枢纽扩建船闸工程上游设计最低通航水位的确定
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摘要
上游设计最低通航水位是船闸工程建设的关键技术参数之一,直接影响船闸使用性能、投资和工期。针对已建枢纽扩建船闸工程上游设计最低通航水位取值的问题,根据株洲枢纽实测水位,进行枢纽实际最低运行水位和保证率水位的分析,对不同特征水位时二线船闸工程投资情况、一线船闸运行情况及渠化梯级间水位衔接情况进行论述,采用模型试验验证和测算投资比较的方法,得出株洲二线船闸上游设计最低通航水位宜采用38. 3 m的结论。该研究方法对山区、丘陵区枢纽扩建船闸工程具有借鉴意义。
The lowest navigable water level in the upstream design is one of the key technical parameters for ship lock construction,which directly affects the performance,investment and duration of the lock. In the light of the value of the lowest navigable water level in the upper reaches of the built ship expansion project,we analyze the actual minimum operating water level and the guaranteed level water level according to the measured water level of the Zhuzhou junction,and discuss the investment situation of the second-line lock project,the operation situation of the first-line lock and the connection of the water level between the channelized cascades under different characteristic water levels. The conclusion is drawn that the lowest navigable water level of the upper design of Zhuzhou second-line lock should be 38. 3 m by means of model test verification and investment comparison. The research method can be used as reference for the lock expansion project in the mountainous and hilly areas.
The lowest navigable water level in the upstream design is one of the key technical parameters for ship lock construction,which directly affects the performance,investment and duration of the lock. In the light of the value of the lowest navigable water level in the upper reaches of the built ship expansion project,we analyze the actual minimum operating water level and the guaranteed level water level according to the measured water level of the Zhuzhou junction,and discuss the investment situation of the second-line lock project,the operation situation of the first-line lock and the connection of the water level between the channelized cascades under different characteristic water levels. The conclusion is drawn that the lowest navigable water level of the upper design of Zhuzhou second-line lock should be 38. 3 m by means of model test verification and investment comparison. The research method can be used as reference for the lock expansion project in the mountainous and hilly areas.
引文
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[2]四川省交通运输厅交通勘察设计研究院,南京水利科学研究院.内河航运工程水文规范:JTS 145-1—2011[S].北京:人民交通出版社,2011.
[3]长江航道局.内河通航标准:GB 50139—2014[S].北京:中国计划出版社,2014.
[4]彭厚德.湘江航电枢纽船闸通航水位的确定[J].湖南交通科技,2012,38(4):148-149+152.
[5]湖南省交通规划勘察设计院.湘江航运开发株洲枢纽航电枢纽工程施工图[R].长沙:湖南省交通规划勘察设计院,2002.
[6]周丁,姜兴良.株洲二线船闸轴线布置方案[J].水运工程,2015(9):138-142.
[7]吴澎,潘海涛,张珊,等.湘江二级航道二期工程株洲航电枢纽二线船闸工程初步设计[R].北京:中交水运规划设计院有限公司,2015.
[8]丁平,刘圣保.天然河流设计最低通航水位两种计算方法的对照分析及选用[J].中国水运(下半月),2010,10(1):157-159.
[9]汪映红,彭厚德,张珊,等.湘江二级航道二期工程船闸最低通航水位专题论证报告[R].长沙:湖南省水运建设投资集团有限公司,2015.
[10]宣国祥,刘本芹,李中华,等.株洲航电枢纽二线船闸工程引航道水流条件研究报告[R].南京:南京水利科学研究院,2015.
[11]彭映凡.株洲航电枢纽工程设计理念综述[J].中国农村水利水电,2009(8):109-111.
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