气动冲沙法辅助小浪底水库调沙的设想
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摘要
针对黄河含沙量大、干流水库不同程度淤积的状况,提出了一种水动力与强人工干预有机结合的泥沙负载提高方法,即通过气动系统使水体中产生气泡,增强水流的紊动强度及垂向流速,提高水流的挟沙、输沙能力。通过水槽试验,对黄河原型沙在气动装置辅助下的起动与输运进行了研究。结果表明:在一次排气过程中,覆盖于排气孔上方的泥沙中有28%的泥沙得以起动并被水流输送,且其中仅有8%落淤到下游水槽中,20%的泥沙被带出水槽,取得了明显的清淤效果。同时,针对小浪底水库的淤积特点,对将气动冲沙法应用到小浪底水库的可行性进行了分析并提出了初步方案。
The sediment concentration in the Yellow River is large and the reservoirs in the mainstream suffer from siltation of different degrees. A new concept and method that combining hydraulic power with strong artificial measure was proposed by this article. This method used pressure air to uplift flow in order to enhance turbulence and improve sediment transport. A flume test was introduced by this paper to study the transport of the prototype sand in the Yellow River. The results show that 28% sediment over the air vent is setting up and carried by flow during a period of deaeration, while only 8% settle down in the down reach of flume, which means 20% is carrying to the outside of flume. Taking Xiaolangdi Reservoir of the Yellow River for an example, the feasibility of applying pneumatic system was analyzed and a preliminary scheme was proposed.
The sediment concentration in the Yellow River is large and the reservoirs in the mainstream suffer from siltation of different degrees. A new concept and method that combining hydraulic power with strong artificial measure was proposed by this article. This method used pressure air to uplift flow in order to enhance turbulence and improve sediment transport. A flume test was introduced by this paper to study the transport of the prototype sand in the Yellow River. The results show that 28% sediment over the air vent is setting up and carried by flow during a period of deaeration, while only 8% settle down in the down reach of flume, which means 20% is carrying to the outside of flume. Taking Xiaolangdi Reservoir of the Yellow River for an example, the feasibility of applying pneumatic system was analyzed and a preliminary scheme was proposed.
引文
[1] 胡春宏.从三门峡到三峡我国工程泥沙学科的发展与思考[J].泥沙研究,2019,44(2):1-10.
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[3] 魏军,张丙夺,蔡彬,等.2018年黄河干流水库群联合调度实践与启示[J].中国防汛抗旱,2019,29 (4):10-14,35.
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[5] 窦国仁,董风舞,DOU Xibing.潮流和波浪的挟沙能力[J].科学通报,1995(5):443-446.
[6] 罗勇,窦希萍,罗肇森.气动冲沙法治理黄河泥沙的一点思考[J].水利学报,2007,38(增刊1):276-282.
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[8] KOBUS H E.Analysis of the Flow by Air-Bubbles Systems[C]//Proceeding of 11th Conference of Coast Engineering.London:Coast Engineering,1968:1016-1031.
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[10] 王婷,马怀宝,王远见,等.小浪底水库运用以来进出库泥沙分析[J].人民黄河,2019,41(1):6-9,13.
[11] 王婷,王远见,曲少军,等.小浪底水库运用以来库区泥沙淤积分析[J].人民黄河,2018,40(12):1-3,20.
[12] 孙东坡,吴默溪.黄河小浪底水库运用以来的泥沙淤积特征分析[J].华北水利水电大学学报(自然科学版),2018,39(2):74-79.
[13] 李立刚,陈洪伟,李占省,等.小浪底水库泥沙淤积特性及减淤运用方式探讨[J].人民黄河,2016,38(10):40-42.
[2] 江恩慧,王远见,张原锋,等.黄河泥沙研究新进展[J].人民黄河,2016,38(10):24-31.
[3] 魏军,张丙夺,蔡彬,等.2018年黄河干流水库群联合调度实践与启示[J].中国防汛抗旱,2019,29 (4):10-14,35.
[4] 张士辰,盛金保,李子阳,等.关于推进水库清淤工作的研究与建议[J].中国水利,2017(16):45-48.
[5] 窦国仁,董风舞,DOU Xibing.潮流和波浪的挟沙能力[J].科学通报,1995(5):443-446.
[6] 罗勇,窦希萍,罗肇森.气动冲沙法治理黄河泥沙的一点思考[J].水利学报,2007,38(增刊1):276-282.
[7] 罗肇森,罗勇.一种治沙输沙的新理念和方法[J].泥沙研究,2009(4):31-38.
[8] KOBUS H E.Analysis of the Flow by Air-Bubbles Systems[C]//Proceeding of 11th Conference of Coast Engineering.London:Coast Engineering,1968:1016-1031.
[9] HABERMAN W L,MORTON R K.An Experiment Study of Bubbles Moving in Liquids[J].Proc.ASCE.,1954,80:379-427.
[10] 王婷,马怀宝,王远见,等.小浪底水库运用以来进出库泥沙分析[J].人民黄河,2019,41(1):6-9,13.
[11] 王婷,王远见,曲少军,等.小浪底水库运用以来库区泥沙淤积分析[J].人民黄河,2018,40(12):1-3,20.
[12] 孙东坡,吴默溪.黄河小浪底水库运用以来的泥沙淤积特征分析[J].华北水利水电大学学报(自然科学版),2018,39(2):74-79.
[13] 李立刚,陈洪伟,李占省,等.小浪底水库泥沙淤积特性及减淤运用方式探讨[J].人民黄河,2016,38(10):40-42.
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