公伯峡水电站导流洞改建为旋流式内消能泄洪洞的体型优化与方案比较研究
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摘要
在高山峡谷的大江大河上修建水电站,往往需要大尺度导流洞。而导流洞在完成导流任务后,又往往因为工期紧,衬砌标准需提高,上下游水位衔接等困难而被废置不用。而常规的挑流消能方案,又常出现象雾化、空蚀破坏、岸坡冲刷等较难以克服的问题。为了解决上面两个方面的问题,近十几年以来,国内外对旋流式内消能工进行了较多的试验研究与设计方案论证。
本文采取理论分析与试验比较相结合的方法,首先对黄河公伯峡水电站右岸导流洞改建为永久式内消能泄洪洞的四个较大设计方案进行了水力特性的试验研究与体型优化,在此基础上,向建设单位分别提供了竖井旋流内消能的推荐方案与水平旋流内消能的推荐方案。其次根据水利水电规划设计总院的专家评审推荐意见和建设单位与设计部门对水平旋流方案进一步论证与优化意见,对水平旋流消能的淹没流方案与自由流方案进行了水力特性的试验研究与体型优化,提出了二种流态下的推荐方案。最后根据整个体型优化过程与结果,从技术与经济对比分析两个方面,对公伯峡右岸旋流泄洪洞进行了选型研究与方案比较,提出了公伯峡水电站右岸旋流内消能泄洪洞的最终推荐方案。
公伯峡水电站右岸旋流内消能泄洪洞是国内第一个泄量达1000m/s、水头超过100m,即将修建的旋流式内消能泄洪洞,其方案的论证与试验研究以及建成后投入使用,将在国内外旋流式内消能泄洪洞设计、研究与工程应用中具有重要的意义,将有力的推动这一新的消能形式在工程中的应
用,从而为解决高坝建设中泄水建筑物的高速水流问题与导流洞改建的技
术与经济问题提供工程实例,对推动与发展水工水力学的研究与发展均具
有重要的理论与实践意义。
Large scale diversion tunnel is often adopted when building a hydraulic power station between high mountains or in canyons on a great river. However the diversion tunnel is generally discarded after used, because the construction period of hydraulic power station is pressing , the lining standard of tunnel needs being improved and the up and down steam water level is difficult to be joined. But the general used ski-jump energy dissipation scheme often causes a series of insurmountable difficulties, such as fogging, cavitations demolition, and bank scouring . In order to solve above mentioned two kind problems ,in recent years , many test researches and designing schemes have been done aimed at internal dissipater with swirling flow .
Firstly in the paper the research of hydraulic characters and the optimize of structure have being carried out on the four bigger design schemes of permanent internal dissipation discharge tunnel reconstructed from the right bank's diversion tunnel of Gongboxia Power Station with a method of theoretical analysis combined with test comparisons. On this basis , two form swirling flow internal dissipation schemes, vertical and horizontal axis are recommended to the construction unit of the station as the schemes to be selected next. Secondly, according to the experts' opinions of General Institute of Hydraulic and Water Power Design and the ideas presented by the construction unit and the design branches , author of the paper accomplished the research of hydraulic characters and the optimize of structure on the submerged flow scheme and free flow scheme of horizontal swirling flow dissipation, and brought forward the recommend scheme of these two flow patterns respectively . Finally , author analyzed and compar
ed these two schemes on the aspects of technology and economy according to the wholly structure optimizing process and outcome, and recommended the final scheme of the right bank's diversion tunnel of Gongboxia Power Station reconstructed into a horizontal swirling flow internal dissipater tunnel.
The horizontal swirling flow internal dissipater tunnel being built in Gongboxia Power Station will be the first one reconstructed from a diversion tunnel whose discharge
reaches to 1000m Vs and water head is more than 100m in china . Its scheme's argumentation ,test research and future apply will have important meanings to the design .research and engineering application of internal dissipation discharge tunnel with swirling flow, will powerfully promote engineering application of this new kind of dissipation mode , which may solve some high velocity problems in high dam construction and provide a engineering example for technological and economical augmentation in a diversion tunnel reconstruction. It is of theoretical and practical importance to promote hydraulic structure researches and development.
本文采取理论分析与试验比较相结合的方法,首先对黄河公伯峡水电站右岸导流洞改建为永久式内消能泄洪洞的四个较大设计方案进行了水力特性的试验研究与体型优化,在此基础上,向建设单位分别提供了竖井旋流内消能的推荐方案与水平旋流内消能的推荐方案。其次根据水利水电规划设计总院的专家评审推荐意见和建设单位与设计部门对水平旋流方案进一步论证与优化意见,对水平旋流消能的淹没流方案与自由流方案进行了水力特性的试验研究与体型优化,提出了二种流态下的推荐方案。最后根据整个体型优化过程与结果,从技术与经济对比分析两个方面,对公伯峡右岸旋流泄洪洞进行了选型研究与方案比较,提出了公伯峡水电站右岸旋流内消能泄洪洞的最终推荐方案。
公伯峡水电站右岸旋流内消能泄洪洞是国内第一个泄量达1000m/s、水头超过100m,即将修建的旋流式内消能泄洪洞,其方案的论证与试验研究以及建成后投入使用,将在国内外旋流式内消能泄洪洞设计、研究与工程应用中具有重要的意义,将有力的推动这一新的消能形式在工程中的应
用,从而为解决高坝建设中泄水建筑物的高速水流问题与导流洞改建的技
术与经济问题提供工程实例,对推动与发展水工水力学的研究与发展均具
有重要的理论与实践意义。
Large scale diversion tunnel is often adopted when building a hydraulic power station between high mountains or in canyons on a great river. However the diversion tunnel is generally discarded after used, because the construction period of hydraulic power station is pressing , the lining standard of tunnel needs being improved and the up and down steam water level is difficult to be joined. But the general used ski-jump energy dissipation scheme often causes a series of insurmountable difficulties, such as fogging, cavitations demolition, and bank scouring . In order to solve above mentioned two kind problems ,in recent years , many test researches and designing schemes have been done aimed at internal dissipater with swirling flow .
Firstly in the paper the research of hydraulic characters and the optimize of structure have being carried out on the four bigger design schemes of permanent internal dissipation discharge tunnel reconstructed from the right bank's diversion tunnel of Gongboxia Power Station with a method of theoretical analysis combined with test comparisons. On this basis , two form swirling flow internal dissipation schemes, vertical and horizontal axis are recommended to the construction unit of the station as the schemes to be selected next. Secondly, according to the experts' opinions of General Institute of Hydraulic and Water Power Design and the ideas presented by the construction unit and the design branches , author of the paper accomplished the research of hydraulic characters and the optimize of structure on the submerged flow scheme and free flow scheme of horizontal swirling flow dissipation, and brought forward the recommend scheme of these two flow patterns respectively . Finally , author analyzed and compar
ed these two schemes on the aspects of technology and economy according to the wholly structure optimizing process and outcome, and recommended the final scheme of the right bank's diversion tunnel of Gongboxia Power Station reconstructed into a horizontal swirling flow internal dissipater tunnel.
The horizontal swirling flow internal dissipater tunnel being built in Gongboxia Power Station will be the first one reconstructed from a diversion tunnel whose discharge
reaches to 1000m Vs and water head is more than 100m in china . Its scheme's argumentation ,test research and future apply will have important meanings to the design .research and engineering application of internal dissipation discharge tunnel with swirling flow, will powerfully promote engineering application of this new kind of dissipation mode , which may solve some high velocity problems in high dam construction and provide a engineering example for technological and economical augmentation in a diversion tunnel reconstruction. It is of theoretical and practical importance to promote hydraulic structure researches and development.
引文
[1]阮莉.涡流式竖井溢洪道研究述评.云南工业大学学报,13(3),1997:24-29.
[2]牛晋蜀.涡流竖井消能初步研究.水电站设计,12(2),1996:67-72.
[3]Henry T.Falvey.陡槽及溢洪道的空化.长江科学院水工研究所,1991.
[4]王永生,李建中,牛争鸣.旋流式内消能工研究综述.陕西水力发电,11(4),1995:21-26.
[5]曹民雄,龙杰等.涡流式内消工及其在高水头泄水建筑物中的应用.水利水电科技进展,17(5),1997:29-34.
[6]夏维洪.苏联的旋转水流消能.河海科技进展,11(3),1991:29-40.
[7]Drioli C. Esperienze su installazioni con pozzo di scarico a Vortice [J].L' Eletterica, 1996,6.
[8]Jeanpierre D, Lachal A. Dissipation d energie dans un puits a vortex [X]. La Houille Blance, n. 7,1996.
[9]Jain S C. Tangntail vortex inlet[J].J of Hydraulic Engineering, 1984.110(12).
[10]Quik M C. Analysis of spiral vortex and vertical slot vortex drop shafts [J].J. of Hydraulic Engineering, 1990,116(3).
[11]Hager W H. Vortex drop inlet for supercritical approaching flow[J].J. of Hydraulic Engineering, 1990,116(8).
[12]Vischer D L. Hager W H. Vortex drops [M]. IAHR Hydraulic Structures Design Manual. 1995,9.
[13]倪汉根,郭琰.旋流式竖井溢洪道的流量系数.泄水工程与高速水流论文集.成都:成都科技大学出版社,1994(9):342-345.
[14]钱莺莺等.同轴反向涡旋内消能工的试验研究.泄水工程与高速水流论
文集.成都:成都科技大学出版社,1994(9):71-76.
[15]马萍章等.单向涡旋内消能工的试验研究.泄水工程与高速水流论文集,成都:成都科技大学出版社,1994:77-83.
[16]崔陇天,吕瑞平.涡流式消能工水力特性初探.全国水动力学研讨会文集.水动力学研究与进展编辑部,1993(9):538-547.
[17]A.Ⅱ.祖伊科夫和A.Γ.切帕伊金.旋涡式无压泄水道的水力计算.(苏)水工建设,1988(4):25-28.
[18]B.B.沃尔尚尼克等.旋流竖井溢洪道的水力计算的解析法.(苏)水工建设,1989(4):32-38.
[19]郭琰,倪汉根.旋流式竖井溢洪道竖井的水流特性研究.水动力学研究与进展, 10(2),1995:146-154
[20]郭琰,倪汉根.旋流式竖井溢洪道的过流能力及蜗室与锥形渐缩段的水力特性研究.水动力学研究与进展,10(1),1995:97-105
[21]C.M.斯里斯基.高水头水工建筑物的水力计算.水利电力出版社,1984
[22][美]H.T.法尔维.水工建筑物中的掺气水流.水利电力出版社,1984
[23]WilliH. Hager. Head-Discharge Relation for Vortex Shafts. Journal of Hydraulic Engineering, 1985,111(6).
[24]董兴林,高季章.利用导流洞改为竖井式永久泄洪洞研究综述.水力发电,1993(8):47-50.
[25]董兴林,高季章等.导流洞改为旋涡式竖井溢洪到综合研究.水力发电,1995(3):32-3.
[26]董兴林 郭军等.高水头大泄量旋涡竖井式泄洪洞的设计研究.水利学报,2000(11):27-33.
[27]牛争鸣,李建忠等.竖井进流水平旋转内消能泄水道的空化特征.水利学报,1998(1):44-49.
[28]牛争鸣,李建忠,崔陇天.竖井进流水平旋转内消能泄水道泄流特性.西
安理工大学学报,14(1),1998:28-66.
[29]牛争鸣等.竖井进流水平旋转内消能泄水道的泄流特性研究.水利学报,2002(1):61-69.
[30]牛争鸣等.竖井进流水平旋转内消能泄水道壁面压力分布规律.水力发电学报,2002(4).
[31]牛争鸣等.竖井进流水平旋转内消能泄水道流速分布与消能率的试验研究.水力发电学报,2003(1).
[32]牛争鸣等.竖井进流水平旋转内消能泄水道空腔直径的变化规律.水利学报,2003(1).
[33]夏维洪,王河生.旋转水流消能及空化特性.河海大学学报,26(23),1998:11-17.
[34]钱莺莺,姜树海等.涡旋内消能竖井泄洪洞的研究.泄水工程与高速水流,1998(9):54-60.
[35]孙双科,刘之平等.下游高水位条件下导流洞改建为旋流竖井式泄洪洞的水力学问题研究. 水利学报,2000(10):22-27.
[36]郑大琼,王念慎等.高坝施工导流洞改为永久竖井泄洪洞水力学研究.水力学报,1996(2):43-50.
[2]牛晋蜀.涡流竖井消能初步研究.水电站设计,12(2),1996:67-72.
[3]Henry T.Falvey.陡槽及溢洪道的空化.长江科学院水工研究所,1991.
[4]王永生,李建中,牛争鸣.旋流式内消能工研究综述.陕西水力发电,11(4),1995:21-26.
[5]曹民雄,龙杰等.涡流式内消工及其在高水头泄水建筑物中的应用.水利水电科技进展,17(5),1997:29-34.
[6]夏维洪.苏联的旋转水流消能.河海科技进展,11(3),1991:29-40.
[7]Drioli C. Esperienze su installazioni con pozzo di scarico a Vortice [J].L' Eletterica, 1996,6.
[8]Jeanpierre D, Lachal A. Dissipation d energie dans un puits a vortex [X]. La Houille Blance, n. 7,1996.
[9]Jain S C. Tangntail vortex inlet[J].J of Hydraulic Engineering, 1984.110(12).
[10]Quik M C. Analysis of spiral vortex and vertical slot vortex drop shafts [J].J. of Hydraulic Engineering, 1990,116(3).
[11]Hager W H. Vortex drop inlet for supercritical approaching flow[J].J. of Hydraulic Engineering, 1990,116(8).
[12]Vischer D L. Hager W H. Vortex drops [M]. IAHR Hydraulic Structures Design Manual. 1995,9.
[13]倪汉根,郭琰.旋流式竖井溢洪道的流量系数.泄水工程与高速水流论文集.成都:成都科技大学出版社,1994(9):342-345.
[14]钱莺莺等.同轴反向涡旋内消能工的试验研究.泄水工程与高速水流论
文集.成都:成都科技大学出版社,1994(9):71-76.
[15]马萍章等.单向涡旋内消能工的试验研究.泄水工程与高速水流论文集,成都:成都科技大学出版社,1994:77-83.
[16]崔陇天,吕瑞平.涡流式消能工水力特性初探.全国水动力学研讨会文集.水动力学研究与进展编辑部,1993(9):538-547.
[17]A.Ⅱ.祖伊科夫和A.Γ.切帕伊金.旋涡式无压泄水道的水力计算.(苏)水工建设,1988(4):25-28.
[18]B.B.沃尔尚尼克等.旋流竖井溢洪道的水力计算的解析法.(苏)水工建设,1989(4):32-38.
[19]郭琰,倪汉根.旋流式竖井溢洪道竖井的水流特性研究.水动力学研究与进展, 10(2),1995:146-154
[20]郭琰,倪汉根.旋流式竖井溢洪道的过流能力及蜗室与锥形渐缩段的水力特性研究.水动力学研究与进展,10(1),1995:97-105
[21]C.M.斯里斯基.高水头水工建筑物的水力计算.水利电力出版社,1984
[22][美]H.T.法尔维.水工建筑物中的掺气水流.水利电力出版社,1984
[23]WilliH. Hager. Head-Discharge Relation for Vortex Shafts. Journal of Hydraulic Engineering, 1985,111(6).
[24]董兴林,高季章.利用导流洞改为竖井式永久泄洪洞研究综述.水力发电,1993(8):47-50.
[25]董兴林,高季章等.导流洞改为旋涡式竖井溢洪到综合研究.水力发电,1995(3):32-3.
[26]董兴林 郭军等.高水头大泄量旋涡竖井式泄洪洞的设计研究.水利学报,2000(11):27-33.
[27]牛争鸣,李建忠等.竖井进流水平旋转内消能泄水道的空化特征.水利学报,1998(1):44-49.
[28]牛争鸣,李建忠,崔陇天.竖井进流水平旋转内消能泄水道泄流特性.西
安理工大学学报,14(1),1998:28-66.
[29]牛争鸣等.竖井进流水平旋转内消能泄水道的泄流特性研究.水利学报,2002(1):61-69.
[30]牛争鸣等.竖井进流水平旋转内消能泄水道壁面压力分布规律.水力发电学报,2002(4).
[31]牛争鸣等.竖井进流水平旋转内消能泄水道流速分布与消能率的试验研究.水力发电学报,2003(1).
[32]牛争鸣等.竖井进流水平旋转内消能泄水道空腔直径的变化规律.水利学报,2003(1).
[33]夏维洪,王河生.旋转水流消能及空化特性.河海大学学报,26(23),1998:11-17.
[34]钱莺莺,姜树海等.涡旋内消能竖井泄洪洞的研究.泄水工程与高速水流,1998(9):54-60.
[35]孙双科,刘之平等.下游高水位条件下导流洞改建为旋流竖井式泄洪洞的水力学问题研究. 水利学报,2000(10):22-27.
[36]郑大琼,王念慎等.高坝施工导流洞改为永久竖井泄洪洞水力学研究.水力学报,1996(2):43-50.