Numerical simulation of pore-scale flow in chemical flooding process

Chemical flooding is one of the effective technologies to increase oil recovery of petroleum reservoirs after water flooding.Above the scale of representative elementary volume(REV), phenomenological modeling and numerical simulations of chemical flooding have been reported in literatures,but the studies alike are rarely conducted at the pore-scale,at which the effects of physicochemical hydrodynamics are hardly resolved either by experimental observations or by traditional continuum-based simulations.In this paper,dissipative particle dynamics(DPD),one of mesoscopic fluid particle methods,is introduced to simulate the pore-scale flow in chemical flooding processes.The theoretical background,mathematical formulation and numerical approach of DPD are presented.The plane Poiseuille flow is used to illustrate the accuracy of the DPD simulation,and then the processes of polymer flooding through an oil-wet throat and a water-wet throat are studies, respectively.The selected parameters of those simulations are given in details.These preliminary results show the potential of this novel method for modeling the physicochemical hydrodynamics at the pore scale in the area of chemical enhanced oil recovery.

Three-Dimensional Imaging of Pore-Scale Water Flooding Phenomena in Water-Wet and Oil-Wet Porous Media

The penetration of water during water flooding has been observed over many years using several methods. A microfocused X-ray computed tomography scanner can be used to directly observe 3D water flooding in a nondestructive manner. To eliminate the possibility of false images being produced because of X-ray broadening effects, we developed a visualization method by arranging the brightness distribution of all phases involved. Water flooding experiments were conducted using oil-wet and water-wet porous media. The water phase was injected upward into packed glass beads containing an oil phase, and the process was scanned every minute until steady state was reached. Using this scheme, real-time, the water invasion pattern and oil trapping process in clusters of pores and individual pores can be observed clearly. By eliminating false images, the boundary of each phase could be identified with high precision, even in a single pore. Porelevel phenomena, including snap off (which has never before been captured in a real 3D porous medium), piston-like displacement, and the curvature of the interface, were also observed. Direct measurement of the pore throat radius and the contact angle between the wetting and nonwetting phases gave an approximation of the capillary pressure during the piston-like displacement and snap-off processes.

Assessment of Flood Catastrophe Risk for Grain Production at the Provincial Scale in China Based on the BMM Method

Flood catastrophe risk assessment is imperative for the steady development of agriculture under the context of global climate change,and meanwhile,it is an urgent scientific issue need to be solved in agricultural risk assessment discipline.This paper developed the methodology of flood catastrophe risk assessment,which can be shown as the standard process of crop loss calculation,Monte Carlo simulation,the generalized extreme value distribution（GEV） fitting,and risk evaluation.Data on crop loss were collected based on hectares covered by natural disasters,hectares affected by natural disasters,and hectares destroyed by natural disasters using the standard equation.Monte Carlo simulation based on appropriate distribution was used to expand sample size to overcome the insufficiency of crop loss data.Block maxima model（BMM） approach based on the extreme value theory was for modeling the generalized extreme value distribution（GEV） of flood catastrophe loss,and then flood catastrophe risk at the provincial scale in China was calculated.The Type III Extreme distribution（Weibull） has a weighted advantage of modeling flood catastrophe risk for grain production.The impact of flood catastrophe to grain production in China was significantly serious,and high or very high risk of flood catastrophe mainly concentrates on the central and eastern regions of China.Given the scenario of suffering once-in-a-century flood disaster,for majority of the major-producing provinces,the probability of 10% reduction of grain output is more than 90%.Especially,the probabilities of more than 15% decline in grain production reach up to 99.99,99.86,99.69,and 91.60% respectively in Anhui,Jilin,Liaoning,and Heilongjiang.Flood catastrophe assessment can provide multifaceted information about flood catastrophe risk that can help to guide management of flood catastrophe.

1600-1900年渭南地区洪涝灾害多尺度时序特征及对降水的响应

目的 研究1600-1900年渭南地区洪涝灾害的多尺度时序特征及其对降水的响应,为认识该区洪涝灾害的发生机制和历史时期气候变化规律提供理论依据。方法 基于《中国三千年气象记录总集》等历史文献资料,利用集合经验模态分解(EEMD)和Morlet小波分析等方法。结果 1600-1900年渭南地区的洪涝灾害具有显著的准3 a和6 a的年际,准12 a, 15 a, 28 a和57 a的年代际和准125 a和208 a的百年际周期变化;厄尔尼诺和太平洋年代际振荡可能是导致该区洪涝灾害发生的主要原因;该区洪涝灾害在年际尺度上的方差贡献率(68.34%)大于在年代际和百年尺度上的方差贡献率(24.0%和2.92%),这可能暗含着该地区洪涝灾害的年际振荡信号强于年代际和百年尺度的振荡信号。结论 1600-1900年渭南地区的洪涝灾害存在年际、年代际和百年际尺度变化特征,并与毗邻地区华山和中北地区的降水有着较好的响应。

基于VIC模型的三峡库区流域小时尺度实时洪水预报

VIC模型在流域面积大于3 000 km^(2)的大型流域日或月尺度洪水模拟中表现出良好的适用性,而在大型流域小时尺度实时洪水预报过程中的适用性尚未得到验证。以三峡库区大型流域为例,通过建立小时尺度VIC分布式洪水预报模型,构建三峡库区流域实时滚动洪水预报方案,将VIC分布式洪水预报模型实地化部署并应用于2022及2023年三峡库区实时洪水预报。结果表明:VIC模型应用于2014—2021年三峡库区各子流域历史洪水模拟,率定期和验证期的洪量、洪峰平均合格率均在80%以上,确定性系数均值在0.70以上,构建的VIC分布式洪水预报模型在三峡库区及其子流域洪水模拟中表现出良好的适用性;在2022及2023年三峡库区4场典型洪水的实时洪水预报中,径流深和洪峰的平均相对误差达到16.3%和5.0%,重点产流区产流量平均相对误差为7.8%,能够准确把握库区重点产流区的洪量及来水过程,因此VIC模型在大型流域小时尺度实时洪水预报中具有较大的应用潜力。

基于多参数优化地理探测器的山洪灾害驱动力分析及风险评价

【目的】大同市地处黄土高原东北边缘,区域内频繁的地下开采活动加剧了山洪灾害,严重威胁人民生命财产安全。为揭示该区域山洪灾害主要驱动力及对其进行风险性评价,【方法】基于大同市山洪灾害调查评价项目成果数据,采用多尺度网格进行采样,并组合参数最优地理探测器对连续型驱动因子进行最优离散化处理,探测分析山洪灾害驱动因子解释力和各驱动因子分级的平均危险度,最后基于所得解释力和危险度进行定量风险性评价。【结果】结果表明:降雨是诱发山洪灾害的首要因素(q=0.088 8),人类活动次之(q=0.061 8),地表环境最弱(q=0.022 7);在所选降雨指标中,6 h强降雨对大同市山洪灾害发生有平均最强解释力(q=0.141 2),可在进一步山洪灾害临界雨量研究中予以考虑;大同市山洪灾害危险水平较高,中高危险区面积占比超3/5,高危险区灾害点密度达0.038 5个/km^(2)。【结论】网格尺度和离散方式的优化选择均可有效提高地理探测器分析结果解释力;短历时(<6 h)强降雨若降雨不能持续,对山洪灾害的诱发力度大打折扣;整体来看大同市山洪灾害危险水平较高,且主要集中分布在易损性水平较低区域。研究结果可为定量进行山洪灾害风险性评价提供参考,为大同市山洪灾害防治区划提供一定的科学依据。

当前渗流力学理论遇到的挑战与对策思考

本文详细阐述了渗流力学经典理论——达西定律的发展历程及其适用条件,并从Navier-Stokes(N-S)方程推导出了达西定律在多孔介质中的毛细管渗流和裂缝渗流中的数学表达式。文章指出了当前达西定律应用中存在的8大问题,并综合分析了渗流力学理论在油气田开发中的主要挑战。针对这些挑战,本文提出了一系列对策和思考。文章强调指出:构建多尺度、多物理场耦合模型并借助AI科学计算是揭示油气储层复杂真实流动机制,填补目前理论空白的必由之路。建议指出:进一步发展核磁共振、电镜扫描及智能数据与图像处理等高精度实验技术,以直观展现流体在储层中的流动行为和过程。最后,建议综合运用实验研究、新理论模型建立和AI科学研究方法(AI for Science),突破油气渗流力学理论中目前遇到的挑战。研究成果可为我国高校、科研机构和研究者开展石油科学理论研究和课题立项提供重要参考,同时可为我国油气资源可持续进行科学和技术战略规划提供强有力的技术支撑。

城市水利大海绵在宿迁市的探索与实践

当前我国海绵城市建设主要以低影响开发(LID)为主,虽有效提升了城市排水防涝能力,但仍缺乏流域、区域、城市、社区多尺度建设措施的协同推进。以江苏省宿迁市推进海绵城市建设为切入点,提出“城市水利大海绵”的概念,阐述其理念内涵、建设目标等,指出城市水利大海绵是以城市河湖水系为基础、各种水利设施为节点、精细化调度为灵魂,并与小尺度LID设施有效衔接的系统化全域海绵城市建设新模式。在此基础上,确定了以天然水域面积比例为基础指标,以统筹保障城市水安全、优化水资源配置、改善水生态等为基本目标的城市水利大海绵构建思路,剖析了其构建过程中的关键指标,阐明了相应的实施路径。

海上高温水驱油田防垢技术研究与应用

针对渤海M稠油油田热水驱过程中高效换热器内部易结垢问题,通过垢化学分析系统模拟了现场注入水水质,筛选出适用于M油田的高温缓蚀防垢剂体系,评价了其性能。结果表明,该体系优选质量浓度为200 mg/L,在130℃的现场注入水质下,试验时间12 h,动态防垢率为94.32%,同时在130℃下对实验挂片动态腐蚀速率为0.0173 mm/a。现场应用结果表明:高温缓蚀防垢剂在M油田具有明显的防垢效果。

雨涝治理中的城市空间韧性传导——多尺度嵌套结构与交互关系

雨涝灾害是制约城市高质量发展的难题之一。将雨涝韧性建设融入国土空间规划治理体系、整合城市空间布局与雨涝韧性的逻辑和秩序、区分不同尺度空间秩序所对应的雨涝治理路径,是城市在不断变化的气候环境中维持可持续发展、确保人居环境安全的紧迫需求。本文首先搭建了耦合城市空间与雨涝韧性的多尺度传导理论架构,进而以厦门岛为实证案例,阐明城市空间雨涝韧性的基本单元类型、多尺度嵌套结构和跨尺度交互作用关系。以此为依据,提出“区隔类型、理顺结构、重塑关系”的多尺度传导优化路径。旨在拓展城市空间布局与雨涝韧性关系研究和层级研究的深度和广度,并为落实“多规融合”和规划传导、实现城市对雨涝灾害的动态适应提供科学依据。

三元复合驱和聚驱采出水混合回注结垢特性分析

三元区块已陆续进入后续水驱阶段,为保证三元后续区块水量平衡,增加普通注水量,减少深度水用量,三元区块的注入水质从深度污水逐步转换为三元区块的采出水,并与聚驱采出水混合回注。在实际运行中发现注水管道存在注入量下降、注入管道憋压、注水井筒结垢等问题,因此,对注水站上游来水进行取样,开展室内配伍试验,根据1∶2混掺比例对污水进行混掺,对混掺前、后污水在不同温度和pH值下的结垢特性进行了分析,确定了其结垢特性为单一的污水结垢速度,结垢趋势相对于混掺后的污水结垢趋势更低、速度更慢,结垢的主要影响因素为温度和pH值。同时,通过结垢计算软件对样品进行结垢趋势计算,预测其成垢趋势及速度。最终明确了混掺污水的成垢特性及成垢趋势,为防垢措施的制定提供了依据,为今后相似区块开发后期管道结垢预防方法提供了新思路。

丹江口库区多时间尺度旱涝变化特征研究

利用丹江口库区1961年-2019年21个气象站点数据计算了多个时间尺度的标准化降水蒸散指数,探究了库区旱涝时空变化特征,以期为库区生态环境建设与管理提供科学依据。结果表明:时间尺度越小,库区旱涝发生越频繁,反之越稳定,库区干旱发生频率高于洪涝频率,而库区未来呈偏湿趋势;除1个月时间尺度外,其余时间尺度库区干旱与洪涝频率空间分布特征相反,而库区旱涝变化趋势空间分布较为一致;库区多时间尺度旱涝周期交替现象一致,主要时间尺度以28年~32年、6年、14年为主,未来几年库区呈偏涝趋势,应加强相应的生态环境保护措施。

CO_(2)驱不同注入方式对低渗透储层渗流能力的影响

CO_(2)驱是提高低渗透储层采收率有效的技术手段。CO_(2)与原油接触后使体系中的沥青质以固体形式沉积下来,对储层造成一定堵塞,但同时发生的溶蚀作用整体上提高了储层渗流能力,且不同注入方式下CO_(2)驱对低渗透储层渗流能力的影响具有一定差异。开展了CO_(2)连续注入及CO_(2)-水交替注入后有机垢堵塞机理实验、储层润湿性实验及CO_(2)-水溶液对岩石的溶蚀评价实验,并对相对渗透率曲线参数变化特征进行评价,定量表征了CO_(2)驱不同注入方式对低渗透储层渗流能力的影响程度。结果表明:CO_(2)驱产生的有机垢会对岩石孔喉造成堵塞,但整体上CO_(2)与绿泥石反应导致的溶蚀作用更强,使得低渗透储层采收率有效提高;且CO_(2)-水交替注入比CO_(2)连续注入引起的有机垢堵塞要弱,溶蚀作用效果更好,渗透率损失率更低,能够在中、大孔隙中取得更好的驱油效果,整体上更能增大岩石孔隙空间和渗流通道,使得低渗透储层采收率有效提高。

10—20d和30—60d低频振荡对华南前汛期持续性暴雨的影响差异及机制研究

利用中国气象局发布的《区域性重要过程检测和评价业务规定》中对省级区域性暴雨过程的统计数据,NOAA气候预测中心降水、向外长波辐射(OLR)资料以及ERA-Interim再分析资料,探讨了10—20 d和30—60 d两类低频振荡对华南前汛期持续性暴雨的相对重要性,并基于尺度分离的水汽方程和垂直速度方程诊断了相关物理机制。结果表明,10—20 d准双周振荡对暴雨强度的影响较为显著,而30—60 d季节内振荡与暴雨持续时间相关较高,表明持续性暴雨事件与低频降水的发生和演变关系密切。通过对低频降水的热力和动力过程诊断,发现10—20 d低频降水的水汽来源主要为水汽平流过程,而导致水汽平流正距平的主要原因是10—20 d风场和背景水汽场的相互作用;而对于30—60 d低频降水而言,水汽平流和水汽辐合均为扰动水汽的累积做正贡献,但其中水汽平流更加重要,其主要来源于平均风场和30—60 d水汽场的相互作用。有利于两类低频降水发生的动力条件,即垂直上升运动,其主要源于平均风场和扰动涡度场相互作用引发的垂直涡度平流梯度。以上结果显示,提高模式中低频振荡与季节平均状态尺度相互作用的刻画能力,是改进预报持续性暴雨的关键。

沿海中小河流域地表-地下水库联合调控洪水资源利用研究:Ⅰ.方法与模型

针对沿海中小河流域地表-地下水库复杂工程系统,因缺少联合调控方法而导致洪水资源利用难的问题,解析地表-地下水库系统结构与功能,定量模拟地表水库调度、闸坝调控下河流和地下水动力过程,并利用智能替代模型提升水动力过程计算速度;在此基础上通过研发时/日/月多时间尺度模型耦合嵌套方法,构建了兼顾计算精度与效率的地表-地下水库联合调控模型。该模型实现了洪水、地表-地下水相互作用和供水等时间尺度差异明显的调节过程的统一调配,可为沿海中小河流域洪水资源利用提供新思路与技术支撑。

Similarity criterion of flood discharge atomization

By combining the results of prototype observation of flood discharge atomization at the Wujiangdu Hydropower Station, and by adopting the serial model test method, the model scale effect was examined, the influences of the Reynolds and Weber numbers of water flow on the rain intensity of flood discharge atomization were analyzed and a rain intensity conversion relation was established. It is demonstrated that the level of atomization follows the geometric similarity relations and it is possible to ignore the influence of the surface tension of the flow when the Weber number is greater than 500. Despite limitations such as incomplete data sets, it is undoubtedly helpful to study the scale effect of atomization flow, and it is beneficial to identify the rules of the model test results in order to extrapolate to prototype prediction.

基于局部洪泛优化的低轨星座分布式路由算法

针对传统分布式路由算法应用于大型低轨星座时拥塞控制能力有限的问题,提出了基于局部洪泛优化的分布式路由算法。该算法通过局部洪泛的机制收集星间链路的拥塞信息,以应对局部通信需求密集所导致的常见拥塞现象;通过局部路径优化,以较低运行开销实现了流量疏导和网络负载均衡。并且该算法可适用于多层低轨卫星网络结构,不会产生路由环路,对卫星随机故障具有宽适应性。仿真实验表明:该算法在通信需求分布不均的高网络负载情况下能降低2%~10%的丢包率,并对网络随机故障具有鲁棒的表现。

High-resolution flood modeling of urban areas using MSN_Flood

Although existing hydraulic models have been used to simulate and predict urban flooding, most of these models are inadequate due to the high spatial resolution required to simulate flows in urban floodplains. Nesting high-resolution subdomains within coarser-resolution models is an efficient solution for enabling simultaneous calculation of flooding due to tides, surges, and high river flows. MSN_Flood has been developed to incorporate moving boundaries around nested domains, permitting alternate flooding and drying along the boundary and in the interior of the domain. Ghost cells adjacent to open boundary cells convert open boundaries, in effect, into internal boundaries. The moving boundary may be multi-segmented and non-continuous, with recirculating flow across the boundary. When combined with a bespoke adaptive interpolation scheme, this approach facilitates a dynamic internal boundary. Based on an alternating-direction semi-implicit finite difference scheme,MSN_Flood was used to hindcast a major flood event in Cork City resulting from the combined pressures of fluvial, tidal, and storm surge processes. The results show that the model is computationally efficient, as the 2-m high-resolution nest is used only in the urban flooded region.Elsewhere, lower-resolution nests are used. The results also show that the model is highly accurate when compared with measured data. The model is capable of incorporating nested sub-domains when the nested boundary is multi-segmented and highly complex with lateral gradients of elevation and velocities. This is a major benefit when modelling urban floodplains at very high resolution.

Multiple time scales of fluvial processes—theory and applications

Fluvial processes comprise water flow,sediment transport and bed evolution,which normally feature distinct time scales.The time scales of sediment transport and bed deformation relative to the flow essentially measure how fast sediment transport adapts to capacity region in line with local flow scenario and the bed deforms in comparison with the flow,which literally dictates if a capacity based and/or decoupled model is justified.This paper synthesizes the recently developed multiscale theory for sediment-laden flows over erodible bed,with bed load and suspended load transport,respectively.It is unravelled that bed load transport can adapt to capacity sufficiently rapidly even under highly unsteady flows and thus a capacity model is mostly applicable,whereas a non-capacity model is critical for suspended sediment because of the lower rate of adaptation to capacity.Physically coupled modelling is critical for fluvial processes characterized by rapid bed variation.Applications are outlined on very active bed load sediment transported by flash floods and landslide dam break floods.

多尺度分级河网模型在江苏省太湖地区的应用研究

江苏省太湖地区地处长江三角洲地区,河网密布,城镇化率高,水利工程众多且调度复杂,流域、区域、圩区等特点明显,区域防洪、城市防洪排涝、圩区排涝等问题比较突出。由于平原河网水动力模拟模型有其内在的复杂性,大型平原河网的水文—水动力联合模拟通常难以满足模型数据动态更新和多尺度分级模拟要求。利用多尺度智能模型构建思路,针对江苏省太湖地区洪涝问题开展多尺度智能分级模型的构建与模拟,结果表明,多尺度模型能够快速模拟江苏省太湖地区洪涝情况,为江苏省太湖地区洪涝精准调度提供有力支撑。