河套灌区井渠联合运用优化灌溉模型

针对河套灌区的地面水与地下水联合运用问题,提出了井渠结合优化灌溉模型,以最佳种植模式和最优工程运行策略,达到控制地下水位、防治土壤盐碱化、获得农作物稳产高产的目的.模型有调蓄地面水源、土壤贮水层、地下含水层的能力.优化计算成果与266.7hm2试验示范区的实际运行结果相吻合,节水、节能、增产及控制地下水位、改良盐碱地等效果十分显著,这对发展节水型灌溉农业具有重要的现实意义.     

Global extent and distribution of artificial, residential waterways in estuaries

Artificial residential waterways are now widespread in the world’s estuaries. We used the global mapping tool, Google Earth, to determine that there are nearly 4000 linear km of artificial waterways globally, covering an area of 270 km². Residential waterways constructed as open, flow-through canal estates are at their greatest extent in North America (77% of global linear extent), where systems are typically longer and narrower, with more openings and dead-ends than systems elsewhere. The remaining canal estates are spread across all other continents except Antarctica: Asia (7%), Europe (7%), Oceania (7%), South America (0.9%), and Africa (0.6%). A relatively recent design change from open canals to artificial estuarine lakes with tidal barriers has occurred on all continents except Africa, most extensively in Australia (14 km² area, 57 independent systems). The extremely large expansion in artificial residential waterways aimed at increasing opportunities for waterfront living by humans has also modified and expanded estuarine habitat available to aquatic biota. Research can best underpin planning and management of these types of waterways by focussing on their value as habitat and their provision of other goods and services.     

道真沙坝水库干渠滑坡的治理

本文从治理滑坡的实践出发,探讨并制定了渠道所遇土质滑坡的治理方案,经实施,既经济,效果又好,具有推广实用价值。     

基于广义Winkler弹性地基梁理论的梯形渠道冻胀力学模型

寒区渠道衬砌冻胀破坏现象普遍,而渠道的防冻工程设计大多依赖工程实践经验和定性认识,具有一定的随意性和盲目性,对衬砌结构所受的冻胀力计算缺乏简明、合理的方法。考虑冻土与衬砌的相互作用和冻土地基的连续性,基于广义Winkler地基梁理论并结合有限差分法,推导了渠道衬砌板冻胀挠曲线微分方程,建立了梯形渠道冻胀力学模型,给出了衬砌渠道法向冻胀力及切向冻结力的计算方法。同时,考虑渠道衬砌冻胀破坏的极限承载力以及冻胀过程中坡脚上抬位移对实际冻胀力的削减和释放效应,避免了冻胀力及衬砌结构内力计算值过大。为验证模型的合理性,以甘肃省靖会总干渠梯形渠道为研究对象,对其进行冻胀破坏计算。结果表明：模型由于考虑了衬砌结构与冻土间的相互作用,渠道衬砌板法向冻胀力呈非线性分布,修正了工程力学模型线性分布假设;与工程力学模型相比,冻胀力数值在坡脚处增大、跨中减小、底板上增大,计算结果更符合工程实际。研究提出的冻胀力学模型科学合理,简便快捷,具有更好的通用性,可为寒区渠道的抗冻胀设计提供参考。     

河渠渗漏量计算方法研究进展

河渠渗漏是水资源利用与水环境保护中重要环节之一,对它进行量化具有重要的实践意义。对国内外各种有关河渠渗漏量计算方法的研究成果进行了系统的总结,分别指出各种方法的适用范围和优缺点,并对如何改进现有方法进行了展望。     

A fuzzy logic based dynamic wave model inversion algorithm for canal regulation

A fuzzy logic based centralized control algorithm for irrigation canals is presented. Purpose of the algorithm is to control downstream discharge and water level of pools in the canal, by adjusting discharge release from the upstream end and gates settings. The algorithm is based on the dynamic wave model (Saint‐Venant equations) inversion in space, wherein the momentum equation is replaced by a fuzzy rule based model, while retaining the continuity equation in its complete form. The fuzzy rule based model is developed on fuzzification of a new mathematical model for wave velocity, the derivational details of which are given. The advantages of the fuzzy control algorithm, over other conventional control algorithms, are described. It is transparent and intuitive, and no linearizations of the governing equations are involved. Tuning of the algorithm and method of computation are explained. It is shown that the tuning is easy and the computations are straightforward. The algorithm provides stable, realistic and robust outputs. The disadvantage of the algorithm is reduced precision in its outputs due to the approximation inherent in the fuzzy logic. Feed back control logic is adopted to eliminate error caused by the system disturbances as well as error caused by the reduced precision in the outputs. The algorithm is tested by applying it to water level control problem in a fictitious canal with a single pool and also in a real canal with a series of pools. It is found that results obtained from the algorithm are comparable to those obtained from conventional control algorithms. Copyright © 2009 John Wiley & Sons, Ltd.     

基于线性二次型的多级联输水渠道最优控制

灌溉输配水是水联网链路的重要环节,其自动控制水平直接影响着水联网效率和风险控制能力,对实现水资源高效管理与利用有重要意义。通过变化输水渠道线性积分时滞控制模型,建立了多级联渠道离散时间状态空间方程,基于线性二次型理论设计最优状态反馈控制器,利用MATLAB求解和SOBEK模拟进行了验证。在甘肃省昌马南灌区多级联渠道运行过程优化控制的模拟结果显示,线性二次型算法能够使控制点水位较快恢复并稳定在设定值,控制过程动作与水位波动次数少、幅度小,效果远优于常规分布式PI反馈控制。线性二次型算法能够应对多级联渠道时滞、耦合特性和一般未知取水扰动,实现可靠供水服务和有效运行控制。目前算法仅采用反馈控制,尚无法应对过大未知取水扰动,还有进一步改进空间。     

Pediculate Brachiopod Diandongia pista from the Lower Cambrian of South China

The Chengjiang Lagerstatte has been celebrated for prolific soft-bodied fossils. Based on specimens recently excavated in the Chengjiang Lagerstatte by the Early Life Institute, Northwest University, Diandongia pista Rong, 1974, is directly revealed to be a pediculate brachiopod, assigned to the Family Botsfordiidae, as is further confirmed by the exceptionally preserved vascular system including dorsal and ventral mantle canals. These specimens described herein exhibit some peculiarities, notably the extremely thin and long pedicles, which suggest that Diandongia is epifaunal rather than burrowing brachiopod. A study of this group of animals indicates that they may be vital to understand the relationship between the lingulids and the remaining brachiopods, and the character evolution of the early Cambrian brachiopods.     

Combined influences of irrigation diversions and associated subsurface return flows on river temperature in a semi-arid region

Irrigation activities alter water distribution and storage in arid and semi-arid regions worldwide. The removal of water from streams can drastically impact instream flows. However, irrigation water conveyance and application onto fields can create surface and subsurface hydrologic connections, or lateral inflows, that return some of this diverted water back to streams. Prior research has shown the impact of surface water diversions from streams on downstream warming that increases stress on aquatic species. However, the combined effects of flow depletion and irrigation-enhanced lateral inflows on stream temperature and river ecosystems remains poorly studied. To further understand these relationships, we combined intensive field monitoring over three irrigation seasons and thermal aerial imagery to identify irrigation-enhanced subsurface lateral inflow locations and evaluate their effects on stream flow and temperature patterns over a 2.5-km highly depleted study reach. Considering variable hydrology, weather, flow diversions, channel geometry and lateral inflows, we found irrigation-enhanced lateral inflows were the likely explanation for buffered longitudinal and diel warming patterns that prevented stressful or lethal thermal conditions for brown trout. These localized temperature effects were more pronounced in drier years, under high diversion rates and during high solar radiation intensity. We also found that lateral inflows corresponded with greater spatial variability of stream temperatures and potential thermal refugia. Study results illustrate the potential ecological consequences of reducing irrigation-enhanced lateral inflows and highlight the importance of hydrologic monitoring in irrigated arid river valleys. The role and preservation of these lateral inflows should be considered in water resources management related to irrigation efficiency and environmental flows.     

Isolating the impacts of anthropogenic water use within the hydrological regime of north India

The effects of anthropogenic water use play a significant role in determining the hydrological cycle of north India. This paper explores anthropogenic impacts within the region's hydrological regime by explicitly including observed human water use behaviour, irrigation infrastructure and the natural environment in the CHANSE (Coupled Human And Natural Systems Environment) socio-hydrological modelling framework. The model is constrained by observed qualitative and quantitative information collected in the study area, along with climate and socio-economic variables from additional sources. Four separate scenarios, including business as usual (BAU, representing observed irrigation practices), groundwater irrigation only (where the influence of the canal network is removed), canal irrigation only (where all irrigation water is supplied by diverted surface water) and rainfed only (where all human interventions are removed) are used. Under BAU conditions the modelling framework closely matched observed groundwater levels. Following the removal of the canal network, which forces farmers to rely completely on groundwater for irrigation, water levels decrease, while under a canal-only scenario flooding occurs. Under the rainfed-only scenario, groundwater levels similar to current business-as-usual conditions are observed, despite much larger volumes of recharge and discharge entering and leaving the system under BAU practices. While groundwater abstraction alone may lead to aquifer depletion, the conjunctive use of surface and groundwater resources, which includes unintended contributions of canal leakage, create conditions similar to those where no human interventions are present. Here, the importance of suitable water management practices, in maintaining sustainable water resources, is shown. This may include augmenting groundwater resources through managed aquifer recharge and reducing the impacts on aquifer resources through occasional canal water use where possible. The importance of optimal water management practices that highlight trade-offs between environmental impact and human wellbeing are shown, providing useful information for policy makers, water managers and users. © 2019 John Wiley & Sons, Ltd.