陆水水库建库近60年泥沙淤积、库区演变及影响

doi:10.11988/ckyyb.20240828

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (9): 10-16.DOI: 10.11988/ckyyb.20240828

陆水水库建库近60年泥沙淤积、库区演变及影响

刘心愿¹(), 李凌云¹^,², 张金武³, 张丹⁴

¹ raybet体育在线水利部长江中下游河湖治理与防洪重点实验室,武汉 430010
² 长江水利委员会汉江流域治理保护中心,武汉 430010
³ 长江水利委员会陆水试验枢纽管理局,湖北赤壁 437399
⁴ 湖北省碾盘山水利水电枢纽工程建设管理局,武汉 430010

收稿日期:2024-08-04 修回日期:2024-11-29 出版日期:2025-09-01 发布日期:2025-09-01
作者简介:
刘心愿(1981-),男,河南周口人,正高级工程师,博士,主要从事水文预报及调度、河流演变及治理等研究工作。E-mail: wishesliu@126.com
基金资助:
国家自然科学基金长江水科学研究联合基金项目(U2240224); 国家自然科学基金长江水科学研究联合基金项目(U2240206); 水利部三峡后续工作项目(CKSG2024272/HL); 水利部三峡后续工作项目(CKSG2024273/HL)

Sedimentation and Evolution of Lushui Reservoir and Their Impacts over the Past 60 Years since Construction

LIU Xin-yuan¹(), LI Ling-yun¹^,², ZHANG Jin-wu³, ZHANG Dan⁴

¹ Key Laboratory of River and Lake Regulation and Flood Control in the Middle and Lower Reaches of the Changjiang River of Ministry of Water Resources, Changjiang River Scientific Research Institute,Wuhan 430010,China
² Hanjiang River Basin Management and Protection Center of the Changjiang Water Resources Commission,Wuhan 430010,China
³ Lushui Experimental Junction Administration Bureau of the Changjiang Water Resources Commission,Chibi 437399,China
⁴ Construction Management Bureau for Nianpanshan Water Conservancy and Hydropower Junction Project in Hubei Province,Wuhan 430010, China

Received:2024-08-04 Revised:2024-11-29 Published:2025-09-01 Online:2025-09-01

摘要/Abstract

摘要：

研究库区泥沙淤积情况对于水库的运行和管理十分重要,结合陆水水库建库前及近期库区地形,复核了陆水水库建库前库容曲线,采用断面法和栅格地形法分析了陆水水库库区的淤积时空分布特征,开展了淤积重点区域的河道演变分析,并从多个方面综合分析了库区淤积的影响。总体而言,陆水水库泥沙淤积总量不大,但局部库段淤积比较突出,对防洪、航运、灌溉、发电等功能发挥带来了不利影响,建议采取机械清淤、加强汛期排沙调度等措施,控制库区泥沙淤积,保持水库有效库容。研究成果可为水库相关管理工作提供参考。

关键词: 陆水水库, 泥沙淤积, 地形法, 河道演变, 淤积影响

Abstract:

[Objective] This study systematically examines the characteristics of sediment deposition and river evolution in Lushui Reservoir over 60 years since its construction and evaluates their comprehensive impacts. [Methods] Based on pre-construction (1959) 1∶10 000 topographic maps and recent (2018) 1∶5 000 maps, sediment volumes and stage-capacity curves were calculated using the cross-section method and 10 m × 10 m grid-based method (combined with Simpson’s 3/8 rule). [Results] The total deposition was 32.397 million m³, accounting for only 4.6% of the total storage below the design flood level, indicating overall light siltation. However, the spatial distribution was highly uneven—74% of the deposition was concentrated below the flood-limit water level, with the Hongshang-Shikeng downstream 11km reach becoming the core deposition zone, accounting for 51% of the total (local maximum deposition thickness up to 11.79 m), while the Hongshang-Langkou reach was likely in a scouring state due to unregulated sand mining and reduced sediment inflow. For channel evolution, the thalweg in the Hongshang-Shikeng reach rose on average 6.27 m, and the shoreline at the 45 m dead water level elevation shrank markedly; maximum thalweg migration reached 660 m (at the Lashupu widening), and the depositional pattern tended toward a deltaic form—with the Hongshang-Shikeng reach dominated by main-channel deposition, and sections above Hongshang mainly showing floodplain deposition. Deposition significantly impaired reservoir functions: (1) For flood control, 6.856 million m³ of flood-control capacity was lost (4.2% loss rate), and the cross-section area in the Hongshang-Shikeng reach was reduced by 26% on average (up to 54%), markedly lowering discharge capacity and raising the regulated flood levels under design floods. (2) For beneficial use, 17.193 million m³ of active storage lost (equal to an annual power loss of 842 000 kW·h), and 12.29 million m³ between the dead water level and flood-limit level was lost (8.1% of mean annual irrigation withdrawal). (3) For navigation, thalweg elevations were generally at or above the 45 m dead water level elevation, severely restricting navigation during low-flow periods. [Conclusion] Although the overall sedimentation rate of Lushui Reservoir is low, local deposition poses a significant threat to flood-control and navigation functions. Mechanical dredging in the key reach (Hongshang-Shikeng) and optimization of sediment-flushing schedules during the flood season are urgently needed to control sediment and maintain effective storage capacity. These findings provide a scientific basis for sediment management in long-operating reservoirs and for the development of “modern reservoir operation and management matrix” proposed by the Ministry of Water Resources.

Key words: Lushui Reservoir, sedimentation, topographic method, river channel evolution, sedimentation impacts

中图分类号:

TV697.11

刘心愿, 李凌云, 张金武, 张丹. 陆水水库建库近60年泥沙淤积、库区演变及影响[J]. raybet体育在线院报, 2025, 42(9): 10-16.

LIU Xin-yuan, LI Ling-yun, ZHANG Jin-wu, ZHANG Dan. Sedimentation and Evolution of Lushui Reservoir and Their Impacts over the Past 60 Years since Construction[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(9): 10-16.

图/表 11

表1 已有研究成果对比

Table 1 Comparison of existing research results

成果来源	滞洪期(1961—1967年) 淤积量/(万m³)	蓄水运用期淤积量/(万m³)					计算方法
成果来源	滞洪期(1961—1967年) 淤积量/(万m³)	1967—1986年	1987—1991年	1991—2005年	1959—2005年	2005—2018年	计算方法
毛荣生等^[6]	360.4	1 550.1	252.6	—	>2 163.1	—	断面法
水文报告^[7,9]	193.9	832.7	—	317.0	>1 343.6	—	断面法
蔺秋生等^[8]	—	1 578.8	311.6	1 142.5	>3 032.9	—	断面法
本次计算	—	—	—	—	1 494.3	-189.7	断面法

表2 断面法计算成果分析

Table 2 Analysis of calculation results using cross-section method

断面平均间距/m	2 915	1 003	2 007	203
淤积量/(万m³)	2 115.4	4 594.5	5 149.5	3 189.7

图1 建库前水库水位-库容曲线复核计算

Fig.1 Verification of pre-construction stage-capacity curve

表3 栅格地形法计算成果分析

Table 3 Analysis of calculation results using grid-based topographic method

栅格尺寸/(m×m)	10×10	100×100	200×200
淤积量/(万m³)	3 239.7	3 191.5	3 203.0

表4 不同特征水位以下总淤积量

Table 4 Total sediment volume below different characteristic water levels

特征水位	高程/m	总淤积量/(万m³)
死水位	45.0	1 151.5
灌溉限制水位	50.5	2 097.7
汛限水位(主汛期)	53.0	2 380.5
正常蓄水位	55.0	2 870.8
防洪高水位	56.0	3 066.1
设计洪水位	56.5	3 150.9
校核洪水位	57.1	3 239.7

表5 不同河段淤积量及淤积强度统计

Table 5 Statistics of sedimentation volume and intensity in different segments

河段	距离/km	总淤积量/(万m³)	淤积强度/(m³·m^-1)
坝上—花庙	15.7	254.4	162
花庙—石坑	5.7	990.4	1 738
石坑—腊树铺	4.7	1 642.2	3 494
腊树铺—洪上	7.5	887.2	1 183
洪上—浪口	8.5	-534.5	-629

图2 建库以来库区冲淤分布

Fig.2 Distribution of erosion and deposition in reservoir since construction

图3 建库以来库区深泓高程变化

Fig.3 Changes in thalweg elevation in reservoir since construction

图4 典型断面变化

Fig.4 Changes in typical cross sections

图5 淤积重点库段河道演变平面变化

Fig.5 Planform evolution of key sedimentation segments

图6 设计洪水位以下洪上至腊树铺沿程过水断面面积淤损百分比

Fig.6 Reduction ratio of cross-sectional area along Hongshang-Lashupu reach below design flood level

[1]	王奕森, 周智伟, 李志晶, 李大志, 金中武. 滇中引水工程取水枢纽引水防沙试验研究[J]. raybet体育在线院报, 2025, 42(8): 188-197.
[2]	陈益民, 林荡, 阳甜甜, 郑保, 张国华, 李凌云, 郭超. 2023年下荆江湖南段“天字一号”护岸段崩岸分析[J]. raybet体育在线院报, 2025, 42(6): 8-13.
[3]	渠庚, 陈栋, 姚仕明, 王洪杨. 长江中下游弯曲河道治理研究进展[J]. raybet体育在线院报, 2025, 42(1): 20-27.
[4]	袁晶, 杨成刚. 三峡水库汛期沙峰预报技术及排沙调度实践[J]. raybet体育在线院报, 2024, 41(7): 1-7.
[5]	邹红梅, 陈芳, 杨成刚. 2022年“汛期反枯”对三峡库区泥沙冲淤的影响[J]. raybet体育在线院报, 2024, 41(7): 190-195.
[6]	廖宇昂, 刘瑜. 荆江陈家湾—突起洲分汊段河道演变与趋势分析[J]. raybet体育在线院报, 2024, 41(7): 196-202.
[7]	张成潇, 米博宇, 吕超楠, 赵汗青, 高宇, 任实. 高洪水期运行水位对三峡水库泥沙淤积的影响[J]. raybet体育在线院报, 2024, 41(6): 10-17.
[8]	渠庚, 卢金友, 马月华, 尹大聪, 雷文韬, 栾华龙, 李梦雨. 新条件下长江镇扬世业洲段演变对河流功能的影响[J]. raybet体育在线院报, 2023, 40(2): 177-185.
[9]	卢阳, 王玉璇, 曹磊, 张乾柱, 赵东. 乌江重庆段河道演变及其对航运的影响[J]. raybet体育在线院报, 2023, 40(2): 186-191.
[10]	姚仕明, 胡呈维, 渠庚. 三峡水库下游河道演变与生态治理研究进展[J]. raybet体育在线院报, 2021, 38(10): 16-26.
[11]	施骐, 张小峰, 许全喜. 不同水沙条件下顺直型河道交错边滩演变规律[J]. raybet体育在线院报, 2020, 37(4): 7-13.
[12]	金中武, 任实, 吴华莉, 朱帅, 王玉璇, 李秋荔. 三峡水库淤积排沙及河型转化规律[J]. raybet体育在线院报, 2020, 37(10): 9-15.
[13]	黄仁勇, 王敏, 张细兵, 刘亮, 任实, 周曼. 三峡水库汛期“蓄清排浑”动态运用方式初探[J]. raybet体育在线院报, 2018, 35(7): 9-13.
[14]	孙羽,李向阳,孙东坡,张晓雷,植凤娟. 抽水蓄能电站下库长系列年泥沙淤积特性研究[J]. raybet体育在线院报, 2018, 35(1): 5-10.
[15]	黄建成，赵萍，闫霞，马秀琴，周银军. 西藏扎拉水电站水库泥沙对电站运行影响试验研究[J]. raybet体育在线院报, 2017, 34(6): 7-11.

陆水水库建库近60年泥沙淤积、库区演变及影响

Sedimentation and Evolution of Lushui Reservoir and Their Impacts over the Past 60 Years since Construction

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 11

相关文章 15

编辑推荐

Metrics

本文评价