人工鱼礁流场效应的PIV试验研究
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摘要
采用PIV(粒子图像测速)二维测试技术和水槽模拟试验研究人工鱼礁流场效应,对单体开口比分别为0、0.04、0.16、0.25人工鱼礁模型在来流流速分别为180mm/s、112mm/s、67mm/s时产生的流场效应和纵向双体人工鱼礁随着礁体间距为50mm、100mm、150mm、200mm时产生的流场效应,以及多块人工鱼礁不同组合方式产生的流场效应进行分析研究。结果表明:单体人工鱼礁流场效应中,开口比是影响平均上升流流速和背涡流流域涡流面积的主要因素,来流流速影响程度次之;纵向双体人工鱼礁流场效应中,开口比也是影响平均上升流流速和背涡流流域涡流面积的主要因素,礁体间距影响程度次之;多块人工鱼礁组合方式流场效应中,迎流面为斜面和背流面为直立面时产生的流场效应最佳,即群礁组合为直角梯形时效果较好。
The flowing field of artificial reefs was studied by PIV (particle imagevelocimetry) two-dimensional flow field measurements and water channel physicalinvestigation. It was studied of the flow field of single cube artificial reefs which theopening ratio of the monomer were0,0.04,0.16,0.25at three different incomingvelocities of180mm/s,112mm/s,67mm/s, longitudinal catamaran artificial reefs atfour different reef spacing of50mm,100mm,150mm and200mm and combinedartificial reefs. The results showed that: in the flowing field of single cube artificialreefs, the opening ratio of the artificial reefs was the major factor influencingupwelling average velocity and area of reverse vortex, and the effect of the incomingflowing velocities was found to be less significant; in the flowing field of longitudinalcatamaran artificial reefs, the opening ratio of the artificial reefs also was the majorfactor influencing upwelling average velocity and area of reverse vortex, and theeffect of the reef spacing was found to be less significant; in the flowing field ofcombined artificial reefs, it was preferably influence of the flowing field that incidentflow surface was slop and reverse vortex surface was upright, in other words, theartificial reefs combination into rectangular trapezoidal was more better.
The flowing field of artificial reefs was studied by PIV (particle imagevelocimetry) two-dimensional flow field measurements and water channel physicalinvestigation. It was studied of the flow field of single cube artificial reefs which theopening ratio of the monomer were0,0.04,0.16,0.25at three different incomingvelocities of180mm/s,112mm/s,67mm/s, longitudinal catamaran artificial reefs atfour different reef spacing of50mm,100mm,150mm and200mm and combinedartificial reefs. The results showed that: in the flowing field of single cube artificialreefs, the opening ratio of the artificial reefs was the major factor influencingupwelling average velocity and area of reverse vortex, and the effect of the incomingflowing velocities was found to be less significant; in the flowing field of longitudinalcatamaran artificial reefs, the opening ratio of the artificial reefs also was the majorfactor influencing upwelling average velocity and area of reverse vortex, and theeffect of the reef spacing was found to be less significant; in the flowing field ofcombined artificial reefs, it was preferably influence of the flowing field that incidentflow surface was slop and reverse vortex surface was upright, in other words, theartificial reefs combination into rectangular trapezoidal was more better.
引文
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[32]张硕,孙满昌,陈勇.不同高度混凝土模型礁背涡流特性的定量研究[J].大连水产学院学报,2008,23(4):278~282.
[33]张硕,孙满昌,陈勇.不同高度混凝土模型礁上升流特性的定量研究[J].大连水产学院学报,2008,23(5):353~358.
[34]吴健,拾兵,杨立鹏等.多孔方形鱼礁对水动力环境影响的试验研究[J].海洋湖沼通报,2011,(2):147~152.
[35]刘健,徐柳雄,张硕,黄宏亮.人工鱼礁礁体模型阻力系数的试验研究[J].中国海洋大学学报,2011,41(10):35~39.
[36]潘灵芝,林军,章守宇.铅直二维定常流中人工鱼礁流场效应的数值试验[J].上海水产大学学报,2005,14(4):407~412.
[37]崔勇,关长涛,万荣,李娇,等.人工鱼礁流场效应的数值模拟与仿真研究.系统仿真学报,2009,21(23):7393~7396.
[38]关长涛,刘彦等.复合M型人工鱼礁粒子图像测速二维流场试验研究[J].渔业现代化,2010,37(1):15~19.
[39]李珺,林军,章守宇.方形人工鱼礁通透性及其对礁体周围流场影响的数值试验[J].上海海洋大学学报,2010,19(6):836~840.
[40]黄远东,姜剑伟,赵树夫.方形人工鱼礁周围水流运动的数值模拟研究[J].水资源与水工程学报,2012,23(3):1~3.
[41]郑延璇,关长涛,宋协法等.星体形人工鱼礁流场效应的数值模拟[J].农业工程学报,2012,28(19):185~193.
[42]唐洪武,唐立模,陈红,等.现代流动测试技术及应用[M].北京:科学出版社,2009:165~178.
[43]刘秀珍.超声多普勒技术的物理原理[J].襄樊职业技术学院学报,2006,5(4):9~10.
[44]鲁娟娟.流速测量对比研究[J].甘肃水利水电技术,2011,47(12):6~8.
[45]吴持恭.水力学(下册)[M].北京:高等教育出版社,2008:327~340.
[46]刘洪生,马翔,章守宇,等.人工鱼礁流场效应的模型试验[J].水产学报,2009,33(2):229~305.
[47]盛骤,谢式千,潘承毅.概率论与数理统计[M].北京:高等教育出版社,2001:282~294.
[2]邓景耀.海洋渔业资源研究的现状及其发展趋势[J].现代渔业信息,1989,4(4):5-7.
[3]徐恭昭.海洋农牧化的进展与问题[J].现代渔业信息,1998,13(1):3-10.
[4]徐绍斌.我国海洋水产资源增殖开发研究中若干问题的探讨[J].现代渔业信息,199,16(7):1-6.
[5]王波、武建平、高峻,等.关于青岛建设人工鱼礁改善近海生态和渔业环境的探讨[J].海岸工程,2004,23(4):66-73.
[6]吴健,拾兵,范菲菲等.单位多孔方形鱼礁保滩促淤的试验研究[J].水利水运工程学报,2011,9(3):42~47.
[7]张亮,黄泽强.广东省人工鱼礁建设成效、存在问题及向关建议[J].中国水产,2012,(3):31~32.
[8]张剑诚,于金海,王吉桥,等.人工渔礁建设研究现状.水产科学,2004,23(11):27~30.
[9]陈秀玲,高玉坡,刘绍成,远全义,等.浅海人工鱼礁建设势在必行.河北渔业,2008,(4):4~5.
[10]张剑诚,于金海,王吉桥,等.人工渔礁建设研究现状.水产科学,2004,23(11):27~30.
[11]影山方郎,大阪英雄,山田英巳,等.水槽實驗とょる多孔立方体魚礁こひね周りの可化[J].水產土木,1982,17(1):1~10.
[12]佐藤修.人工鱼礁に関する若干の问题点[J].水產增殖臨時,1968,7:43~65.
[13]黑木敏郎,佐藤修,尾崎晃.魚礁構造の物理学的研究Ⅰ[J].北海道水產部,1964,1~19.
[14]佐久田博司,佐久田昌昭,渡边浩一郎,等.人工沉設鱼礁模型に関する基础研究[J].水產土木,1981,18(1):7~19.
[15]佐藤修,影山方郎.人工魚礁[M].京:恒星社厚生阁,1984:17~26;38~42.
[16]影山芳郎,大阪英雄,山田英已,等.平面上に置かれた透过壁立方体周りの流れの可視化[J].水土木,1982,19(2):1~9.
[17]影山芳郎,大阪英雄,山田英已,等.人工礁モデル周りの流[J].水土木,1986,23(2):1~8.
[18]池田骏介,二瓶泰雄,秋山信义等.各種構造物にょゐ湧昇流の発生に関すゐ試驗的研究[J].海岸工程学论文集,1992,39(3):896~900.
[19]铃木连雄,本田阳一.3次元物体背後発生すゐ涌昇渦に関すゐ研究[J].海岸工程学论文集,1992,39(3):901~905.
[20]野添学,大桥行三,藤原正幸。铅直2次定常流场に设置さゎた働立型構造物にょゐ植物ァヲンクトンと营养盐の变化预测に关すゐ数值试验[J].Fisheries Engineering,2000,36(3):253~259.
[21]Fujihara.M,Kakeuchi.T.G,Ohashi.Physical-biological coupled modelingfor artificially generated upwelling [J].农业土木学会论文集.1997,189:69~79.
[22]Kim J Q,M Itzutani N,Iwata K.Experimental study on the local scour andembedment of fish reef by wave action in shallow water depth [C].Tokyo:Proceedings, International Conference on Ecological System EnhancementTechnology for Aquatic Environ2ments.Japan International Marine Science andTechnology Federa2tion,1995:168~173.
[23]William seaman.A rtificial reef evaluation with application to natural marinehabitats[M].Boca Raton:CRC press,2000.51-94.
[24]刘同渝.人工鱼礁的流态效应[J].水产科技,2003(6):43~44.
[25]虞聪达,俞存根,,严世强.人工船礁铺设模式优选方法研究[J].海洋与湖沼,2004,35(4):299~305.
[26]吴子岳,孙满昌,汤威.十字型人工鱼礁礁体的水动力计算[J].海洋水产研究,2003,24(4):32~35.
[27]钟术求,孙满昌,章守宇,等.钢制四方台型人工鱼礁礁体设计及稳定性研究[J].海洋渔业,2006,28(3):234~240.
[28]田文敏,安輝.永安港外海人工魚礁之下陷量與下沉制分析[G].台湾:中華民國第十九屆海洋工程研討論文集,1997:545~552.
[29]史红卫.正方体人工鱼礁模型试验与礁体设计[D].青岛:中国海洋大学,2006.
[30]赵海涛,张亦飞,郝春玲,等.人工鱼礁的投放区选址和礁体设计[J].海洋学研究,2006,24(4):72~74.
[31]刘洪生,马翔,章守宇,等.人工鱼礁流场风洞试验与数值模拟对比验证[J].中国水产科学,2009,16(3):365~371.
[32]张硕,孙满昌,陈勇.不同高度混凝土模型礁背涡流特性的定量研究[J].大连水产学院学报,2008,23(4):278~282.
[33]张硕,孙满昌,陈勇.不同高度混凝土模型礁上升流特性的定量研究[J].大连水产学院学报,2008,23(5):353~358.
[34]吴健,拾兵,杨立鹏等.多孔方形鱼礁对水动力环境影响的试验研究[J].海洋湖沼通报,2011,(2):147~152.
[35]刘健,徐柳雄,张硕,黄宏亮.人工鱼礁礁体模型阻力系数的试验研究[J].中国海洋大学学报,2011,41(10):35~39.
[36]潘灵芝,林军,章守宇.铅直二维定常流中人工鱼礁流场效应的数值试验[J].上海水产大学学报,2005,14(4):407~412.
[37]崔勇,关长涛,万荣,李娇,等.人工鱼礁流场效应的数值模拟与仿真研究.系统仿真学报,2009,21(23):7393~7396.
[38]关长涛,刘彦等.复合M型人工鱼礁粒子图像测速二维流场试验研究[J].渔业现代化,2010,37(1):15~19.
[39]李珺,林军,章守宇.方形人工鱼礁通透性及其对礁体周围流场影响的数值试验[J].上海海洋大学学报,2010,19(6):836~840.
[40]黄远东,姜剑伟,赵树夫.方形人工鱼礁周围水流运动的数值模拟研究[J].水资源与水工程学报,2012,23(3):1~3.
[41]郑延璇,关长涛,宋协法等.星体形人工鱼礁流场效应的数值模拟[J].农业工程学报,2012,28(19):185~193.
[42]唐洪武,唐立模,陈红,等.现代流动测试技术及应用[M].北京:科学出版社,2009:165~178.
[43]刘秀珍.超声多普勒技术的物理原理[J].襄樊职业技术学院学报,2006,5(4):9~10.
[44]鲁娟娟.流速测量对比研究[J].甘肃水利水电技术,2011,47(12):6~8.
[45]吴持恭.水力学(下册)[M].北京:高等教育出版社,2008:327~340.
[46]刘洪生,马翔,章守宇,等.人工鱼礁流场效应的模型试验[J].水产学报,2009,33(2):229~305.
[47]盛骤,谢式千,潘承毅.概率论与数理统计[M].北京:高等教育出版社,2001:282~294.