白鹤滩库区水沙变化及冲淤特性

罗刚; 肖潇; 吴迪; 吉沙日夫; 卢俊

doi:10.11988/ckyyb.20241217

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长江科学院院报 ›› 2025, Vol. 42 ›› Issue (8) : 38-43. DOI: 10.11988/ckyyb.20241217

河湖保护与治理

白鹤滩库区水沙变化及冲淤特性

罗刚 ¹ ,
肖潇 ² ,
吴迪 ¹ ,
吉沙日夫 ¹ ,
卢俊 ¹

作者信息 +

Water-Sediment Variation and Characteristics of Erosion and Deposition in Baihetan Reservoir Area

LUO Gang ¹ ,
XIAO Xiao ² ,
WU Di ¹ ,
JISHA Ri-fu ¹ ,
LU Jun ¹

Author information +

文章历史 +

摘要

深入分析白鹤滩库区水沙及冲淤特性的变化规律,是白鹤滩库区河段诸多工程问题的基础支撑。基于实测水沙、地形及水流等观测资料,采用水沙关系分析、输沙量计算及冲淤量计算等方法研究库区水沙特征及冲淤规律。结果表明:乌东德与白鹤滩水电站相继运行后,河段年径流量略有下降,年输沙量剧降90%以上;月均径流量分布重分配,12月份径流量增加,7月份径流量减少。从整体来看河段呈淤积趋势, 2021—2023年总淤积量达到1 263万m³,而白鹤滩库尾区域,受乌东德坝下泄水流条件的影响呈现冲刷态势。乌东德坝下游20 km范围内水流非恒定流特性强,动能大,挟沙能力强,导致显著冲刷;下游河段水位趋于稳定,流速减缓,挟沙能力弱,加之支流入汇泥沙补给,共同作用促成库区河段淤积。

Abstract

[Objective] This study aims to investigate the dramatic changes in water-sediment processes within the Jinsha River reservoir area following the impoundment and operation of the Wudongde and Baihetan cascade hydropower stations. Using multi-source observational data, the study reveals the variation patterns of water and sediment fluxes between the two dams, the spatiotemporal distribution characteristics of riverbed erosion and deposition, and their driving mechanisms. The findings provide scientific support for reservoir safety operation, navigation channel management, and ecological conservation. [Methods] The study was conducted using runoff-sediment transport data from 2015 to 2023 at the Wudongde and Baihetan hydrological stations, fixed cross-sectional topographic surveys from 2016 to 2023, and hydrodynamic measurements collected downstream of the Wudongde Dam in 2023. Water-sediment relationship analysis was employed to examine the response patterns between runoff and sediment transport. Erosion and deposition volumes were calculated using the cross-sectional method, with 825 m water level as the reference and the channel storage volume estimated via the frustum formula. Spatial variations of erosion and deposition were quantified by overlaying thalweg line and comparing morphological changes of typical cross-sections (JC199, JC153, JC126). [Results] 1) Water-sediment flux variations: Annual runoff exhibited a slight decrease, 2% at the Wudongde station and 17.8% at the Baihetan station. Annual sediment transport plummeted by more than 90%, primarily due to the “cumulative sediment retention effect” of upstream reservoirs. Intra-annual runoff distribution demonstrated a “peak-shaving and valley-filling” pattern, with a 22%-48% increase in December and a 16%-38% decrease in July. Sediment transport was concentrated from June to October (accounting for over 63%), yet monthly averages dropped by more than 95%. A progressive downstream sedimentation trend was observed in September. 2) Spatiotemporal evolution of erosion and deposition: erosion dominated during dry season (October-May), while deposition dominated the wet season (May-October). From 2021 to 2023, a net deposition volume reached 12.63 million m³, showing an overall cumulative trend. Spatially, a strong erosion zone formed at the reservoir tail driven by the high-kinetic-energy discharges from the Wudongde Dam. The core deposition area in the main reservoir was found 25-75 km upstream of the dam. In the tributary-affected zone, the Heishui River confluence showed prominent deposition. 3) Driving mechanisms of erosion and deposition: In terms of hydrodynamic forces, erosion was triggered by high flow velocities and strong sediment-carrying capacities within 20 km downstream of the Wudongde Dam, while beyond this zone, deposition was promoted by slower flows and weaker sediment-carrying capacities. Regarding tributary replenishment, tributaries such as the Pudu River, Xiaojiang River, and Heishui River contributed an average annual sediment transport of 5.73 million tons (2011-2022), accounting for over 46% of the deposition volume in the reservoir area. [Conclusions] The operation of cascade hydropower stations has restructured the water-sediment process. Although the runoff volume decreased slightly, its intra-annual redistribution was significant, and the sediment transport plummeted by 96% due to the “cumulative sediment retention effect”, with sediment being concentrated in flood season. The erosion and deposition in the reservoir area exhibit a spatial pattern of “erosion at the tail and deposition in the head”. The reservoir tail is eroded by the discharged flow, while the main reservoir experiences deposition due to reduced flow velocity and tributary replenishment, with the confluence of the Heishui River being a key source of deposition. A clear long-term deposition trend is observed, and it is necessary to focus on the high-risk deposition zone 25-75 km upstream of the dam and the sections with drastic morphological changes at tributary estuaries. These findings provide a quantitative basis for the joint operation of cascade reservoirs, navigation channel maintenance, and sediment management.

导出引用

罗刚, 肖潇, 吴迪, 等. 白鹤滩库区水沙变化及冲淤特性[J]. 长江科学院院报. 2025, 42(8): 38-43 https://doi.org/10.11988/ckyyb.20241217

LUO Gang, XIAO Xiao, WU Di, et al. Water-Sediment Variation and Characteristics of Erosion and Deposition in Baihetan Reservoir Area[J]. Journal of Changjiang River Scientific Research Institute. 2025, 42(8): 38-43 https://doi.org/10.11988/ckyyb.20241217

中图分类号： TV697

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https://doi.org/10.11988/ckyyb.20170109

摘要

采用实测典型水沙过程,对溪洛渡、向家坝、三峡梯级水库基于沙峰调度和基于汛期“蓄清排浑”动态使用的联合排沙调度方式开展了计算研究。结果表明:基于沙峰调度的梯级水库联合排沙调度方式从定性分析来看有利于提高梯级水库出库沙量,但提高的幅度有限;基于汛期“蓄清排浑”动态使用的梯级水库联合排沙调度方式有利于提高梯级水库出库沙量,且提高的幅度相对较大。通过计算研究提出了基于沙峰调度和基于汛期“蓄清排浑”动态使用的溪洛渡、向家坝、三峡梯级水库联合排沙调度方案,研究成果可为溪洛渡、向家坝、三峡梯级水库汛期泥沙调度提供科技支撑。

(HUANG

Ren-yong

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Min

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摘要

三峡水库泥沙问题直接关系到水库库容的长效保持。选取典型高洪水期,基于数值模型探究入库水沙量级、水沙异步及运行水位对三峡库区沙峰输移和淤积排沙的影响。结果表明:入库洪峰的增大抑制了涪陵沙峰比的衰减,并导致更多泥沙输运至坝前,使得坝前沙峰降幅受运行水位的抬升更为显著;变动回水区较常年回水区更易受到入库水沙异步影响,且随着来沙系数的增大,由低水位抬升时淤积占比更高;水库排沙比受入库水沙异步影响有限,且随着入库洪峰、沙峰的增大,排沙比增加的同时对运行水位抬升导致的衰减更为敏感。研究成果初步揭示了入库水沙异步及运行水位对库区沙峰运动与淤积的影响,可为三峡水库汛期优化沙峰排沙调度提供参考。

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