基于分布式水文模型的中小河流洪水预报技术

中小河流大多位于资料短缺的山丘区,洪水具有突发性强、汇流时间快、预见期短以及分布广的特点。中小河流洪水预报首要目的和任务是预警预报,预报方式应以自动预报为主,以实现及时预警,最大程度地避免人员伤亡,减轻灾害损失。本文分析了中小河流洪水预报的特点与难点,提出了中小河流洪水预报的思路及实用预报模型与方法,开展了基于分布式水文模型的中小河流洪水预报技术在新安江上游屯溪流域预警预报中的应用研究,以期为当前所开展的全国中小河流洪水预警预报系统建设提供参考。研究表明:分布式水文模型是资料短缺地区中小河流洪水预报的有效方法,基于分布式水文模型的洪水预报技术能够满足中小河流洪水自动预警预报的生产需要。     

SWAT模型在伊犁河上游缺资料区的应用

 在分布式水文模型中,探索产生分布式降水数据的方法是该领域研究的热点之一,发展基于水文物理过程的模型校准方法是实践PUB的热点与难点。基于SWAT分布式水文模型,以资料稀缺的伊犁河上游为研究区域,针对流域的水资源评价关键问题,首先准确描述区域的降水空间分布特征,并基于流域水文过程采用综合流域特征、多时间尺度、多变量和多站点的适宜性模型校准新方法,取得了满意的模拟结果,表明模型较好地再现了流域的水文过程。另外,完善水文机理研究,提高降水及下垫面相关参数的观测水平是改善模型模拟的有效途径。     

An experiment on reservoir representation schemes to improve hydrologic prediction: coupling the national water model with the HEC-ResSim

ABSTRACT

This study experiments with reservoir representation schemes to improve the ability to model active water management in the National Water Model (NWM). For this purpose, we developed an integrated water management model, NWM-ResSim, by coupling the NWM with HEC-ResSim, and two reservoir representation schemes are tested: simulation of reservoir operations and retrieval of scheduled operations. The experiments focus on a pilot reservoir domain in the Russian River basin – Lake Mendocino, California – and its contributing watershed. The evaluation results suggest that the NWM-ResSim improves the simulation performance of reservoir outflow from this managed reservoir over the NWM default level pool routing scheme. The degree of this improvement depends on the suitability of the operation guidance; the reservoir operations simulation scheme could have acceptable errors for the purposes of water resources management, but not for flood operations. Results of the retrieval scheme of scheduled operations demonstrated better performance for sub-daily flood operations.     

多功能水文频率分析计算软件的研制和应用

介绍了多功能水文频率分析计算软件的设计及功能扩充，尤其是增加了采用鼠标拉动曲线直接屏幕适线的功能。本软件在生产实践中，获得了较好的应用效果，不仅功能多，而且实用方便。     

Atmospheric hydrological budget with its effects over Tibetan Plateau

1IntroductionThe Tibetan Plateau is the most prominent feature located at unique latitudes in the world and shows special dynamic and thermal effects, thus responsible for a conspicuous hydrological cycle in the atmosphere within Asian monsoon areas, and an extremely sensitive region of land-air interactions in East Asia. A lot of researches have dealt with Tibetan dynamic and thermal effects on atmospheric circulation (Ye and Gao, 1979; Zhang etal., 1988; Ye and Fang, 1999; Zheng etal., 2…     

青藏高原大气水汽收支特征及影响

Based on 1961-2000 NCEP/NCAR monthly mean reanalysis datasets, vapor transfer and hydrological budget over the Tibetan Plateau are investigated. The Plateau is a vapor sink all the year round. In summer, vapor is convergent in lower levels (from surface to 500 hPa) and divergent in upper levels (from 400 to 300 hPa), with 450 hPa referred to as level of non-divergence. Two levels have different hydrologic budget signatures: the budget is negative at the upper levels from February to November, i.e., vapor transfers from the upper levels over the plateau; as to the lower, the negative (positive) budget occurs during the winter (summer) half year. Evidence also indicates that Tibetan Plateau is a "vapor transition belt", vapor from the south and the west is transferred from lower to upper levels there in summer, which will affect surrounding regions, including eastern China, especially, the middle and lower reaches of the Yangtze. Vapor transfer exerts significant influence on precipitation in summertime months. Vapor transferred from the upper layers helps humidify eastern China, with coefficient -0.3 of the upper budget to the precipitation over the middle and lower reaches of the Yangtze (MLRY); also, vapor transferred from east side (27.5°-32.5°N) of the upper level has remarkable relationship with precipitation, the coefficient being 0.41. The convergence of the lower level vapor has great effects on the local precipitation over the plateau, with coefficient reaching 0.44, and the vapor passage affects the advance and retreat of the rainbelt. In general, atmospheric hydrologic budget and vapor transfer over the plateau have noticeable effects on precipitation of the target region as well as the ambient areas.     

黄河河源区变化环境下分布式水文模拟

将黄河河源区划分为38个自然子流域,利用分布式水文模型模拟径流量,采用唐乃亥水文站逐年、月实测径流资料进行验证,得到了较好的模拟效果。文章建立了5种土地覆被情景模型及24组不同气温和降水的情景组合,分别模拟不同情景下的年径流量。模拟结果表明,随着植被覆盖度的增加,流域年径流量减小,蒸发量增加。当气温降低2_oC且降水增加20%时,流域径流量增加得最大,增加39.69%。     

气候变化下极端水文事件的研究进展

气候异常变化导致洪涝灾害、干旱等极端水文事件的发生及其增加的水灾害风险正成为人类生存所面临的重大挑战。近年来,开展气候变化背景下流域极端水文事件的变化趋势、发生机理及其对气候变化的响应与预测研究正逐渐受到国内外众多学者的关注。本文从极端水文事件的定义、研究方法、水文极值分布函数、观测事实及模拟研究等方面分析评述了极端水文事件问题的研究现状和研究成果。在此基础上,讨论了研究现状存在的问题并对该领域未来研究方向进行了展望。     

Changes in an urban water resource,an example from Sydney,Australia

This paper examines present and future resource utilization in the tidal section of the Georges River in the southern part of Sydney. Over the last 30 years, the physical characteristics of the river have changed as a result of urbanization, changed hydrologic regime and sand dredging. Urbanization has resulted in an increase in population from 190,000 in 1947 to 550,000. This has resulted in an increase in runoff, sediment input to the river and waste disposal. The change in hydrologic regime has resulted in a substantial increase in the magnitude and frequency of flooding which has increased erosion. Sand dredging has increased the channel capacity, enlarged the tidal prism and increased water turbidity. It has also resulted in extensive bank erosion in the upper part of the river and extensive deposition lower down as tailings are deposited. Although most of these changes have resulted in the deterioration of environmental quality, use of the river for recreation and as an urban amenity has increased.