A Regional-Scale Method of Forecasting Debris Flow Events Based on Water-Soil Coupling Mechanism

A debris flow forecast model based on a water-soil coupling mechanism that takes the debrisflow watershed as a basic forecast unit was established here for the prediction of disasters at the watershed scale.This was achieved through advances in our understanding of the formation mechanism of debris flow.To expand the applicable spatial scale of this forecasting model,a method of identifying potential debris flow watersheds was used to locate areas vulnerable to debris flow within a forecast region.Using these watersheds as forecasting units and a prediction method based on the water-soil coupling mechanism,a new forecasting method of debris flow at the regional scale was established.In order to test the prediction ability of this new forecasting method,the Sichuan province,China was selected as a study zone and the large-scale debris flow disasters attributable to heavy rainfall in this region on July 9,2013 were taken as the study case.According to debris flow disaster data on July 9,2013 which were provided by the geo-environmental monitoring station of Sichuan province,there were 252 watersheds in which debris flow events actually occurred.The current model predicted that 265 watersheds were likely to experience a debris flow event.Among these,43 towns including 204 debrisflow watersheds were successfully forecasted and 24 towns including 48 watersheds failed.The false prediction rate and failure prediction rate of thisforecast model were 23% and 19%,respectively.The results show that this method is more accurate and more applicable than traditional methods.

Optimization of water-urban-agricultural-ecological land use pattern:A case study of Guanzhong Basin in the southern Loess Plateau of Shaanxi Province,China

Extensive land use will cause many environmental problems.It is an urgent task to improve land use efficiency and optimize land use patterns.In recent years,due to the flow decrease,the Guanzhong Basin in Shaanxi Province is confronted with the problem of insufficient water resources reserve.Based on the Coupled Ground-Water and Surface-Water Flow Model(GSFLOW),this paper evaluates the response of water resources in the basin to changes in land use patterns,optimizes the land use pattern,improves the ecological and economic benefits,and the efficiency of various spatial development,providing a reference for ecological protection and high-quality development of the Yellow River Basin.The research shows that the land use pattern in the Guanzhong Basin should be further optimized.Under the condition of considering ecological and economic development,the percentage change of the optimum area of farmland,forest,grassland,water area,and urban area compared with the current land use area ratio is+2.3,+2.4,-6.1,+0.2,and+1.6,respectively.The economic and ecological value of land increases by14.1%and 3.1%,respectively,and the number of water resources can increase by 2.5%.

Influence of underground water seepage flow on surrounding rock deformation of multi-arch tunnel

Based on a typical multi-arch tunnel in a freeway, the fast Lagrangian analysis of continua in 3 dimensions(FLAC3D) was used to calculate the surrounding rock deformation of the tunnel under which the effect of underground water seepage flow was taken into account or not. The distribution of displacement field around the multi-arch tunnel, which is influenced by the seepage field, was gained. The result indicates that the settlement values of the vault derived from coupling analysis are bigger when considering the seepage flow effect than that not considering. Through the contrast of arch subsidence quantities calculated by two kinds of computation situations, and the comparison between the calculated and measured value of tunnel vault settlement, it is found that the calculated value(5.7-6.0 mm) derived from considering the seepage effect is more close to the measured value(5.8-6.8 mm). Therefore, it is quite necessary to consider the seepage flow effect of the underground water in aquiferous stratum for multi-arch tunnel design.

碳酸盐岩缝洞型油藏流固耦合下的油水两相流动特征

为提高缝洞型碳酸盐岩油藏采收率,探究其流固耦合下的油水两相流动特性,根据不同介质中的流体流动规律,建立了Stokes-Darcy两相流体流动模型;基于有效应力原理和广义胡克定律,建立了适用于缝洞型碳酸盐岩油藏的油水两相Stokes-Darcy流固耦合数学模型;分别针对有无流固耦合的缝洞型碳酸盐岩油藏,进行了宏观和细观的油水两相流体流动模拟。研究结果表明:油藏有无流固耦合作用,其油水两相流体流动特性在基质区差异较大,在溶洞内差异较小,注水速度对缝洞型碳酸盐岩油藏的油水流动影响较大。

螺杆泵转速对油水旋流分离管流场特性的影响

旋流分离器在井下采油螺杆泵作用下会发生复杂的振动现象,对旋流分离器内部流场造成一定影响。为研究螺杆泵不同转速下旋流分离器内部流场的变化规律,以同井注采工艺中螺杆泵作用下的旋流分离管柱为研究对象,针对振动壁面旋流分离管柱结构及工作特点,基于计算流体动力学方法、计算固体力学方法以及流固耦合理论,建立流固耦合力学模型;利用流固耦合分析方法,对双螺杆泵转动条件下井下旋流分离管柱内速度场、油相分布、涡量及湍动能等流场特性进行分析。分析结果表明:随着螺杆泵转速升高,分离器内切向速度和轴向速度强度逐渐减弱,径向速度的不对称性逐渐加剧,转速的周期性变化还会造成径向速度场分布的偏移;螺杆泵不同转速下旋流分离器内部涡量分布不同,随着转速升高,溢流管以及锥段部分附近相关流场的涡旋明显增强;旋流器溢流口附近油相体积分数会随着螺杆泵转速的升高而减小;不同螺杆泵转动状态下,大颗粒油滴的分布不同。所得结果可为螺杆泵井下旋流分离同井注采系统的设计及螺杆泵的转速设定提供参考。

采动覆岩裂隙演化的光纤监测耦合性及分带表征

分布式光纤感测作为科学认识采动覆岩动态演变规律的重要工具,其监测数据的准确性主要取决于光纤-岩体的耦合关系。选择神东某矿作为研究对象,将分布式光纤感测技术应用于相似模拟实验,结合光纤-岩体耦合关系,探究采动覆岩垂直分带时空演化特征与光纤应变数据峰值点位置的内在联系。针对以往研究中光纤应变数据容易受光纤-岩体耦合关系影响,从而导致测试结果出现误差的问题,提出用岩体裂隙率表征光纤-岩体耦合关系的新方法。通过光纤-岩体耦合关系试验,得到光纤-岩体应变传递系数与岩体裂隙率之间呈线性函数关系,并采用二值化方法处理模型图像获取各区域裂隙变化量,分区域地计算出采动覆岩直埋光纤的应变传递系数,为进一步探究光纤应变数据峰值与采动覆岩垂直分带特征之间的关系提供了支撑。研究表明:光纤应变峰值点位置能用于关键层下方离层以及覆岩分带表征,利用构建的关键层下方离层及覆岩分带表征模型,结合峰值检测算法,得到关键层的位置分别为44、68、107 cm,以及垮落带、导水裂隙带发育高度分别为35、68 cm,算法识别结果与理论计算数值吻合,符合神东某矿的实际情况。

基于水-经济社会-生态环境协同演变的生态流量阈值适宜性研究

针对天门河-汉北河流域生活-生产-生态“三生”用水矛盾突出、水生态退化及经济社会发展受限等问题,基于水系统理论与系统动力学方法,构建“水-经济社会-生态环境”耦合模型,从系统层面研究河道内生态流量阈值的适宜性。应用情景模拟法,考虑高效节水、再生水利用率提高等调控措施及未来天然来水的不确定性,设置9种情景模拟2022—2035年研究区高、中、低3种生态流量阈值下的水资源供需及经济社会发展态势。结果表明:高效节水和再生水利用率提高均有利于缓解因生态流量阈值增大而引起的区域水资源用户间的冲突问题;从“水-经济社会-生态环境”协调发展的角度分析,建议研究区丰水年(P=25%)生态流量阈值设置为年径流量的30%~50%,平水年(P=50%)和枯水年(P=75%)生态流量阈值设置为年径流量的10%~30%;增大生态流量阈值的同时应采取提高水资源利用效率的调控措施。研究结果从“水-经济社会-生态环境”耦合系统的协同演化机制出发分析河流生态流量阈值的适宜性,为复杂水资源系统的优化运行与科学管理提供了理论基础。

基于气−水两相流的注热CO_(2)增产CH_(4)数值模拟研究

注CO_(2)增产煤层气技术(CO_(2)−ECBM)可以降低温室气体排放,具有清洁能源生产和环境保护的功能。为研究气−水两相流条件下,在含水煤层中注CO_(2)增产CH_(4)的排采规律以及不同初始含水饱和度、不同CO_(2)注入条件对CH_(4)产量、CO_(2)储存和储层渗透率的影响,构建了竞争吸附、温度变化、煤体变形以及水运移的流−固−热耦合模型,通过与现场数据、已有试验以及现有模型的数值解结果,对比证明了模型有较高的准确性并对模型的优势做出具体阐述,随后利用COMSOL开展了CO_(2)−ECBM数值模拟。结果表明:注CO_(2)可以提升CH_(4)产气速率和产气量,这表明了注CO_(2)增产的可行性。随着CO_(2)持续注入,储层CH_(4)浓度降低,CO_(2)浓度升高,注气井附近温度升高,生产井附近温度降低且从注气井到生产井的温度缓慢下降;注气抽采期间,水相相对渗透率逐渐减小,气相相对渗透率逐渐增大。由于有效应力、基质收缩/膨胀共同作用,储层渗透率呈现“降低—升高—降低”的趋势;煤层初始含水饱和度越大,CH_(4)产量越低,渗透率下降幅度越小。累计CH_(4)产量最大下降15.19%,忽略煤层中水的影响会高估CH_(4)产量,在进行数值模拟时要考虑煤层水的影响;CO_(2)注入温度与注入压力越大,CH_(4)产量越大,渗透率下降幅度越大。累计CH_(4)产量分别增加13.27%、39.77%,渗透率分别下降20.4%、46.14%,提高CO_(2)注入温度和注入压力有利于提高CH_(4)产量。

基于SPH方法的围油栏仿真研究

为解决计算流体动力学(computational fluid dynamics,CFD)方法在模拟围油栏围控溢油时流-固耦合、水-油液体两相流中的不稳定性、计算效率差、将自由表面视为滑移壁且不考虑围油栏移动等问题,基于光滑粒子流体动力学(smoothed particle hydrodynamics,SPH)方法建立适用于围油栏围控溢油的固-液耦合、液体两相流数值模型,将5种不同裙摆结构的围油栏导入两相液体相互作用的数值仿真模型中,通过SPH代码设定数值模拟相关参数,提高计算效率,得到较精确的围油栏滞油长度与溢油失效步长。结果表明:围油栏围控溢油能力与上、下裙摆高度比及裙摆角类型有关,上裙摆高度占比越大,围油栏的滞油表现越好;前折角型围油栏的滞油表现优于前转角型围油栏;滞油长度与油品性质有关,油品的密度和黏度越小,围油栏的滞油长度越大。

Coupled effect of cement hydration and temperature on hydraulic behavior of cemented tailings backfill

Cemented tailings backfill(CTB) is made by mixing cement, tailings and water together, thus cement hydration and water seepage flow are the two crucial factors affecting the quality of CTB. Cement hydration process can release significant amount of heat to raise the temperature of CTB and in turn increase the rate of cement hydration. Meanwhile, the progress of cement hydration consumes water and produces hydration products to change the pore structures within CTB, which further influences the hydraulic behavior of CTB. In order to understand the hydraulic behavior of CTB, a numerical model was developed by coupling the hydraulic,thermal and hydration equations. This model was then implemented into COMSOL Multiphysics to simulate the evolutions of temperature and water seepage flow within CTB versus curing time. The predicted outcomes were compared with correspondent experimental results, proving the validity and availability of this model. By taking advantage of the validated model, effects of various initial CTB and curing temperatures, cement content, and CTB's geometric shapes on the hydraulic behavior of CTB were demonstrated numerically. The presented conclusions can contribute to preparing more environmentally friendly CTB structures.

基于GSFLOW的青土湖生态输水量-湖水面积关系研究

西北地区水资源匮乏,生态环境脆弱,如何科学处理生产用水与生态用水的关系一直是西北干旱区水资源开发利用中关注和研究的热点难点课题之一。关于流域中上游生态输水与尾闾湖水域面积(或湿地面积)关系的定量化研究较少。以我国西北干旱区河西走廊石羊河流域的尾闾湖—青土湖为例,利用GSFLOW建立了区域地表水-地下水耦合模型,其中采用LAK模块及SFR2模块分别处理湖泊和输水渠道,在此基础上预测了不同生态输水方案下湖泊湖面面积的变化情况,分析了青土湖生态输水量-湖水面积关系,确定了青土湖生态输水的合理范围。研究结果显示:当前3100×10^(4) m^(3)/a的生态输水量可以保证青土湖维持年内最高湖水水位1212.23 m(平均水位1211.68 m),稳定最大面积可达16.27 km^(2);当输水量为2000×10^(4)~3700×10^(4) m^(3)/a时,随输水量增大水面面积线性增加,面积变化率相对稳定;当输水量为3700×10^(4)~4500×10^(4) m^(3)/a时,水面面积随生态输水量增多,面积增大率逐渐减小;当输水量大于4500×10^(4) m^(3)/a时,水面面积随生态输水增多增大幅度很小,特别是当生态输水量大于5500×10^(4) m^(3)/a时,面积变化率趋近于0。从维持当前青土湖水面面积和向青土湖生态输水的效益考虑,红崖山水库向青土湖的生态输水量应保持在3100×10^(4)~4500×10^(4) m^(3)/a。研究成果对于确定西北干旱区合理生态需水,协调生态、经济、社会用水可持续发展具有一定的参考价值。

A state‑of‑the‑art review on rock seepage mechanism of water inrush disaster in coal mines

Water inrush is one of the most dangerous disasters in coal mining.Due to the large-scale mining and complicated hydrogeological conditions,thousands of deaths and huge economic losses have been caused by water inrush disasters in China.There are two main factors determining the occurrence of water inrush:water source and water-conducting pathway.Research on the formation mechanism of the water-conducting pathway is the main direction to prevent and control the water inrush,and the seepage mechanism of rock mass during the formation of the water-conducting pathway is the key for the research on the water inrush mechanism.This paper provides a state-of-the-art review of seepage mechanisms during water inrush from three aspects,i.e.,mechanisms of stress-seepage coupling,fow regime transformation and rock erosion.Through numerical methods and experimental analysis,the evolution law of stress and seepage felds in the process of water inrush is fully studied;the fuid movement characteristics under diferent fow regimes are clearly summarized;the law of particle initiation and migration in the process of water inrush is explored,and the efect of rock erosion on hydraulic and mechanical properties of the rock media is also studied.Finally,some limitations of current research are analyzed,and the suggestions for future research on water inrush are proposed in this review.

基于MODFLOW的地下水渗流与地面沉降耦合模型工程应用一例

随着我国基础建设的迅猛发展,特别是城市轨道交通工程大规模建设,出现了大量的深基坑工程,如果基坑开挖深度超过该区的地下水位则需要首先采取地下水的控制措施,工程降水是地下工程施工中常采用的地下水控制方法,大量抽取地下水必将导致地面沉降的发生,本文以天津站交通枢纽工程后广场工程为依托,以水文地质试验为基础,辅以孔隙水压力监测及变形监测,应用MODFLOW软件,建立基坑地下水渗流模型与地面沉降的数学耦合模型,并根据现场试验资料,反演识别了模型中的有关参数,对降水引起的水位变化进行模拟预测,对可能产生的地面沉降进行定量评估,以更好的指导基坑工程降水。

Numerical Simulation of an Airfoil Electrothermal-Deicing-System in the Framework of a Coupled Moving-Boundary Method

A numerical method for the analysis of the electrothermal deicing system for an airfoil is developed taking into account mass and heat exchange at the moving boundary that separates the water film created due to droplet impingement and the ice accretion region.The method relies on a Eulerian approach(used to capture droplet dynamics)and an unsteady heat transfer model(specifically conceived for a multilayer electrothermal problem on the basis of the enthalpy theory and a phase-change correction approach).Through application of the continuous boundary condition for temperature and heat flux at the coupled movingboundary,several simulations of ice accretion,melting and shedding,runback water flow and refreezing phenomena during the electrothermal deicing process are conducted.Finally,the results are verified via comparison with experimental data.A rich set of data concerning the dynamic evolution of the distribution of surface temperature,water film height and ice shape is presented and critically discussed.

A Model of Debris Flow Forecast Based on the Water-Soil Coupling Mechanism

Debris flow forecast is an important means of disaster mitigation. However, the accuracy of the statistics-based debris flow forecast is unsatisfied while the mechanism-based forecast is unavailable at the watershed scale because most of existing researches on the initiation mechanism of debris flow took a single slope as the main object. In order to solve this problem, this paper developed a model of debris flow forecast based on the water-soil coupling mechanism at the watershed scale. In this model, the runoff and the instable soil caused by the rainfall in a watershed is estimated by the distrib- uted hydrological model （GBHM） and an instable identification model of the unsaturated soil. Because the debris flow is a special fluid composed of soil and water and has a bigger density, the density esti- mated by the runoff and instable soil mass in a watershed under the action of a rainfall is employed as a key factor to identify the formation probability of debris flow in the forecast model. The Jiangjia Gulley, a typical debris flow valley with a several debris flow events each year, is selected as a case study watershed to test this forecast model of debris flow. According the observation data of Dongchuan Debris Flow Observation and Research Station, CAS located in Jiangjia Gulley, there were 4 debris flow events in 2006. The test results show that the accuracy of the model is satisfied.

波动水位影响下的滨岸稳定性预警技术研究

河口地区地表水波动会诱发滨岸潜水层内地下水位的震荡,并呈现出与河道水位非同步性的涨落过程。落潮阶段,河道边坡内地下水位高于地表水位,饱和区和饱和区持水量较大,容易诱发岸坡失稳。为此,通过改进BSTEM模型,并将其与考虑非饱和流运动的地下水模型SUTRA相耦合,提出了适用于复杂河口地区的崩岸预警模型SUBS。研究结果表明:河口地区地表水波动诱发的潜水层地下水波动具有较强的迟滞性,边坡安全系数和最不利崩塌面随潮汐周期性变化,涨潮期安全系数增加,落潮期由于地下水的排水滞后性,导致岸坡安全系数降低。尤其是在大潮期的落潮阶段,水位快速降落,岸坡上浸润面的出现会进一步增加岸坡崩塌的风险。进一步对比均质和非均质边坡的稳定性,结果表明岸坡内土壤黏聚力对边坡的稳定性影响较大,上层为黏土,下层为砂土的复合结构岸坡的稳定性要高于岸坡组成为低黏聚力均质砂土的情况,此时需要更加关注地下水位波动的影响。通过耦合地下水模型,考虑地下水位的实时波动特征,拓展了传统BSTEM模型的应用范围,为河口地区边坡稳定性预测提供了新的研究手段。

分布式地表水-地下水耦合数值模型研究进展

系统梳理地表、地下各水文过程中常见的控制方程以及数值求解方法,指出单一地下水模型和单一地表水模型在解决耦合问题中的短板。回顾近年来的相关研究,归纳出11种常见的耦合模型。从模型原理和适用方向2个方面对已有研究概括总结,将耦合方法划分为松散耦合型、半松散耦合型和紧密耦合型,分析耦合模型在变化环境下的地下水-地表水转化关系、河道生态流量以及地表水-地下水联合调度方面的应用。未来可以重点关注耦合模型在复杂地貌、多样化参数、模型识别验证方法、运算效率以及多学科交叉等方面的研究。

基于水质水量耦合模型的湟水西宁市段生态流量计算及模拟分析

考虑未来枯水期湟水生态流量、水质将面临不稳定达标风险,提出量化计算与数值模拟相结合的方法确定满足水质水量目标的湟水西宁市段生态流量。基于实测流量、断面、污染源等现状调查及分析,采用不同频率最枯月平均值法、改进年内同频率展布法、生态水力半径法3种方法计算了湟水西宁市段生态流量,并与Tennant法的计算结果进行合理性分析比较。利用MIKE11水动力和水质模块构建了水质水量耦合模型,利用率定后的模型,以COD、NH3-N作为主要污染物指标,通过模拟不同生态流量下泄过程,分析了3种计算方法对应的下泄方案对湟水西宁市段水质的影响,优选出合理的生态流量的下泄方案,得出了满足水质水量需求的湟水西宁市段生态流量,为湟水西宁市段的水生态保护及区域水资源配置方案提供理论支撑。

跨介质航行器出入水连续弹道试验与仿真

为研究跨介质航行器出入水连续弹道特性,搭建高速入水弹道试验平台,并设计带有内测系统的试验模型,对跨介质航行器出入水连续弹道过程进行试验研究。建立耦合求解流场和航行器运动的非定常数值仿真模型,研究航行器出入水连续弹道的运动规律与流体动力特性,并通过试验结果验证其准确性。研究结果表明:新提出的跨介质航行器实现了入水-转平-出水连续弹道过程,其弹道轨迹呈类抛物线状,入水最大深度为0.9 m;航行器出入水连续弹道运动可分为入水滑行阶段、呈双侧尾拍运动的超空泡航行阶段以及单侧尾拍运动的出水阶段;航行器流体动力特性呈脉冲式振荡特性,由圆锥段、圆柱段以及尾裙段构成尾部流体动力;预置舵角与尾裙的组合形式能够提高跨介质航行器连续出入水的稳定性。

基于一维水动力-水环境耦合模型的长兴港生态流量研究

【目的】长兴港是太湖流域重要的城市河流,对其开展生态流量研究并确定合理的生态流量管控值,对保障长兴港水生态环境健康、提高当地人民群众幸福指数具有重要意义。【方法】以长兴港新塘断面2016—2020年的逐月水生态监测数据为对象,明确了长兴港非汛期、汛期的水环境约束指标;并基于MIKE 11软件,构建了一维水动力-水环境耦合模型;从保障水生态环境质量、缓解水华爆发的营养条件的角度出发进行了生态流量研究。【结果】结果显示:长兴港非汛期约束指标为NH_(3)-N、COD_(Mn)和BOD,汛期约束指标为NH_(3)-N、TP和COD_(Mn);通过对比实测数据与模拟数据可知,水位、流量的模拟值与实测值间的Re均小于10%,R^(2)和Nash-Suttcliffe系数分别大于0.6和0.9,各时期的水环境主要管控指标的模拟值与实测值间的Re均小于17%;最终计算得到长兴港非汛期和汛期合理的生态流量管控值分别为2.59 m^(3)/s和2.63 m^(3)/s。【结论】结果表明:研究构建的一维水动力-水环境耦合模型符合长兴港的实际情况,能够应用于长兴港生态流量研究,可以解决水动力和水环境模块单独使用不能表征河流特点的问题,为河流生态流量的研究和管控提供了更为科学、高效的工具;研究提出的生态流量管控值具有可达性,可切实有效地改善长兴港水生态环境、抑制水华爆发并为长兴港的生态流量管控和“幸福河”构建等工作提供理论与技术支撑。