with a rectangle at the bottom and a semicircle at the top before the collapse of the pipe roof,rather than a rectangular or circular cross-section.A shear stress-based erosion rate formula was utilized,and the arched pipe tunnel was assumed to enlarge along its length and width until the overlying soil could no longer maintain stability.Orifice flow and open channel flow were adopted to calculate the breach flow discharge for pressure and free surface flows,respectively.The collapse of the pipe roof was determined by comparing the weight of the overlying soil and the cohesion of the soil on the two sidewalls of the pipe.After the collapse,overtopping failure dominated,and the limit equilibrium method was adopted to estimate the stability of the breach slope when the water flow overtopped.In addition,incomplete and base erosion,as well as one-and two-sided breaches were taken into account.The USDAARS-HERU model test P1,with detailed measured data,was used as a case study,and two artificially filled earthen dam failure cases were studied to verify the model.Feedback analysis demonstrates that the proposed model can provide satisfactory results for modeling the breach flow discharge and breach development process.Sensitivity analysis shows that the soil erodibility and initial piping position significantly affect the prediction of the breach flow discharge.Furthermore,a comparison with a well-known numerical model shows that the proposed model performs better than the NWS BREACH model.
出处 《Water Science and Engineering》 EI CAS CSCD 2019年第3期169-178,共10页 水科学与水工程(英文版)
基金 supported by the National Key Research and Development Program of China(Grant No.2017YFC0404805) the National Natural Science Foundation of China(Grants No.51779153 and 51539006) the Central Public-interest Scientific Institution Basal Research Fund(Grant No.Y717012) the Natural Science Foundation of Jiangsu Province(Grant No.BK20161121)
关键词 Earthen DAM PIPING FAILURE OVERTOPPING FAILURE Breach FLOW NUMERICAL modeling Sensitivity analysis Earthen dam Piping failure Overtopping failure Breach flow Numerical modeling Sensitivity analysis
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