Water Transport Models of Moisture Absorption and Sweat Discharge Yarns

An important property of moisture absorption and sweat discharge yarns is their water transport property. In the paper, two water transport models of moisture absorption and sweat discharge yarns were developed to investigate the influence factors on their wicking rate. In parallel Column Pores Model, wicking rate is determined by the equivalent capillary radius R and length of the capillary tube L. In Pellets Accumulation Model, wicking rate is decided by the capillary radius r and length of the fiber unit assemble L0.

Characteristics of Oil Contamination and Numerical Modelling of Its Transport in Fracture-Karst Water in Zibo City,China

In this paper, the hydraulic characteristics of the fracture-karst aquifer and the distribution patterns of petrochemical contaminants are studied. Then, a numerical model using the mixed Eulerian-Lagrangian approach is constructed to predict the distribution and transport of petrochemical compounds in groundwater. The results of numerical modelling and sensitivity analysis show that it may be a workable way for aquifer remediation to combine contamination sources control and capture zone establishment.

Enhancing Groundwater Quality through Computational Modeling and Simulation to Optimize Transport and Interaction Parameters in Porous Media

There is a shortage of high quality drinking water caused by the introduction of contaminants into aquifers from various sources including industrial processes and uncontrolled sewage. Studies have shown that colloids, collections of nanoparticles, have the potential to remediate polluted groundwater. For such applications of nanoparticles, it is important to understand the movement of colloids. This study aims to enhance the previously developed MNM1D (Micro- and Nanoparticle transport Model in porous media in one-dimensional geometry) by making more realistic assumptions about physical properties of the groundwater-porous medium system by accounting for a non-constant flow velocity and the presence of electromagnetic interactions. This was accomplished by coupling the original model with the Darcy-Forchheimer fluid model, which is specific to transport in porous media, coupled with electromagnetic effects. The resulting model also accounts for attachment and detachment phenomena, both of the linear and Langmuirian type, as well as changes to hydrochemical parameters such as maximum colloidal particle concentration in the porous medium. The system of partial-differential equations that make up the model was solved using an implicit finite-difference discretization along with the iterative Newton’s method. A parameter estimation study was also conducted to quantify parameters of interest. This more realistic model of colloid transport in porous media will contribute to the production of a more efficient method to counteract contaminants in groundwater and ultimately increase availability of clean drinking water.

Dynamic simulation and modeling of PCP transport between sediment and water

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On the Existence of Global Weak Solutions to 1D Sediment Transport Model

This paper is devoted to the study of the existence of weak solution in time with a periodic domain of sediment transport model. We consider a one-dimensional viscous sediment transport model which combines a viscous Shallow-Water system with a transport equation that describes the bottom evolution. The model studied does not take into account all the regularizing terms used by Roamba Brahima, Zongo Yacouba and Jean de Dieu Zabsonré (2017) and we use a better transport equation than that used by Zabsonré (2012).

Hydrological Structure, Circulation and Water Mass Transport in the Gulf of Cadiz

Hydrological and LADCP data from four experiments at sea (Semane 1999, 2000/1 2000/3, 2001) are used to describe the structure and circulation of Mediterranean Water in the Gulf of Cadiz. These data were gathered on meridional sections along 8?20′W and 6?15′W and between these longitudes on a zonal section along 35?50′N. The mesoscale and the submesoscale structures (Mediterranean Water Undercurrents, meddies, cyclones) observed along these sections are characterized in terms of thermohaline properties and of velocity. The transports of mass and salt in each class of density (North Atlantic Central Water, Mediterranean Water, North Atlantic Deep Water) are computed with an inverse model. The model indicates a general eastward flux in the Central Water layer, and a westward flux in the Mediterranean Water layer, but there is also a horizontal recirculation and entrainment in these two layers, as well as strong transports associated with the meddy and cyclone found during Semane 1999.

Comparison of depth-averaged concentration and bed load flux sediment transport models of dam-break flow

This paper presents numerical simulations of dam-break flow over a movable bed. Two different mathematical models were compared: a fully coupled formulation of shallow water equations with erosion and deposition terms(a depth-averaged concentration flux model), and shallow water equations with a fully coupled Exner equation(a bed load flux model). Both models were discretized using the cell-centered finite volume method, and a second-order Godunov-type scheme was used to solve the equations. The numerical flux was calculated using a Harten, Lax, and van Leer approximate Riemann solver with the contact wave restored(HLLC). A novel slope source term treatment that considers the density change was introduced to the depth-averaged concentration flux model to obtain higher-order accuracy. A source term that accounts for the sediment flux was added to the bed load flux model to reflect the influence of sediment movement on the momentum of the water. In a onedimensional test case, a sensitivity study on different model parameters was carried out. For the depth-averaged concentration flux model,Manning's coefficient and sediment porosity values showed an almost linear relationship with the bottom change, and for the bed load flux model, the sediment porosity was identified as the most sensitive parameter. The capabilities and limitations of both model concepts are demonstrated in a benchmark experimental test case dealing with dam-break flow over variable bed topography.

Numerical Modeling of Water Wave Interaction with A Soft Mud Bed

A vertical 2-D numerical model is presented for simulating the interaction between water waves and a soft mud bed. Taking into account nonlinear rheology, a semi-empirical rheological model is applied to this water-mud model, reflecting the combined visco-elasto-plastic properties of soft mud under such oscillatory external forces as water waves. In order to increase the resolution of the flow in the neighborhood of both sides of the inter-surface, a logarithmic grid in the vertical direction is employed for numerical treatment. Model verifications are given through comparisons between the calculated and the measured mud mass transport velocities as well as wave height changes.

Physical Hydrography and Algal Bloom Transport in Hong Kong Waters

In sub-tropical coastal waters around Hong Kong, algal blooms and red tides are usually first sighted in the Mirs Bay, in the eastern waters of Hong Kong. A calibrated three-dimensional hydrodynamic model for the Pearl River Estuary （Delft3D） has been applied to the study of the physical hydrography of Hong Kong waters and its relationship with algal bloom transport patterns in the dry and wet seasons. The general 3D hydrodynamic circulation and salinity structure in the partially-mixed estuary are presented. Extensive numerical surface drogue tracking experiments are performed for algal blooms that are initiated in the Mirs Bay under different seasonal, wind and tidal conditions. The probability of bloom impact on the Victoria Harbour and nearby urban coastal waters is estimated. The computations show that： i） In the wet season （May - August）, algal blooms initiated in the Mirs Bay will move in a clockwise direction out of the bay, and be transported away from Hong Kong due to SW monsoon winds which drive the SW to NE coastal current; ii） In the dry season （November- April）, algal blooms initiated in the northeast Mirs Bay will move in an anti-clockwise direction and be carried away into southern waters due to the NE to SW coastal current driven by the NE monsoon winds; the bloom typically flows past the east edge of the Victoria Harbeur and nearby waters. Finally, the role of hydrodynamic transport in an important episodic event -- the spring 1998 massive red tide -- is quantitatively examined. It is shown that the strong NE to E wind during late March to early April, coupled with the diurnal tide at the beginning of April, significantly increased the probability of bloom transport into the Port Shelter and East Lamma Channel, resulting in the massive fish kill. The results provide a basis for risk assessment of harmful algal bloom （HAB） impact on urban coastal waters around the Victoria Habour.

膜调控润灌在不同土壤类型下的技术参数确定

【目的】探究膜调控润灌在不同土壤类型和滴头流量下的土壤水分运移规律,确定不同土壤类型下的技术参数。【方法】基于室内试验数据建立HYDRUS-2D模型,设置4种土壤类型(砂土、壤土、砂质黏壤土、粉土)和3个滴头流量(0.9、2.1、3.2L/h),探究膜调控润灌在不同土壤类型和滴头流量下的技术参数。【结果】HDYDRUS-2D模型可以准确模拟膜调控润灌条件下的土壤水分运移及分布,相对误差在5%以内,决定系数(R2)和均方根偏差(RMSE)分别为0.97和0.007;砂土因其饱和导水率大易造成渗漏,在膜调控润灌系统下需要进一步调整滴灌管埋深和流量,膜调控润灌能较好地适应其余3种土壤,灌水结束时膜上水量占总灌水量的比例高于70%,大大减少了灌溉水渗漏量;随着滴头流量的增加,壤土膜上水量的占比逐渐减小。【结论】砂土条件下,需要调整滴灌管埋深以减少水分深层渗漏;推荐在砂质黏壤土和壤土条件下采用2 L/h的滴头流量进行灌溉;随着流量的增加,粉土膜上水量占比不会降低,推荐采用3 L/h的滴头流量进行灌溉。

利用轨迹追踪法研究雅鲁藏布江大峡谷区域水汽输送减少的成因

雅鲁藏布江大峡谷区域作为高原的主要水汽输送入口,自1979年至今水汽通量辐合及降水量呈持续减少趋势,这对高原水储量具有重要影响。为了探究该区域水汽输送减少的原因,本文利用ERA5逐小时再分析资料驱动LAGRANTO模型,选取典型干旱年份和湿润年份的夏季(6-8月),后向追踪该区域的水汽输送轨迹,对沿轨迹输送的水汽通量变化进行对比分析。研究发现,源自洋面的水汽主要来自高原南部的孟加拉湾,高原西南侧的阿拉伯海,赤道以南的印度洋以及南中国海四个区域,水汽输送主要受南亚和印度夏季风控制,并受索马里跨赤道急流影响。通过对比分析干、湿年份的水汽输送轨迹的特征,发现干湿年轨迹路径除南海源地外基本不变,轨迹上水汽通量随轨迹高度抬升而减少,且湿润年的损耗始终低于干旱年,其中孟加拉湾源地的轨迹得到洋面的水汽补充,在湿润年水汽通量有较强的增长。干湿年份的蒸发、降水、环流场形势的对比也佐证了这一发现。最终湿润年到达雅鲁藏布江峡谷边界的水汽通量大于干旱年,尤其是经由雅鲁藏布江峡谷区域南边界进入的水汽通量显著增大,这表明,除源地水汽贡献和大尺度季风环流影响外,水汽输送途中的降水损耗相关过程对雅鲁藏布江峡谷区域水汽收支具有决定性作用。

玉米芯颗粒对风沙土毛管水运移和蒸发特性的影响

为探索玉米芯在干旱地区的有效利用方式、提高其利用率,通过土柱模拟的方法,将1.5~6.0 mm玉米芯颗粒与风沙土混合开展吸水与蒸发试验。以未添加玉米芯的土柱为对照,设置10种添加玉米芯处理,对不同处理土柱的吸水量、湿润锋、蒸发量、蒸发强度等进行测定,分析玉米芯及其用量对风沙土吸水、保水效果的影响。结果表明,混合土壤毛管水上升高度比对照低0.0%~76.3%,毛管水平均上升速率比对照低7.3%~78.7%,蒸发强度比对照低10.7%~64.2%。玉米芯添加量≤40%时,吸水量比对照高8.6%~16.2%;玉米芯添加量>40%时,吸水量比对照低1.1%~46.0%。毛管水上升高度与时间之间呈幂函数关系,水分补给量与时间之间呈幂函数关系,水分补给量与毛管水上升高度之间呈线性相关。吸水条件下的Green-Ampt模型调整后可用于模拟混合土壤的毛管水上升过程。Rose蒸发模型能很好地表达混合土壤累计蒸发量随时间的变化特征。研究结果为沙化土地治理、秸秆还田改良耕地等研究与实践提供理论依据。

Community Climate Model 3气候模式在东亚季风区产生虚假降水的一种可能原因

通过分析NCAR CCM3气候模式的15年积分结果,从形成降水的垂直运动和水汽供应条件的角度,试图揭示该模式在东亚季风区产生不合理虚假强降水的可能原因.与观测的降水分布相比,CCM3模拟的东亚季风区降水中心位置偏西,雨量偏强,其中对流降水占虚假降水中心总降水量的82%左右.进一步分析发现,对流层上层200 hPa副热带急流南侧的散度季节变化与110°E以西的虚假降水季节变化具有较好的对应关系,急流入口区附近的直接垂直环流上升支位于青藏高原东北部,同时由于急流南侧对流层上层辐散引起的抽吸作用,加强低层的垂直运动,从而为虚假的强对流降水形成提供上升运动条件.分析对流层低层的水汽(比湿)分布和水汽输送表明,模拟的青藏高原地区大气的水汽含量比NCEP/NCAR再分析的水汽含量高,经过高原从孟加拉湾输送到虚假降水中心地区的水汽偏强,从而为虚假的强对流降水形成提供了充足的水汽条件.因此,在改进气候模式对东亚季风区虚假降水的模拟性能时,除了对模式物理过程做改进外,在青藏高原附近地区的水汽分布和水汽输送以及对流层上层西风急流位置和强度模拟的合理性方面也需要引起足够的重视.

“21·7”河南特大暴雨成因分析及三维概念模型的构建

通过对“21·7”河南特大暴雨在地形效应、不同高度的大气环流和水汽输送通道的分析,结论如下:(1)台风“烟花”与副高形成的东南气流在底层灌入河南喇叭口地形,在地形热力抬升和动力阻挡抬升的共同作用下,有利于山前降水的形成。(2)在500 hPa中层,郑州涡旋处于两个高压的“鞍型场”内,该环流配置导致台风“烟花”、“查帕卡”和热带低压相互作用形成三股气流直达河南;在200 hPa高层,河南暴雨区辐散气流向东下沉到同一纬度的东海高层冷涡内,其次级环流进一步加强了河南云团的强度。(3)台风“烟花”和“查帕卡”输送丰沛水汽至河南中西部,受太行山和伏牛山地形阻挡,在山前形成强烈水汽辐合。(4)构建的河南极端暴雨概念模型通过水汽输送通道和次级环流,将环流、台风、低压系统和喇叭口地形等降水成因有机联系,并放入同一个构架之中,从宏观上了解这些成因的运行机理及其相互作用,可加深对该特大暴雨成因的理解。

“船闸+升船机”协同控制下的船舶调度优化

为提高“船闸+升船机”协同控制模式下的内河水运枢纽通航设施工作效率,分析该模式下通航设施和船舶过坝特点,提出一种用于“船闸+升船机”协同控制的基于滑动时间窗的船舶调度两阶段双目标整数规划优化模型。第一阶段采用滑动时间窗和先到先服务规则,设计不同船型的船舶过闸编队方案;第二阶段仍采用滑动时间窗,建立以船舶平均延误时间最短和最大泊位占用数最小为目标的双目标整数规划优化模型。使用带精英策略的非支配排序遗传算法(elitist non-dominated sorting genetic algorithm,NSGA-Ⅱ)进行求解,分别对船舶稀疏过坝、船舶密集过坝、船舶部分时段集中过坝3种情形进行仿真分析,并与不采用滑动时间窗的排队论模型进行比较。结果表明,3种情形下船舶平均延误时间均缩短了15%以上。

XB油田特高含水期油井单管深埋冷输边界条件研究与应用

为了简化集输工艺和降低运行成本,对特高含水期油井单管深埋冷输边界条件进行研究,通过建立单管深埋冷输工艺模型,明确了单管深埋冷输工艺边界条件的计算方法,该方法可指导单管深埋冷输的应用范围。并在XB油田31口采油井开展了现场试验,结果表明,单管深埋冷输工艺适合于现场应用,应用后可有效节约电能及天然气消耗,年节电量11.12×10^(4)kWh,年节气量24.40×10^(4)m^(3),年节约管道维护费用49.6万元,可促进油田绿色低碳高效发展。

Numerical modeling and simulation of PEM fuel cells: Progress and perspective

This paper provides a comprehensive review on the research and development in multi-scale numerical modeling and simulation of PEM fuel cells. An overview of recent progress in PEM fuel cell modeling has been provided. Fundamental transport phenomena in PEM fuel cells and the corresponding mathematical formulation of macroscale models are analyzed. Various important issues in PEM fuel cell modeling and simulation are examined in detail, including fluid flow and species transport, electron and proton transport, heat transfer and thermal management, liquid water transport and water management, transient response behaviors, and cold-start processes. Key areas for further improvements have also been discussed.

Low-frequency variability of terrestrial water budget in China using GRACE satellite measurements from 2003 to 2010

Mass variations in terrestrial water storage（TWS） obtained from eight years of satellite data from the Gravity Recovery and Climate Experiment（GRACE） are used to describe low frequency TWS through Empirical Orthogonal Function（EOF） analysis. Results of the second seasonal EOF mode show the influence of the Meiyu season. Annual variability is clearly shown in the precipitation distribution over China, and two new patterns of interannual variability are presented for the first time from observations, where two periods of abrupt acceleration are seen in 2004 and 2008. GRACE successfully measures drought events in southern China, and in this respect, an association with the Arctic Oscillation and El Nino-Southern Oscillation is discussed. This study demonstrates the unique potential of satellite gravity measurements in monitoring TWS variations and large-scale severe drought in China.

The effect of humidity on the CO_2/N_2 separation performance of copolymers based on hard polyimide segments and soft polyether chains:Experimental and modeling

In this work, we studied two copolymers formed by segments of a rubbery polyether（PPO or PEO） and of a glassy polyimide（BPDA-ODA or BKDA-ODA） suitable for gas separation and CO2 capture. Firstly, we assessed the absorption of water vapor in the materials, as a function of relative humidity（R.H.）, finding that the humidity uptake of the copolymers lies between that of the corresponding pure homopolymers values.Furthermore, we studied the effect of humidity on CO2 and N2 permeability, as well as on CO2/N2 selectivity, up to R.H. of 75%. The permeability decreases with increasing humidity, while the ideal selectivity remains approximately constant in the entire range of water activity investigated. The humidity-induced decrease of permeability in the copolymers is much smaller than the one observed in polyimides such as Matrimid? confirming the positive effect of the polyether phase on the membrane performance.Finally, we modeled the humidity-induced decrease of gas solubility, diffusivity and, consequently, permeability, using a suitable approach that considers the free volume theory for diffusion and LF model for solubility. Such model allows estimating the extent of competition that the gases undergo with water during sorption in the membranes, as a function of the relative humidity, as well as the expected reduction of free volume by means of water molecules occupation and consequent reduction of diffusivity.