隔水幕分层取水研究进展及应用现状

邢领航; 贺蔚; 张健; 练继建; 马超

doi:10.11988/ckyyb.20181279

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raybet体育在线院报 ›› 2020, Vol. 37 ›› Issue (3) : 18-25. DOI: 10.11988/ckyyb.20181279

水资源与环境

隔水幕分层取水研究进展及应用现状

邢领航¹, 贺蔚², 张健², 练继建³, 马超³

作者信息 +

Present Research and Application of Temperature-control Curtain in Stratified Reservoir

XING Ling-hang¹, HE Wei², ZHANG Jian², LIAN Ji-jian³,MA Chao³

Author information +

文章历史 +

摘要

分层水库春夏季下泄低温水效应显著,分层取水是解决上述问题的有效手段。隔水幕是一种较为新型的分层取水方案,具有造价低廉、发电水头损失小、运行灵活、施工便利等优点,对我国大量改建、扩建及新建水库具有重大的研究和应用价值。目前隔水幕在美国和日本部分水库已有工程应用和研究成果,其中美国主要关注下方过流的顶部挡水幕,而日本主要关注中小型水库。国内隔水幕分层取水研究还处于起步阶段,与当前巨大的工程需求不相适应。因此,在借鉴已有国际经验的同时,也需要针对我国水库特点,尤其是诸多大型深水水库,进行自主研发,提出一套适用于我国的隔水幕分层取水理论和施工、运行、调控技术。梳理了现有水库隔水幕分层取水的研究现状,并剖析了研究及应用中存在的各类问题,并对隔水幕后续的研究及应用提出了建议。

Abstract

Discharged low-temperature water in stratified reservoir in spring and summer brings about ecological and environmental problems to the downstream areas. Selective withdrawal is an effective method to mitigate this problem. As a new facility of selective withdrawal of water, temperature-control curtain has advantages of low cost, less head loss, flexible operation and convenient construction, and is of vital academic and practical significance to the construction and management of reservoir. Currently there has been some engineering application and research results concerning temperature-control curtain in the USA and Japan, while the research in China is still preliminary. In the USA, research focuses on top curtain with discharge below, while in Japan, mid-and-small-sized reservoirs are the research emphasis. In China, the demand for research in temperature-control curtain is huge. In view of this, we should work on the theory and technology for the construction, operation, and regulation of temperature-control curtain according to the characteristics of reservoirs in China, particularly, large-scale deep reservoirs. In this paper we summarize the present research and application of temperature-control curtain in stratified reservoir, analyze the research limitations, and give some advices on further research and application.

导出引用

邢领航, 贺蔚, 张健, 练继建, 马超. 隔水幕分层取水研究进展及应用现状[J]. raybet体育在线院报. 2020, 37(3): 18-25 https://doi.org/10.11988/ckyyb.20181279

XING Ling-hang, HE Wei, ZHANG Jian, LIAN Ji-jian,MA Chao. Present Research and Application of Temperature-control Curtain in Stratified Reservoir[J]. Journal of Changjiang River Scientific Research Institute. 2020, 37(3): 18-25 https://doi.org/10.11988/ckyyb.20181279

中图分类号： TV6

参考文献

[1] 庞琼,王士军,倪小荣,等.世界已建高坝大库统计分析.水利水电科技进展,2012,32(6):34-37,59.
[2] International Commission on Large Dams. World Register of Dams. http://www.icold-cigb.net/GB/World_register/world_register.asp.
[3] 李宗坤,葛巍,王娟,等.中国大坝安全管理与风险管理的战略思考.水科学进展, 2015,26(4):589-595.
[4] 中国水利年鉴编纂委员会.中国水利年鉴.北京:中国水利水电出版社,2013.
[5] 郑守仁.我国高坝大库建设及运行安全问题探讨//贾金生,陈云华.水库大坝建设与管理中的技术进展:中国大坝协会2012学术年会论文集.郑州:黄河水利出版社,2012:25-33.
[6] HE W, LIAN J, ZHANG J, et al. Impact of Intra-annual Runoff Uniformity and Global Warming on the Thermal Regime of a Large Reservoir. Science of the Total Environment, 2019, 658:1085-1097.
[7] 王冠.大型深水库纵竖向二维水温模拟.南京:河海大学,2007.
[8] MILSTEIN A, ZORAN M. Effect of Water Withdrawal from the Epilimnion on Thermal Stratification in Deep Dual-purpose Reservoirs for Fish Culture and Field Irrigation. Aquaculture International, 2001, 9(1): 81-86.
[9] ARBAT-BOFILL M, SANCHEZ-JUNY M, BLADE E, et al. Hydrodynamics of Ribarroja Reservoir (Ebro River, Spain): Water Temperature, Water Velocities and Water Age//River Flow 2014—Proceedings of the International Conference on Fluvial Hydraulics. Lausanne, Switzerland. September 3-5, 2014.
[10] WANG S, QIAN X, HAN B, et al. Effects of Local Climate and Hydrological Conditions on the Thermal Regime of a Reservoir at Tropic of Cancer, in Southern China. Water Research, 2012, 46(8): 2591-2604.
[11] ANOHIN V V, IMBERGER J, ROMERO J R, et al. Effect of Long Internal Waves on the Quality of Water Withdrawn from a Stratified Reservoir. Journal of Hydraulic Engineering, 2006, 132(11): 1134-1145.
[12] CRAIG S, JORG I. The Initial Response of a Stratified Lake to a Surface Shear Stress. Journal of Fluid Mechanics, 1996, doi: 10.1017/S0022112096001917.
[13] JAMALI M, AGHSAEE P. Effect of a Contraction on Selective Withdrawal of a Linearly Stratified Fluid from a Line Sink. Physics of Fluids, 2007, 19(10660210).
[14] 高学平,陈弘,王鳌然,等.糯扎渡水电站多层进水口下泄水温试验研究.水力发电学报, 2010,29(3):126-131.
[15] CASTELLETTI A, YAJIMA H, GIULIANI M, et al. Planning the Optimal Operation of a Multioutlet Water Reservoir with Water Quality and Quantity Targets. Journal of Water Resources Planning and Management, 2014, 140(4): 496-510.
[16] 杨智,叶清华,王成,等.基于Delft3D的水库水温模拟技术方法:以观景口水库为例.环境影响评价,2016,38(4):47-50.
[17] SOLEIMANI S, BOZORG-HADDAD O, SAADATPOUR M, et al. Optimal Selective Withdrawal Rules Using a Coupled Data Mining Model and Genetic Algorithm. Journal of Water Resources Planning and Management, 2016, 142(0401606412).
[18] 常理,纵霄,张磊.光照水电站水库水温分析预测及分层取水措施.水电站设计, 2007,23(3):30-32.
[19] 徐茂杰.大型水电站取水口分层取水水温数值模拟.天津:天津大学,2008.
[20] 陈弘.大型水库分层取水下泄水温模型试验与数值模拟研究.天津:天津大学,2013.
[21] 张少雄.大型水库分层取水下泄水温研究.天津:天津大学,2012.
[22] 张信,乾爱国,王鹏远,等.戛洒江一级水电站下泄水温对鱼类的影响.环境影响评价, 2016,38(3):22-23.
[23] 张士杰,彭文启,刘昌明.高坝大库分层取水措施比选研究.水利学报,2012,43(6):653-658.
[24] 高学平,任庆钰.不同类型取水口下泄水温试验研究.水力发电学报,2015,34(6):149-153.
[25] 薛联芳,顾洪宾,冯云海.减缓水电工程水温影响的调控措施与建议.环境影响评价, 2016,38(3):5-8.
[26] 谢玲丽,仇金长,高文,等.聚仙庙水库平面钢闸门分层取水设计及应用.人民黄河, 2015,37(12):139-141.
[27] 练继建,杜慧超,马超.隔水幕布改善深水水库下泄低温水效果研究.水利学报, 2016,47(7):942-948.
[28] 薛联芳.基于下泄水温控制考虑的水库分层取水建筑物设计.中国水利, 2007(6):45-46,58.
[29] 高学平,李妍,宋慧芳.糯扎渡水电站进水口分层取水数值模拟研究.水力发电学报, 2010,29(6):132-137.
[30] 游湘,何月萍,王希成.进水口叠梁门分层取水设计研究.水电站设计, 2011,27(2):32-34.
[31] 汤世飞.光照水电站叠梁门分层取水运行情况分析.贵州水力发电,2011,25(4):18-21.
[32] 陈栋为,陈国柱,赵再兴,等.贵州光照水电站叠梁门分层取水效果监测.环境影响评价, 2016,38(3):45-48,52.
[33] 杜效鹄,喻卫奇,芮建良.水电生态实践:分层取水结构.水力发电,2008,34(12):28-32.
[34] 盛传明,练继建,刘昉,等.深水水库下泄低温水治理挡水幕布受力研究.水利学报, 2016,47(12):1548-1557.
[35] 王煜,戴会超.大型水库水温分层影响及防治措施.三峡大学学报(自然科学版),2009,31(6):11-14.
[36] BRADFORD S. Scoping Options for Mitigating Cold Water Discharges from Dams. Canberra: CSIRO Land and Water, 2000.
[37] U.S. Department of the Interior, Bureau of Reclamation. Lewiston Temperature Management Intermediate Technical Memorandum. Washington D C: U.S. Department of the Interior, Bureau of Reclamation, 2012.
[38] GAO X, LI G, HAN Y. Effect of Flow Rate of Side-type Orifice Intake on Withdrawn Water Temperature. The Scientific World Journal, 2014, doi: 10.1155/2014/979140.
[39] 高学平,张少雄,刘际军,等.浮式管型取水口下泄水温试验研究.水力发电学报, 2013,32(2):163-167.
[40] LIN J. Hydraulic Structures. Beijing: China Water Power Press, 2015.
[41] VERMEYEN T.Application of Flexible Curtains to Control Mixing and Enable Selective Withdrawal in Reservoirs//Proceedings of the 5th International Symposium on Stratified Flows, Vancouver, Canada, 2000, July 10-13: 1-6.
[42] ELOY C, LAGRANGE R, SOUILLIEZ C, et al. Aeroelastic Instability of Cantilevered Flexible Plates in Uniform Flow. Journal of Fluid Mechanics, 2008, 611: 97-106.
[43] WANG S. Numerical and Experimental Investigation on the Interaetion Between Moving Fluid and Flexible Bodies. Beijing: University of Scienee and Technology of China, 2010.
[44] BOHAC C. Underwater Dam and Embayment Aeration for Striped Bass Refuge. Journal of Environmental Engineering, 1989, 115(2):428-446.
[45] VERMEYEN T. Use of Temperature Control Curtains to Control Reservoir Release Water Temperatures. Denver: Bureau of Reclamation, 1997.
[46] 建设部河川局.分层取水设备设计要领(案)同解说.东京都:日本建设省(现国土交通省),1989.
[47] 水库水源地环境整治中心.曝气循环设备及分层取水设备的运用手册(案).东京都:日本国土交通省,2005.
[48] ASAEDA T, PHAM H S, NIMAL PRIYANTHA D G, et al. Control of Algal Blooms in Reservoirs with a Curtain: A Numerical Analysis. Ecological Engineering, 2001, 16(3): 395-404.
[49] ASAEDA T, PRIYANTHA D G N, SAITOH S, et al. A New Technique for Controlling Algal Blooms in the Withdrawal Zone of Reservoirs Using Vertical Curtains. Ecological Engineering, 1996, 7(2): 95-104.
[50] 丸岛水生系统股份有限公司.丸岛水生系统股份有限公司的水环境改善创新方案. http://www.marsima.co.jp/.
[51] SHAMMAA Y, ZHU D Z. Experimental Study on Selective Withdrawal in a Two-Layer Reservoir Using a Temperature-Control Curtain. Journal of Hydraulic Engineering, 2010, 136(4): 234-246.
[52] LEE H S, CHUNG S W, CHOI J K, et al. Feasibility of Curtain Weir Installation for Water Quality Management in Daecheong Reservoir. Desalination & Water Treatment, 2010, 19(1/2/3): 164-172.
[53] CHUNG S. Analysis the Effects of Physical Blocking Weirs on the Water Quality in Daechung Reservoir. Journal of Environmental Impact Assessment, 2012, 21(1): 25-39.
[54] 薛文豪,邓云,李嘉,等.大型水库帷幕水温分层取水效果研究.工程科学与技术,2017,49(增刊1):27-34.
[55] 高学平,宋清林,孙博闻.控制幕运行方式改善下泄水温及其成因研究.中国水利水电科学研究院学报,2018,16(1):45-52.
[56] HE W, LIAN J, LIU F, et al. Experimental and Numerical Study on the Thrust of a Water-Retaining Curtain. Journal of Hydroinformatics, 2018, 20(2): 316.
[57] HE W, LIAN J, MA C, et al. Analysis of the Thrust Force on the Temperature-Control Curtain in a Large Stratified Reservoir. Journal of Hydraulic Engineering, 2017, 143(12): 4017049.
[58] 杜慧超.三板溪水电站低温水治理隔水幕布方案研究.天津:天津大学, 2016.

基金

国家重点研发计划项目专题(2016YFC0401702);国家自然科学基金项目(51909070,51779016);江苏省自然科学基金项目(BK20190488);中央高校基本科研业务费专项(2019B11114);中央级科研院所基本科研业务费项目(CKSF2015050/SL);国家重点研发计划项目专题(2016YFC0401503);中国博士后科学基金资助项目(2019M651676)