新时期新疆水库大坝建设的主要问题与对策建议

doi:10.12118/j.issn.1000-6060.2020.06.01

摘要/Abstract

摘要： 截止 2018 年，全疆（含兵团）已建、在建及拟建水库 722 座（包括电站水库），总库容 295.0 × 10⁸m³。有力地改善了水资源调控和利用效率，在灌溉、供水、防洪、发电、旅游等方面发挥了极其重要的作用。新时期按照水利部“水利工程补短板、水利行业强监管”的工作总基调，针对南北疆水资源配置不平衡问题、水资源利用不充分问题，谋划提出了兴建数十座大中型山区水库，以及提升已建水库大坝信息化管理水平、加强水库调度运行管理，在满足生态需水的前提下统筹生活、生产供水，最大程度发挥水库效益、确保水库安全运行。针对新时期气候变化条件下水库洪水风险分析、大坝建设需要重点关注的几项关键技术、山区水库替代平原水库、河流健康与生态调度、水库清淤与能力提升、水库信息化与智能调度以及延长服役期等问题进行了探讨，提出若干对策建议。

关键词: 水库, 大坝, 气候变化, 关键技术, 问题, 对策建议

Abstract: By 2018, 722 reservoirs (including power station reservoirs) will be built, with some of which had been built and are still partly under construction in Xinjiang (including Xingjing Production and Construction Corps), China giving a total storage capacity of nearly 295×10⁸m³. These reservoirs have effectively enhanced the efficiency of regulating and utilizing water resources and played an extremely crucial role in irrigation, water supply, flood control, power generation, tourism, etc. In line with the working principle given by the Ministry of Water Resources, “compensating the shortcomings of water conservancy projects and enhancing the supervision of water conservancy industry”, plans to address the problem of the imbalanced and insufficient utilization in water resources are proposed. These include building dozens of large and medium-sized mountain reservoirs, improving the information digitization management of dams, providing drinking water and industrial water against the background of satisfying ecological water, maximizing the benefits, and ensuring the safe operations of reservoir. This paper presents the work in terms of the flood risk analysis under climate changes, several key technologies used for dam construction, the replacement of plain reservoirs with mountain reservoirs, the concerns about river health and ecological regulation, reservoir dredging and its capacity enhancement, the digitization and intelligent dispatch of reservoirs, and extending the operating time of reservoirs.

Key words: reservoir, dam, climate change, key technology, issue, suggestions

李江, 柳莹, 刘生云, 彭兆轩, 吴涛 . 新时期新疆水库大坝建设的主要问题与对策建议[J]. 干旱区地理, 2020, 43(6): 1409-1416.

LI Jiang, LIU Ying, LIU Sheng-yun, PENG Zhao-xuan, WU Tao. Main problems and countermeasures of reservoir dam construction in Xinjiang in the new period[J]. Arid Land Geography, 2020, 43(6): 1409-1416.

参考文献 31

[1]	邓铭江, 于海鸣. 新疆坝工建设[M]. 北京: 中国水利水电出版社, 2011. [DENG Mingjiang, YU Haiming. Dam construction prog⁃ ress in Xinjiang [M]. Beijing: China Water & Power Press, 2011. ]
[2]	邓铭江. 严寒地区碾压混凝土筑坝技术及工程实践[J]. 水力发电学报, 2016, (9): 111-120. [DENG Mingjiang. RCC dam build⁃ ing technology for extreme cold regions and engineering practices [J]. Journal of Hydroelectric Engineering, 2016, (9): 111-120. ]
[3]	苗喆. 世界第一高混凝土面板坝——新疆大石峡水利枢纽工程正式开工建设[J]. 水力发电, 2018, (2): 36. [MIAO Ji. The world’s tallest concrete face dam: Xinjiang Dashixia water conservancy project officially started construction[J]. Water Power, 2018, (2): 36. ]
[4]	李江, 柳莹, 黄涛. 新疆中型水库坝型与枢纽布置的关键技术应用实践[J]. 水利水电技术, 2018, 49(12): 87-96. [LI Jiang, LIU Ying, HUANG Tao. Key technology application practice of dam type and hub arrangement of Xinjiang medium- sized reservoir[J]. Water Resources and Hydropower Engineering, 2018, 49(12): 87- 96. ]
[5]	邓铭江, 于海鸣. 新疆坝工技术进展[J]. 岩土工程学报, 2010, 11: 1678- 1687. [DENG Mingjiang, YU Haiming. Dam construc⁃ tion progress in Xinjiang[J]. Chinese Journal of Geotechnical Engi⁃ neering, 2010, 11: 1678-1687. ]
[6]	新疆水利厅. 新疆维吾尔自治区水中长期供求规划[R]. 2016. [Xinjiang Water Conservancy. Long-term water supply and demand planning in Xinjiang Uygur Autonomous Region[R]. 2016. ]
[7]	邓铭江, 李湘权, 龙爱华, 等. 支撑新疆经济社会跨越式发展的水资源供需结构调控分析[J]. 干旱区地理, 2011, 34(3): 379- 390. [DENG Mingjiang, LI Xiangquan, LONG Aihua, et al. Regu⁃ lation of supply and demand structure of the water resources and support economic and social leap- forward development of protec⁃ tion measures[J]. Arid Land Geography, 2011, 34(3): 379-390. ]
[8]	邓铭江. 新疆十大水生态环境保护目标及其对策探析[J]. 干旱区地理, 2014, 37(5): 865-874. [DENG Mingjiang. Top ten ecolog⁃ ical environment protection targets and its solutions in Xinjiang, China[J]. Arid Land Geography, 2014, 37(5): 865-874. ]
[9]	邓铭江. 南疆未来发展的思考——塔里木河流域水问题与水战略研究 [J], 干旱区地理, 2016, 39(1): 1- 11. [DENG Mingjiang. Prospecting development of south Xinjiang: Water strategy and problem of Tarim River Basin[J]. Arid Land Geography, 2016, 39 (1): 1-11. ]
[10]	商莉, 黄玉英, 毛炜峄. 2015 年夏季南疆地区高温冰雪洪水特征 [J]. 冰川冻土, 2016, 38(2): 480- 487. [SHANG Li, HUANG Yuying, MAO Weiyi. Features of the snow and ice meltwater flood caused by high temperature in the Southern Xinjiang Region dur⁃ ing the summer of 2015[J]. Journal of Glaciology and Geocryology, 2016, 8(2): 480-487. ]
[11]	刘思海, 侍克斌, 张宏科. 克孜尔水库泥沙淤积分析及排沙对策探讨 [J]. 人民黄河, 2018, 40(7): 18- 21. [LIU Sihai, SHI Kebin, ZHANG Hongke. Analysis of sediment deposition and the counter⁃ measures for sediment deposition in Kezier Reservoir[J]. Yellow River, 2018, 40(7): 18-21. ]
[12]	李淑珍. 新疆山区水库工程生态基流在水资源平衡分析中定位探讨[J]. 水利技术监督, 2018, (5): 93-97. [LI Shuzhen. Discus⁃ sion on positioning of ecological baseflow of Xinjiang mountain reservoir project in water resources balance analysis[J]. Technical Supervision in Water Resources, 2018, (5): 93-97. ]
[13]	李江, 李淑珍, 柳莹, 等. 新疆水库大坝建设的生态环境保护技术体系与实践[C] // 水库大坝高质量建设与绿色发展—中国大坝工程学会 2018 学术年会论文集. 中国大坝工程学会, 2018: 11. [LI Jiang, LI Shuzhen, LIU Yin, et al. Ecological environment protection technology system and practice of dam construction in Xinjiang[C]//Reservoir dam high quality construction and green development: Proceedings of the 2018 Annual Conference of the Chinese Society of Dam Engineering. 2018: 11. ]
[14]	杨荣金, 孟伟, 段宁, 等. 天山北坡经济带生态文明建设战略研究 [J]. 中国工程科学, 2017, 19(4): 40- 47. [YANG Rongjing, MEN Wei, DUAN Ning, et al. Ecological civilization construction strategies in the Tianshan Mountain northern slope economic belt [J]. Engineering Science, 2017, 19(4): 40-47. ]
[15]	罗纬邦. 分层取水技术在 KLSK 水利枢纽建设中的应用[J]. 水利水电技术, 2013, 44(6): 126-129, 138. [LUO Weibang. Appli⁃ cation of layered water-taking technology to construction of KLSK water control project[J]. Water Resources and Hydropower Engi⁃ neering, 2013, 44(6): 126-129, 138. ]
[16]	杨国华, 李江, 王荣鲁, 等. 塔河流域在役大中型水库风险评估研究[J]. 水利规划与设计, 2020, (1): 64-68. [YANG Guohua, LI Jiang, WANG Ronglu, et al. Study on risk assessment of large and medium reservoirs in service in Tarim River Basin[J]. Water Re⁃ sources Planning and Design, 2020, (1): 64-68. ]
[17]	武清, 李江, 黄涛. 气候变化下山溪性河流水库防洪减灾措施 [J]. 水利水电技术, 2019, 50(12): 98- 105. [WU Qing, LI Jiang, HUANG Tao. Flood prevention and mitigation measures for moun⁃ tain river reservoirs under climate change[J]. Water Resources and Hydropower Engineering, 2019, 50(12): 98-105. ]
[18]	包永侠, 唐德胜. 阿尔塔什大坝天然砂砾石料填筑施工参数的选择 [J]. 水力发电, 2018, 44(2): 37- 39. [BAO Yongxia, TANG Desheng. Parameters selection for natural sand and gravel filling material construction in Aertashi Dam[J]. Water Power, 2019, 50 (12): 98-105. ]
[19]	杜彬. 聚氨酯硬质泡沫在大坝工程中的应用研究[J]. 水利水电科技进展, 2002, (4): 14- 16. [DU Bin. Application of polyure⁃ thane rigid foam to dam projects[J]. Advances in Science and Technology of Water Resources, 2002, (4): 14-16. ]
[20]	张国新, 刘毅, 刘有志, 等. 高混凝土坝温控防裂研究进展[J]. 水利学报, 2018, 49(9): 1068-1078. [ZHANG Guoxin, LIU Yi, LIU Youzhi, et al. Reviews on temperature control and crack preven⁃ tion of high concrete dam[J]. Journal of Hydraulic Engineering, 2018, 49(9): 1068-1078. ]
[21]	亚森•钠斯尔, 童耀. 古河槽超深砂砾石层帷幕灌浆试验研究 [J]. 水利建设与管理, 2019, 39(10): 26-30. [NASR Yasen, TONG Yao. Study on curtain grouting test of ultra- deep sand and gravel layer in ancient river channel[J]. Water Resources Development & Management, 2019, 39(10): 26-30. ]
[22]	王建帮, 李振谦, 唐德胜. 数字智能化监控系统在阿尔塔什大坝工程质量管理中的应用[J]. 水利建设与管理, 2019, 39(8): 1-4, 13. [WANG Jianbang, LI Zhenqian, TANG Desheng. Application of digital intelligent monitoring system in quality management of Altash dam project[J]. Water Resources Development & Manage⁃ ment, 2019, 39(8): 1-4, 13. ]
[23]	杨军, 任志农. 乌鲁瓦提水利枢纽工程高边坡加固处理施工技术[J]. 水利水电技术, 2003, (12): 51-53. [YANG Jun, REN Zhi⁃ nong. Anchoraging technique of high side slope in Wuluwati Hy⁃ droproject[J]. Water Resources and Hydropower Engineering, 2003, (12): 51-53. ]
[24]	刘永强, 刘志辉. 新疆融雪洪水预警决策支持系统研究[J]. 干旱区资源与环境, 2007, (2): 110-113. [LIU Yongqiang, LIU Zhihui. Development about decision support system for snowmelt flood prediction of Xinjiang[J]. Journal of Arid Land Resources and En⁃ vironment, 2007, (2): 110-113. ]
[25]	彭穗萍. 下坂地水库替代部分平原水库可行性分析论证[J]. 西北水力发电, 2002, 18(2): 8-11. [PEN Huiping. Feasibility analysis and reasoning of Xiabandi Reservoir substituting some of plain reser⁃ voirs[J]. Journal of Northwest Hydroelectric Power, 2002, 18(2): 8-11. ]
[26]	张少博, 何新林, 刘兵, 等. 新疆山区水库参与调度后平原水库废弃可行性分析 [J]. 长江科学院院报, 2018, 35(1): 23- 28. [ZHANG Shaofu, HE Xinlin, LIU Bing, et al. Feasibility of aban⁃ doning plain reservoirs after the operation of mountain reservoirs in Xinjiang[J]. Journal of Yangtze River Scientific Research Insti⁃ tute, 2018, 35(1): 23-28. ]
[27]	李丽君, 张小清, 陈长清, 等. 近 20 a 塔里木河下游输水对生态环境的影响 [J]. 干旱区地理, 2018, 41(2): 238- 247. [LI Lijun, ZHANG Xiaoqing, CHEN Changqing, et al. Ecological effects of water conveyance on the lower reaches of Tarim River in recent twenty years[J]. Arid Land Geography, 2018, 41(2): 238-247. ]
[28]	邓铭江, 黄强, 张岩, 等. 额尔齐斯河水库群多尺度耦合的生态调度研究[J]. 水利学报, 2017, 48(12): 1387-1398. [DENG Min⁃ gjiang, HUANG Qiang, ZHANG Yan, et al. Study on ecological scheduling of multiscale coupling of reservoir group[J]. Journal of Hydraulic Engineering, 2017, 48(12): 1387-1398. ]
[29]	曹慧群, 李青云, 黄茁, 等. 我国水库淤积防治方法及效果综述 [J]. 水力发电学报, 2013, 32(6): 183-189. [CAO Huiqun, LI Qin⁃ gyun, HUANG Zhuo, et al. Overview on control measures and their effects against reservoir sedimentation in China[J]. Journal of Hydroelectric Engineering, 2013, 32(6): 183-189. ]
[30]	曹文洪, 刘春晶. 水库淤积控制与功能恢复研究进展与展望[J]. 水利学报, 2018, 49(9): 1079-1086. [CAO Wenhong, LIU Chun⁃ jing. Advance and prospect in research on reservoir sediment con⁃ trol and functional restoration[J]. Journal of Hydraulic Engineer⁃ ing, 2018, 49(9): 1079-1086. ]
[31]	张建云, 刘九夫, 金君良. 关于智慧水利的认识与思考[J]. 水利水运工程学报, 2019, (6): 1- 7. [ZHANG Jianyun, LIU Jiufu, JIN Junliang. Understanding and thinking about smart water conservancy[J]. Hydro-Science and Engineering, 2019, (6): 1-7. ]