洪水漫顶工况下畚箕窝尾矿库溃坝数值模拟OA
Scenario-based Numerical Simulation of the Benjiwo Tailing Dam Breach under Overtopping Flood Conditions
选矿产生的尾矿仅有少量用于地下采空区充填或建材原料制备,其主体仍通过尾矿库进行堆存.随着尾矿量持续增长与堆存高程的不断抬升,尾矿库失稳风险呈几何级数递增.基于气候变化背景下极端降水事件频发的现实挑战,防洪设计标准面临严峻考验,尾矿库面临洪水漫顶引发的溃决风险提升至历史新高.为系统评估极端水文条件下洪水漫顶诱发的连锁灾害效应,构建了覆盖库区下游的三维灾变演化分析整体模型.运用有限元强度折减法开展尾矿坝稳定性数值分析,通过塑性应变云图识别潜在破坏域,继而开展多相流耦合模拟,在数字高程模型中模拟泥石流演进全过程,精确获取了砂石流行进速度、淹没范围与淹没深度等关键参数,并据此提出防控策略,提出采用阶梯式消能结构优化设计.实现了安全防控体系从被动应对向主动防御的转型升级,从源头上显著提升了应对突发灾害事故能力.
[Objective]To evaluate the potential chain disaster effects such as debris flows under ultra-standard ex-treme hydrological conditions,this study aims to establish a comprehensive catastrophe evolution analysis system and propose optimized design solutions to enhance safety control capabilities from the source,transforming the safety control of tailing dams from passive response to proactive defense.[Methods]A combination of numerical simula-tion and engineering analysis was adopted.Focusing on a typical tailing dam,we constructed an integrated 3D ca-tastrophe evolution analysis model covering the reservoir area and downstream regions.The finite element strength reduction method was used for numerical stability analysis of the tailing dam,accurately identifying potential sliding surfaces and instability failure zones through plastic strain cloud maps.Furthermore,multi-phase flow coupling sim-ulation technology was introduced to combine the process of dam failure and subsequent debris flow progression.Within a digital elevation model,the entire evolution process of post-failure debris flow in downstream valleys was dynamically simulated,quantitatively acquiring critical disaster-causing parameters such as flow velocity,inunda-tion extent,and depth.[Results](1)Regarding dam stability,under the action of extreme flood levels,the maxi-mum deformation zone identified by the finite element strength reduction method is not located at the dam body but correlates with the reservoir shape and topography.This area represents the most likely initial instability zone,high-ly susceptible to triggering local or overall landslides,thus inducing dam breaches.(2)Concerning the debris flow evolution process,simulations accurately depicted the descent paths and dynamic evolution characteristics of breached debris flow.Specifically,in terms of flow velocity,maximum flow velocities were observed in the immedi-ate downstream area of the breach,indicating strong erosive capabilities;however,velocities gradually decreased with distance and widening terrain while still posing significant threats to key residential areas and infrastructure.In terms of inundation extent and depth,significant inundation areas formed in downstream valleys,with simulation re-sults clearly delineating risk boundaries corresponding to different flood magnitudes.Maximum inundation depths reached several meters in downstream low-lying areas,directly threatening roads,buildings,and farmlands.Through coupled analysis,the full-chain disaster evolution characteristics from dam breach,debris flow formation to final deposition were identified.[Conclusion]This study proposes optimizing the existing drainage system of tailing dams with a stepped energy dissipation structure which significantly reduces the velocity and kinetic energy of de-scending floods,effectively controlling overflow erosion on the dam slope,fundamentally weakening the dynamic basis for overtopping destruction.It elevates the safety control system from traditional passive reinforcement and post-disaster rescue to a new phase of proactive intervention in water flow energy,preventing damage before it oc-curs,thereby markedly enhancing the ability of tailing dams to cope with sudden excessive floods.The research findings provide important theoretical support and technical references for risk assessment,emergency planning,and engineering renovation and expansion of similar tailing dams.
陈星
长沙矿山研究院有限责任公司,长沙 410012||湖南铭生安全科技有限责任公司,长沙 410012||金属矿山安全技术国家重点实验室,长沙 410012
矿业与冶金
洪水漫顶溃坝数值模拟砂石流防控措施尾矿库有限元强度折减法
flood overtoppingdam breachnumerical simulationrock and mud-flow containment systemstailing pondfinite-element strength reduction method
《长江科学院院报》 2026 (4)
99-106,8
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