不同因素对沿程汇流多孔流体分布管压力分布的影响
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摘要
为了研究不同因素(水深、开孔比、长径比等)对沿程汇流多孔流体分布管压力分布的影响,采用流体力学基本原理,从理论角度分析论证了不同因素对压力分布的影响,提出了压力分布综合表达式。通过室内模型试验结果分析并验证综合表达式,结果表明:压力随水深、开孔比的增加而增加。当开孔比相对较大时,压力分布的均匀性将会降低;压力随长径比的增加而增加,但增加值相对较小。多孔流体分布管在汇流过程中,管长前1/3段压力变化值较小,后段较为显著。在这些影响因素中,长径比对压力分布的影响最小,但是长管压力分布的均匀性比短管好。压力分布综合表达式经试验验证拟合效果较好,可以为多孔流体分布管的设计和应用提供参考。
In order to study the influences from various factors(water depth, opening ratio and length-diameter ratio, etc.) on the pressure distribution of the perforated pipe along the confluence, the influences from various factors on the pressure distribution are demonstrated herein with the basic principles of fluid mechanics, and then a synthetic expression of pressure distribution is proposed herein. The synthetic expression is analyzed and verified through the analysis of the relevant indoor model experiment, from which the result shows that the pressure is increased along with the increases of water depth and opening ratio. When the opening ratio is relatively large, the uniformity of pressure distribution is to be decreased, while the pressure is increased along with the length-diameter ratio, but the increment value is relatively small. During the confluence of the perforated pipe, the pressure variation value of the first 1/3 of the pipe length is small, but that of the later section is more significant. Within these influencing factors, the influence from the length-diameter ratio is the smallest, but the uniformity of pressure distribution of long pipe is better than that of the short one. Through the relevant experimental verification, the fitting effect of the synthetic expression of pressure distribution is better and then can provide reference for design and application of perforated pipe.
In order to study the influences from various factors(water depth, opening ratio and length-diameter ratio, etc.) on the pressure distribution of the perforated pipe along the confluence, the influences from various factors on the pressure distribution are demonstrated herein with the basic principles of fluid mechanics, and then a synthetic expression of pressure distribution is proposed herein. The synthetic expression is analyzed and verified through the analysis of the relevant indoor model experiment, from which the result shows that the pressure is increased along with the increases of water depth and opening ratio. When the opening ratio is relatively large, the uniformity of pressure distribution is to be decreased, while the pressure is increased along with the length-diameter ratio, but the increment value is relatively small. During the confluence of the perforated pipe, the pressure variation value of the first 1/3 of the pipe length is small, but that of the later section is more significant. Within these influencing factors, the influence from the length-diameter ratio is the smallest, but the uniformity of pressure distribution of long pipe is better than that of the short one. Through the relevant experimental verification, the fitting effect of the synthetic expression of pressure distribution is better and then can provide reference for design and application of perforated pipe.
引文
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[15] 杜涛,刘焕芳,金瑾,等.沿程出流多孔流体分布管压力分布特性[J].化学工程,2014,42(9):48- 52.
[16] 刘焕芳,吕宏兴.高等流体力学[M].北京:中国教育文化出版社,2005.
[17] 王凌,刘焕芳,杜涛.开孔率对多孔管压力水头分布规律的影响分析[J].人民黄河,2015,37(5):97- 98.
[2] STUYT L C P M,DIERICKX W,MARTINEZ B J M.Materials for subsurface land drainage systems[M].Rome:Food and Agriculture Organization of the United Nations,2005.
[3] 刘焕芳,程琨,吕宏兴.渗渠取水压力变化过程分析[J].西北农林科技大学学报(自然科学版),2007,35(8):211- 216.
[4] 郑晓瑜,刘焕芳,于旭永.河床砂厚度对渗管取水出水量及浊度的影响[J].排灌机械工程学报,2015,33(2):128- 132.
[5] 刘文,陈卫平,彭驰.城市雨洪管理低影响开发技术研究与利用进展[J].应用生态学报,2015,26(6):1901- 1912.
[6] AKAN A O.Preliminary design aid for bioretention filters[J].Journal of Hydrologic Engineering,2013,18(3):318- 323.
[7] SCHWARTZ S S.Effective curve number and hydrologic design of pervious concrete storm water systems[J].Journal of Hydrologic Engineering,2010,15(6):465- 474.
[8] LI X,TROY T J.Changes in rainfed and irrigated crop yield response to climate in the western US[J].Environmental Research Letters,2018,13(6):064031.
[9] 阿不力米提江·阿布力克木,陈春艳,玉素甫·阿不都拉,等.2001-2012年新疆融雪型洪水时空分布特征[J].冰川冻土,2015,37(1):226- 232.
[10] WANG J Y.Theory of flow distribution in manifolds[J].Chemical Engineering Journal,2011,168(3):1331- 1345.
[11] MURPHY P,KAYE N B,KHAN A.Hydraulic performance of aggregate beds with perforated pipe underdrains flowing full[J].Journal of Irrigation & Drainage Engineering,2014,140(8):04014023.
[12] AFRIN T,KAYE N B,KHAN A.Parametric study of perforated pipe underdrains surrounded by loose aggregate[J].Journal of Hydraulic Engineering,2016,142(12):04016066.
[13] 陈水俤.多孔管集水均匀性的理论分析[J].福州大学学报(自然科学版),1999,27(3):78- 81.
[14] 王峻晔,章明川,吴东棣.流体在多孔管分支系统中的流动机理研究[J].水动力学研究与进展(A辑),1999,14(1):34- 44.
[15] 杜涛,刘焕芳,金瑾,等.沿程出流多孔流体分布管压力分布特性[J].化学工程,2014,42(9):48- 52.
[16] 刘焕芳,吕宏兴.高等流体力学[M].北京:中国教育文化出版社,2005.
[17] 王凌,刘焕芳,杜涛.开孔率对多孔管压力水头分布规律的影响分析[J].人民黄河,2015,37(5):97- 98.
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