土石围堰溃堰洪水三维动态仿真模型

为增强土石围堰溃堰洪水演进计算数据及结果的直观性与处理的同步性,耦合土石围堰溃堰洪水数值模拟模型和溃堰动态仿真模型构建了土石围堰溃堰洪水演进动态仿真架构,其中考虑了洪水演进水力要素、洪水演进过程和河槽空间位置等特征信息。建立了数值模拟数据及三维动态仿真数据与相应图元对象的映射关联,通过动态更新水位、围堰及河道等图元变量和属性变量,直观地表现了土石围堰溃堰洪水演进的时空分布特征,为防洪减灾的决策分析提供了交互式可视化平台。

苗尾水电站施工期溃堰洪水计算分析

苗尾水电站施工期临时围堰挡水度汛期间,若因上游超标洪水导致围堰溃决,将引起围堰库区水体骤然下泄,形成较大溃坝洪峰向下游传播,严重威胁下游两岸村镇及功果桥梯级电站的安全。根据溃坝洪水传播和运动的特点,建立了一个包括围堰溃决过程和洪水演进的溃堰洪水数学模型。利用该模型,合理假定围堰溃决模式,拟定不同的计算方案,对苗尾水电站施工期围堰溃决及溃堰洪水演进过程进行了模拟计算。通过模型计算可以得到各特征断面的最高水位和最大流量值,并可以得到溃堰洪水传至各特征断面的演进时间。因此,可以利用溃堰洪水数学模型,为围堰溃决时下游河道两岸的洪灾分析及溃堰应急预案制定提供科学依据。

基于HEC-RAS的施工期围堰溃决洪水模拟研究

研究溃坝(堰)洪水演进对下游区域的灾害预警和防洪决策等具有重要意义。基于HEC-RAS一维非恒定流水力学模型,考虑不同的入库流量及围堰破坏形式,对某水利工程施工期围堰溃决洪水进行了数值模拟,并分析了各工况下围堰溃口及河道下游的洪水流量过程、洪峰到达时间等。研究成果可为该工程防洪抢险预案的制定提供科学依据,同时可供其他类似工程参考。

白格堰塞湖抢险处置应急管理与经验启示

基于2018年金沙江白格堰塞湖应急处置工作,全面总结了部际联合会商、央地协同联动等应急抢险工作机制,深入分析了金沙江中游梯级水库群联合调度削峰对防灾减灾所发挥的重要作用。研究表明,若无梨园水库拦蓄,将可能新增淹没面积约160 km^(2),必对沿江两岸造成更大的损失。据此认识到,迅速获取堰塞湖信息是抢险处置的前提,快速研判堰塞湖风险是重要支撑,精准分析溃决洪水是核心技术,协同联动工作机制是基本保证,动态抢险工程管理是科学方法,完善的高坝水库群是应对洪灾的根本手段。进而提出加强乏信息条件下堰塞湖多源信息快速获取与处理技术、乏信息条件下风险快速研判技术能力、抢险处置专用装备研发、抢险工程统筹管理和协同联动体系完善、高坝水库群开发建设和风险防控与应急调度体系建设等建议,为堰塞湖应急管理水平提升和流域综合防灾减灾提供借鉴。

2018年长江上游水库群联合调度实践与成效

在水利部的领导下,2018年长江水利委员会超前谋划、精心组织,科学实施长江上游水库群联合调度,保障了防洪安全,有效减轻了洪涝灾害损失。概述了2018年长江上游水雨情及特点,从准确预测预报预警、应对流域洪水和堰塞湖险情、统筹安排上游水库群有序蓄水、稳妥做好流域应急及生态调度4个方面总结了2018年长江上游水库群调度工作及成效。

Catastrophic Debris Flows on July 10^(th) 2013 along the Min River in Areas Seriously-hit by the Wenchuan Earthquake

Over 240 debris flows occurred in hill-slopes, gullies （ indicated those with single-channel） and watersheds （indicated those with tributaries and channels） on July 10th 2013 in the Wenchuan county, and caused 29 casualties and about 633×10^6 USD losses. This work aimed to analyze characteristics, hazards and causes of these events and explore mitigating measures based on field investigation and remote sensing images interpretation. The debris flows contained clay content of 0.1%~3.56%, having densities of 1.72-2.14 t/m^3, velocities of 5.0-m.7 m/s, discharges of 335-2353 m^3/s and sediment yields of 0.10-1.26×10^6 m^3, and also numerously occurred in large watersheds with the area over lo km^2. Large debris flows formed 3 hazard-chains in slopes, gullies, watersheds and rivers, which all evolved in dammed lakes and outburst flood, and 26 dammed lakes and lO newly ones were generated along the rivers of Min and Yuzi. The remarkable spatial difference of loose solid materials accumulation and intense rainfall, with the cumulative of about or more than 150 mm and the hourly of over 16mm, caused debris flows in the sections from Yingxiu to Miansi and Gengda. The damages on buildings, reconstructions, highways,factories and hydro power station originated from the impacting, scouring, burying of debris flows, the submerging of dammed lake and the scouring of outburst flood, and the huge losses came from the ruinous destructions of control engineering works of debris flows as well as the irrational location and low- resistant capabilities of reconstructions. For hazards mitigating of debris flows in long term, the feasible measures for short term, including risk-reassessing of foregone and potential hazard sites, regional alarming system establishing and integrated control in disastrous sites, and middle-long term, including improving reconstruction standard, rationally disposing river channel bed rise and selecting appropriate reconstruction time and plans, were strongly suggested.

金沙江白格堰塞湖应急抢险与处置技术

山体滑坡堵塞江河形成堰塞湖,应急抢险时间紧迫、环境复杂、条件险恶、交通不便,处置难度大,一旦失控下泄将严重威胁下游梯级电站和沿岸人民生命财产安全.为系统研究堰塞湖应急处置技术,明晰堰塞湖溃决与抢险过程,结合2018年金沙江上游"10·11"和"11·03"白格堰塞湖应急抢险与风险处置,在分析两次白格堰塞湖特征及成因的基础上,采用基于冲刷侵蚀的双曲线溃坝计算模型预测两次堰塞湖溃决洪峰分别为10000和44300 m^(2)/s,据此提出"11·03"堰塞湖抢险处置必须人工开挖引流槽、在建苏洼龙电站围堰破拆、已建梨园水电站泄水腾库等一系列应急处置措施.结果表明,"11·03"堰塞湖开挖深13.5 m引流槽将洪峰流量降低至33900 m^(2)/s,与预测的34400 m^(2)/s基本一致;在建苏洼龙电站围堰破拆避免溃决洪峰叠加放大,如不破拆围堰,溃决洪峰可能由19800 m^(2)/s增加至32200 m^(2)/s;在运梨园水库泄水腾库,成功拦洪削峰,使得溃决洪峰由7190 m^(2)/s削减至4500 m^(2)/s,减轻了下游各梯级电站水库防洪压力,并通过梯级水电站库群联合调度,将沿岸灾害损失降至最低.本文系统反演分析了两次白格堰塞湖抢险过程和应急处置关键技术及措施,为类似堰塞湖应急抢险和流域梯级水电站库群风险防控提供借鉴.