圆柱桩群阻力特性及其对底床冲淤影响的研究
|
摘要
圆柱桩群基础在码头、桥梁和海洋平台工程中被广泛应用,研究圆柱桩群阻力特性及其对水流和底床冲淤变化影响具有重要意义,也是正确模拟桩群的关键。
本文针对具有自由表面及有限水深均匀流中圆柱桩群阻力特性与桩群对底床冲淤影响研究成果的缺乏,特进行了圆柱阻力水槽试验,得到了圆柱阻力特性研究成果;并通过对各种排列方式、各种迎流角情况下桩群的阻力试验,得到了圆柱横向阻力影响特性和纵向阻力影响特性及迎流角对桩群阻力的影响特性的研究成果,研究得到圆柱阻力横向影响系数k_H与纵向遮流影响系数k_Z及迎流角对桩群阻力影响系数k_θ的计算经验公式,并提出了桩群阻力计算方法,且用桩群阻力试验资料验证了该方法的有效性和准确性,给工程实际中准确把握桩群阻力提供了理论依据。
桩群附近水域底床局部冲淤也是桩群模拟必须考虑的一个因素,为此,本文特进行了不同桩群在同一水流中对附近水域底床局部冲淤影响比较试验,和同桩群在不同水流中对附近水域底床局部冲淤影响比较试验,得到了桩群附近水域底床局部冲淤变化规律。发现桩群的排列方式对桩群附近水域底床局部冲淤具有很大的影响力度,同时发现不同水流中桩群附近水域底床局部冲淤特性有所差别。
通过研究发现,桩群桩柱排列方式对桩群阻力特性、桩群附近水域底床局部冲淤特性具有很大的影响程度,指出正确模拟桩群必须在做到阻力相似的同时尽量考虑桩群的桩柱排列方式相同。
Cylinder pile cluster foundation is extensively used in wharfs, bridges and oceanicplatform projects. Studies on drag force characteristics of cylinder pile cluster anderosion-disposition influence imposed on flow and bottom bed are of importance and alsothe key to successfully simulate pile cluster.
The dissertation aims at the shortage of data on drag force characteristics of cylinder pilecluster in uniform flow with free surface and limited water depth, and carries on flume testson cylinder pile cluster drag force and acquires drag force characteristics of cylinder pile;tests drag force of pile cluster with various arranging formats and up-flow angles, recognizeslaw of up-flow angles influencing drag force of pile cluster, finds empirical formula ofcalculating pile cluster drag force coefficient ko from horizontal influencing coefficient k_H,vertical flow-covering coefficient and up-flow angle, puts forward calculating method andformats about drag force of pile cluster, effectiveness and precision of which is verified bytest data, and supplies theoretical base for precisely computing drag force in projects.
Local erosion-deposition of bottom bed near pile cluster is also a factor that must beconsidered in simulating pile cluster. Therefore, the dissertation makes comparative tests oflocal erosion-deposition among different pile clusters in the same flow, and among the samepile cluster in different flows, and acquires local erosion-deposition laws of pile cluster nearbottom bed. It is found that arranging format of pile cluster has much influence on localerosion-deposition near bottom bed, and that some difference exits between localerosion-deposition characteristics at bottom bed near pile cluster in different flows.
Arranging format of pile cluster has much influence on characteristics of drag force andlocal erosion-deposition near bottom bed. It is necessary for successfully simulating pilecluster to consider as much as possible arranging of pile cluster while drag force similarity issatisfied.
本文针对具有自由表面及有限水深均匀流中圆柱桩群阻力特性与桩群对底床冲淤影响研究成果的缺乏,特进行了圆柱阻力水槽试验,得到了圆柱阻力特性研究成果;并通过对各种排列方式、各种迎流角情况下桩群的阻力试验,得到了圆柱横向阻力影响特性和纵向阻力影响特性及迎流角对桩群阻力的影响特性的研究成果,研究得到圆柱阻力横向影响系数k_H与纵向遮流影响系数k_Z及迎流角对桩群阻力影响系数k_θ的计算经验公式,并提出了桩群阻力计算方法,且用桩群阻力试验资料验证了该方法的有效性和准确性,给工程实际中准确把握桩群阻力提供了理论依据。
桩群附近水域底床局部冲淤也是桩群模拟必须考虑的一个因素,为此,本文特进行了不同桩群在同一水流中对附近水域底床局部冲淤影响比较试验,和同桩群在不同水流中对附近水域底床局部冲淤影响比较试验,得到了桩群附近水域底床局部冲淤变化规律。发现桩群的排列方式对桩群附近水域底床局部冲淤具有很大的影响力度,同时发现不同水流中桩群附近水域底床局部冲淤特性有所差别。
通过研究发现,桩群桩柱排列方式对桩群阻力特性、桩群附近水域底床局部冲淤特性具有很大的影响程度,指出正确模拟桩群必须在做到阻力相似的同时尽量考虑桩群的桩柱排列方式相同。
Cylinder pile cluster foundation is extensively used in wharfs, bridges and oceanicplatform projects. Studies on drag force characteristics of cylinder pile cluster anderosion-disposition influence imposed on flow and bottom bed are of importance and alsothe key to successfully simulate pile cluster.
The dissertation aims at the shortage of data on drag force characteristics of cylinder pilecluster in uniform flow with free surface and limited water depth, and carries on flume testson cylinder pile cluster drag force and acquires drag force characteristics of cylinder pile;tests drag force of pile cluster with various arranging formats and up-flow angles, recognizeslaw of up-flow angles influencing drag force of pile cluster, finds empirical formula ofcalculating pile cluster drag force coefficient ko from horizontal influencing coefficient k_H,vertical flow-covering coefficient and up-flow angle, puts forward calculating method andformats about drag force of pile cluster, effectiveness and precision of which is verified bytest data, and supplies theoretical base for precisely computing drag force in projects.
Local erosion-deposition of bottom bed near pile cluster is also a factor that must beconsidered in simulating pile cluster. Therefore, the dissertation makes comparative tests oflocal erosion-deposition among different pile clusters in the same flow, and among the samepile cluster in different flows, and acquires local erosion-deposition laws of pile cluster nearbottom bed. It is found that arranging format of pile cluster has much influence on localerosion-deposition near bottom bed, and that some difference exits between localerosion-deposition characteristics at bottom bed near pile cluster in different flows.
Arranging format of pile cluster has much influence on characteristics of drag force andlocal erosion-deposition near bottom bed. It is necessary for successfully simulating pilecluster to consider as much as possible arranging of pile cluster while drag force similarity issatisfied.
引文
[1] 朱仁庆,杨松林,杨大明.实验流体力学[M],北京,国防工业出版社,2005(8).
[2] 刘应中,缪国平.高等流体力学[M].,上海:上海交通大学出版社,2000,189-209.
[3] 张远君.流体力学大全[M],北京:北京航空航天大学出版社,1991,72-243.
[4] 巴切勒GK著.沈青贾复译.流体动力学引论[M],北京:科学出版社,1997,11:附录.
[5] JULIOS. An investigation of the near wake of a circular cylinder using a vidor based digital correlation particle image velocimetry technique [J], Experimental Thermal and Fluid Science, 1996,12:221-233.
[6] BRUCKER CH. Digital particle image velocimetry(DPIV) in a scanning light sheet: 3D starting flow around a short cylinder[J]. Expriments in Fluids. 1995,19: 255-263.
[7] ROCKWELL D. LINJC. CETINER O. Quantitative imaging of the wake of a cylinder in a steady current and free-surface waves[J] Journal of Fluids and Structurcs,2001, 15(3-4): 427-443.
[8] 张玮,王元,徐忠,金文.圆柱绕流涡系演变的DPIV测试[J],空气动力学学报,2002,20(4):172-181.
[9] H.Morand, R. Ohayon. Fluid Structure Interaction. John Wiley and Sons, 2002: 9~15.
[10] M.V.Morkovin.Flow around Circular Cylinder—Kaleidoscope of Challlenging Fluid Phenomena. Proc. ASME Symp. Fully Sep. Flows, 1964. Philadelphia:85~89.
[11] C.J.Garrison.论作用于圆形桩柱上的阻力和惯性力[J],OCT,1984(4):18-31.
[12] 邓庆增.圆柱绕流的非线性动力学[J],力学进展,1994,24(4):525~539.
[13] 叶春明,吴兴权.数值模拟圆柱绕流旋涡运动及尾流不稳定性分析[J],工程热物理学报.,1997,18(2):169~172.
[14] 陆夕云,庄礼宪.均匀来流中旋转圆柱粘性绕流的数值研究[J],力学学报.,1994,26(3):233~238.
[15] 邓见,黄钰期,任安禄.分块法研究圆柱绕流升阻力[J],力学与实践,2004(26):24-26.
[16] 王亚玲,刘应中,缪国平.圆柱绕流的三维数值模拟[J],上海交通大学学报,2004,35(10):1464~1469.
[17] 方建雯,凌国平.用速度—涡量方法解具有表面抽吸的圆柱绕流问题[J],苏州大学学报(自然科学版),2002,18(3):8-16.
[18] 黄钰期,邓见,任安禄.黏性非定常圆柱绕流的升阻力研究[J],浙江大学学报(工学版),2003,37(5):146-152.
[19] 甘孜.边界拟合坐标涡量—流函数绕物体流动计算[J],重庆建筑大学学报,2003,25(6):143-148.
[20] 陈和春,石岩.圆柱绕流的非交错多层笛卡尔网格混合有限分析法[J],三峡大学学报(自然科学版),2004,23(3):214-218.
[21] 袁竹林,蔡桂英.圆柱绕流现象的格子玻尔兹曼数值模拟[J],中国电机工程学报,2004(8):162-166.
[22] 吴剑,齐鄂荣,李炜等.应用PIV系统研究横流中近壁水平圆柱绕流旋涡特性[J],水科学进展,2005,16(5):268-274.
[23] 张军.用HLLC方法处理运行边界[J],力学与实践,2004(6):22-26.
[24] 薛雷平,刘桦,刘海江.床面上直立圆柱的三维湍流数值模拟[J],力学学报,2004,36(6):649-655.
[25] 李晓渝,索奇峰,强士中.钝体绕流的随机涡方法[J],西南交通大学学报,2002,37(1):40-44.
[26] Walther J H. Discrete vortex method for two-dimensional flow past bodies of arbitrary shape undergoing prescribed rotary and traaslation motion[D]. Doctoral Dissertation, Technical University of Denmark,DK-2800, Lyngby Denmark, 1994.
[27] 宋红军,王肇,尹协振.二维翼型非定常运动数值模拟[J],水动力学研究与进展,2004(12)896-903.
[28] 徐元利,徐元春,梁兴等.FLUENT软件在圆柱绕流模拟中的应用[J],水利电力机械,2005,27(1):39-42.
[29] 李寿英,顾明.斜直圆柱绕流的CFD模拟[J],空气动力学学报,2005,23(2):222-228.
[30] 施卫平,祖迎庆.用Lattice Bo ltzm ann方法计算流体对曲线边界的作用力[J],吉林大学学报(理学版),2005,43(2):132-137.
[31] 苏铭德,康钦军.亚临界雷诺数下圆柱绕流的大涡模拟[J],力学学报,1999,31(1):100-106.
[32] 万德成.用水深平均雷诺方程模拟有限长直立圆柱绕流[J],上海大学学报(自然科学版),1995(6):259-269.
[33] 仇轶,由长福,祁海鹰等.用无网格法求解不同Re下圆柱绕流问题[J],清华大学学报(自然科学版),2005,45(2):220-224.
[34] 王革,赖国璋,李玉成等.有限元—有限差分法对振荡流加任意方向均匀来流中圆柱绕流的数值模拟分析[J],水动力学研究与进展A辑,1994(4):224-234.
[35] 樊洪明,王小华,何钟怡.粘性流体圆柱绕流的有限元模拟[J],哈尔滨建筑大学学报,2001(2):62-67.
[36] 范明.高雷诺数圆柱绕流的二维大涡模拟[J],水动力学研究与进展,1992(A辑增刊):614-622.
[37] T.Sarpkaya. M. Isaacson. On Stationary and Traveling Vortex Breakdowns. Journal of Fluid Mechanics. 1971, 45: 545-568.
[38] R.W.Wardlaw. Approaches to the Suppression of Wind-induced Vibrations of Structures. E.Naudascher. D. Rockwell. In Practical Experiences with Flow-induced Vibrations, Berlin, 1980: 650-752.
[39] S. Ziada, A. Oengoren, Vortex Shedding in an In-line Tube Bundle with Large Spaces Journal of Fluid Structure. 1993,7:661—687.
[40] M. M. Zdravkovich. Review of Flow around Interference between Tow Circular Cylinders in Various Arrangements. Journal of Fluid Engineering. 1977,99: 618-633.
[4l] A. Slaoutiand, P. K. Stansby. Flow around Two Circular Cylinders by the Random Vortex Method. Journal of Fluid Structure. 1992,6:641-670.
[42] P. K. Stansby. A Numerical Study of Vortex Shedding from One and Two Circular Cylinders. Aeronautical Quarterly, 1981,32:48-71.
[43] C.H.Williamson. Evolution of a Single Wake behind a Pair of Bodies. Journal of Fluid Mechanics. 1985,159:1-18.
[44] M. D. Palmer, J.F.Keffer. An Experimental Investigation of an Asymmetrical Turbulent Wake. Journal of Fluid Mechanics. 1972.53:593-610.
[45] T.Farrant, M. Tan, W. G. Price. A Cell Boundary Element Method Applied to Laminar Vortex-Shedding from Arrays of Cylinder in Various Arrangements. Journal of Fluids and Structures. 2000,14(3): 375-402.
[46] K.Lam, X. Fang. The Effect of Interference of Four Equispaced Cylinders in Cross Flow on Pressure and Force Coefficients. Journal of Fluids and Structures. 1995,9(2): 195-214.
[47] 李椿萱,彭少波,吴子牛.附属小圆柱对主圆柱绕流问题影响的数值模拟[J],北京航空航天大学学报,2003(11):951-958.
[48] ZOU Jian-feng,REN An-lu,DENG Jian. A Forced System of Two Cylinders with Various Spacings[J]. China Ocean Engineering, 18(3): 391-402.
[49] 邓见,黄钰期,任安禄.分块法研究圆柱绕流升阻力[J],力学与实践,2004(26):143-146.
[50] 陈文曲,任安禄,邓见.下游圆柱涡致振动的升阻力特性及涡脱落模态分析[J],浙江大学学报(工学版),2005(8):1254-1259.
[51] 陈文曲,任安禄,李广望.串列双圆柱绕流下游圆柱两自由度涡致振动研究[J],力学学报,2004(11):732-739.
[52] 刘明侯,Y.Zhou,陈义良.圆柱绕流复杂尾迹的试验研究[J],中国科学技术大学学报,2000,30(3):318-324.
[53] 刘松,符松.串列双圆柱绕流问题的数值模拟[J],计算力学学报.2000,17(3):260-266.
[54] 廖俊,景思睿.高雷诺数下双圆柱的数值模拟[J],华中理工大学学报,1998,26(9):44-48.
[55] 顾志福,孙天风.三圆柱绕流的实验研究[J],空气动力学学报,2000(12):441-448.
[56] 李景银,K.Lam,K.ZChan,R.M.C.So.绕正方形排列的顺排的四个圆柱的流动研究[J],工程热物理学报,2004,25(1):59-62.
[57] 李会知,谢长天.高雷诺数下三圆柱的压力分布及气动力[J],流体力学实验与测量,1997,11 (2):43-47.
[58] 陈斌,郭烈锦,杨晓刚.圆柱绕流的离散涡数值模拟[J],自然科学进展,2002(9):143-149.
[59] 张爱社,张陵.等边布置三圆柱绕流的数值分析[J],应用力学学报,2003,20(1):142-150.
[60] 徐有恒,黄东群.侧柱对串列双柱脉动压力的干扰[J],力学学报,1997,29(1):30-38.
[61] 徐有恒,张德龙,马健.三圆柱绕流压力的脉动幅度及其与RMS值数值关系的实验研究[J],水动力学研究与进展,1997,A辑12(4):419-428.
[62] 楼小峰,曹丰产,林志兴.串列钝体绕流的数值计算[J],同济大学学报,2002,30(5):604-610.
[63] 吴文权.流体绕多个钝体不稳定分离流动数值仿真[J],华东工业大学学报,19(3):1-8.
[64] 陈炬桦,熊盛武.绕三圆柱流体的LB模拟[J],武汉大学学报(自然科学版),1998(2):37-41.
[65] Hoerner, S. F. Fluid Dymamic Drag[M], 1958.
[66] David J. Ball. Simulation of Piers in Hydraulic Models, Jourmal of the Waterways Harbors and Coastal Engineering Division, ASCE, Vol. 100, No WW1, February, 1974.
[67] Davil J. Ball and Clifford D. Hall, Drag of Yawed pile Groups at Low Roynolds Numbers, ASCE, Vol. 106, No.WW2, May, 1980.229-238.
[68] D. J. Ball, R. B. J. penoyre and B. A. O'connor, Numerical Modelling of the Hydrodynamics of Complex Civil Engineering Structures, International Conference on Hydralic Modelling of CivilEngineering Structures, England, September 22-24, 1982.
[69] C. DALON. Drag force of the group of Cylinder[J], Journal of Pressure Vessel Technology, 1977(2).
[70] 陈志昌.杨林口石油勘探码头模型试验报告[R],南京:南京水利科学研究院,1982.
[71] A.Bokaian.两个圆柱上的水动力[J],OTC,1985,50(7):13-25.
[72] J.C.Heideman.密集圆柱群上的水动力[J],OTC,1985,50(7):36-49.
[73] 徐立论,王爱群,赵林等.垂直圆柱群波浪作用力的研究[J],青岛海洋大学学报,1991,21(1):1-14.
[74] 杨正己,左其华,苏伟东.作用于群桩上的波浪力[J],南京水利科学研究院,水利水运科学研究,1992(9):231-243.
[75] 赵晓冬.桩群阻力研究及模型码头桩群计算[R],南京:南京水利科学研究院,1996.
[76] 唐士芳.二维潮流数值水槽的桩群数值模拟[J],中国港湾建设,2002(6):14-18.
[77] 唐士芳,李蓓.桩群阻力影响下的潮流数值模拟研究[J],中国港湾建设,2001(10):25-30
[78] 唐士芳.桩和桩群的水流阻力及其在潮流数值模拟中的应用[D],大连理工大学,2002.
[79] 周华兴,孙玉萍.墩柱受水流作用时阻力系数的试验研究[R],天津:交通部天津水运科学研究所,1985.
[80] 李光炽.高桩码头对河道流场影响的数值模拟[J],河海大学学报(自然科学版),2004,32(2): 216-220.
[81] 李文文,黄本胜等.高桩码头桩群水流特性的试验研究[J],新疆农业大学学报(自然科学版),2004,27(4):78-81.
[82] 王智辉,王震.桩群阻力数值模拟与物理模型比较研究[M].南京:江苏省海洋湖沼学会第一届青年学术研讨会文集.2004.
[83] 张金善,刘卫平,戴贤凯.外高桥顺岸桩基码头泥沙回淤及分析[J],水利水运工程学报,2004(3).53-58.
[84] Bayram, Atilla; Larson, Magnus. Analysis of scour around a group of vertical piles in the field[J]. Journal of Waterway, Port, Coastal and Ocean Engineering, 16 (4): 215-220.
[85] Coleman, Stephen E. Clearwater local scour at complex piers[J]. Journal of Hydraulic Engineering, 131 (4): 330-334.
[86] B.Mutlu.Sumer, Klavs Bunlgard. Global and Local Scour at Pile Groups[J]. International Journal of Offshore and PolarEngineering, 15(3): 204-209.
[87] 胡江,杨胜发,周华君等.群桩阻力损失与桩前冲刷研究[J].水动力学研究与进展(A),2006(11),776-781.
[88] 李昌华,孙梅秀.《河港工程总体设计规范》修订中的码头高程壅水试验研究[R],南京水利科学研究院报告,1993(5):1-10.
[89] 孙梅秀.南京港新生于码头桩群对港区水流的影响试验[R],南京水利科学研究院报告,1983(12):1-8.
[90] 孙梅秀,杨永荻,应强.南京港新生王于码头桩群对港区河段影响的动床模型试验研究[R],南京水利科学研究院,1985(6):2-10.
[91] 孔祥柏,吴济难,王亚林.哈尔滨港七道街码头壅水定床模型试验报告[R],南京水利科学研究院报告,1985(6):1-8.
[92] 孔祥柏,吴济难,王亚林.码头桩群壅水试验的相似条件[R],南京水利科学研究院报告,1985(11):1-10.
[93] 华绍曾.实用阻力手册[M],北京,国防工业出版社,1985.
[94] 夏震寰.现代水力学[M],北京,高等教育出版社,1990.
[95] Dey S. Local scour at piers, Part Ⅰ: A review of developments of research. Int J Sediment Rcs, 1997,12(2):23-46.
[96] Melville BW, Raudkivi AJ. Flow characteristics in local scour at bridge piers, J Hydr Res, 1977, 15(4):373-380.
[97] Dargahi B. The turbulent flow field around a circular cylinder. Exp Fluids, 1989,8:1-12.
[98] Dargahi B.Controlling mechanism of local scouring. ASCE J Hydr Engrg, 1990, 116(10): 1197~1214.
[99] Graf WH, Yulistiyanto B. Experiment on flow around a cylinder, the velocity and vorticity fields. J Hydr Res, 1998, 36(4): 637-653.
[100] Graf WH, Istiarto I, Flow pattern it., the scour hole around a cylinder. J Hydr Res, 2002, 40(1): 13-20.
[101] 高正荣,黄建维,卢中一.长江河口跨江大桥桥墩局部冲刷及防护研究[M].海洋出版社,北京,2005.
[102] 赵威,呼和敖德.圆柱绕流局部冲刷机制的试验研究[J]_力学学报,2006(9):577-586.
[103] 胡江,杨胜发,周华君等.群桩阻力损失与桩前冲刷研究[J].水动力学研究与进展,2006(11):776-781.
[104] Melville B.Wo,"Local scour at bridge abutments",Journal of Hydraulic Engineering, Vol, 118,No.4,(1992).
[105] Melville B.W.,and Raudkivi A.J.,"Effects of foundation geometry on bridge pier scour",Journal of Hydraulic Engineering, ASCE, Vol. 122,No.4,pp.203~209(1996).
[106] Melville B. W. and Chiew Yee-meng, "Time scale for local scour at bridge piers",Journal of Hydraulic Engineering, "Vol,125,No. 1.(1999).
[107] Raudkivi A.J.,"Clear-water scour at cylindrical piers",Journal of Hydraulic Engineering,ASCE, Vol. 109, No.3, pp.338~350(1983).
[108] Raudkivi A.J.,"Founctional trends of scour at bridge piers",Journal of Hydraulic Engineering, ASCE,Vol. 112,No.3,pp. 1~13(1986).
[109] Raudkivi A.J., Ettema R.,"Effect of sediment gradation on clear water scour",Joumal of Hydraulic Division,ASCE, Vol. 103,No.NY 10,pp. 1209~1213,(1977).
[110] Raudkivi A.Land Ettema R.,"Clear-water scour at cylindrical piers",Journal of Hydraulic Engineering,ASCE,Vol. 109,No.3,pp.5;38~349.(1983).
[111] 刘长龄,詹元豪,黄进坤.桥墩单桩与桩群之冲刷研究[J],第七届水利工程研讨会论文集(1994).
[112] McNeil J., Taylor C., and Lick W., "Measurements of erosion of undisturbed bottom sediments with depth", Journal of Hydraulic Division, ASCE, Vol, 122, No. 6, pp.316-324,(1996).
[113] 赖进松,胡瑞麟.泥沙起动条件相关研究之探讨[J],第十届水利工程研讨会论文集,逢甲大学,pp.D62-D67(1999).
[114] 张艺馨.不均匀圆形桥墩之局部冲刷研究[M],台湾国立中央大学硕士论文,2000.
[115] 刘佩伦.不均匀桥墩及群桩基础之局部冲刷研究[M],台湾国立中央大学硕士论文,2001.
[116] 沙玉清.泥沙运动学引论[M],北京,中国工业出版社,1965.
[117] 张瑞瑾,谢鉴衡,王明甫等.河流泥沙运动力学[M],北京,水利水电出版社,1989.
[118] 王兴奎,邵学军,李丹勋.河流动力学基础[M],北京,清华大学出版社,2002.
[119] 韩玉芳,罗晓峰,陈志昌等.大丰港一期工程模型试验研究[R],南京,南京水利科学研究院,2005.
[120] 韩玉芳,罗小峰.大丰港二期工程数学模型和物理模型试验研究[R],南京水利科学研究院研究报告,南京,2006(7).
[2] 刘应中,缪国平.高等流体力学[M].,上海:上海交通大学出版社,2000,189-209.
[3] 张远君.流体力学大全[M],北京:北京航空航天大学出版社,1991,72-243.
[4] 巴切勒GK著.沈青贾复译.流体动力学引论[M],北京:科学出版社,1997,11:附录.
[5] JULIOS. An investigation of the near wake of a circular cylinder using a vidor based digital correlation particle image velocimetry technique [J], Experimental Thermal and Fluid Science, 1996,12:221-233.
[6] BRUCKER CH. Digital particle image velocimetry(DPIV) in a scanning light sheet: 3D starting flow around a short cylinder[J]. Expriments in Fluids. 1995,19: 255-263.
[7] ROCKWELL D. LINJC. CETINER O. Quantitative imaging of the wake of a cylinder in a steady current and free-surface waves[J] Journal of Fluids and Structurcs,2001, 15(3-4): 427-443.
[8] 张玮,王元,徐忠,金文.圆柱绕流涡系演变的DPIV测试[J],空气动力学学报,2002,20(4):172-181.
[9] H.Morand, R. Ohayon. Fluid Structure Interaction. John Wiley and Sons, 2002: 9~15.
[10] M.V.Morkovin.Flow around Circular Cylinder—Kaleidoscope of Challlenging Fluid Phenomena. Proc. ASME Symp. Fully Sep. Flows, 1964. Philadelphia:85~89.
[11] C.J.Garrison.论作用于圆形桩柱上的阻力和惯性力[J],OCT,1984(4):18-31.
[12] 邓庆增.圆柱绕流的非线性动力学[J],力学进展,1994,24(4):525~539.
[13] 叶春明,吴兴权.数值模拟圆柱绕流旋涡运动及尾流不稳定性分析[J],工程热物理学报.,1997,18(2):169~172.
[14] 陆夕云,庄礼宪.均匀来流中旋转圆柱粘性绕流的数值研究[J],力学学报.,1994,26(3):233~238.
[15] 邓见,黄钰期,任安禄.分块法研究圆柱绕流升阻力[J],力学与实践,2004(26):24-26.
[16] 王亚玲,刘应中,缪国平.圆柱绕流的三维数值模拟[J],上海交通大学学报,2004,35(10):1464~1469.
[17] 方建雯,凌国平.用速度—涡量方法解具有表面抽吸的圆柱绕流问题[J],苏州大学学报(自然科学版),2002,18(3):8-16.
[18] 黄钰期,邓见,任安禄.黏性非定常圆柱绕流的升阻力研究[J],浙江大学学报(工学版),2003,37(5):146-152.
[19] 甘孜.边界拟合坐标涡量—流函数绕物体流动计算[J],重庆建筑大学学报,2003,25(6):143-148.
[20] 陈和春,石岩.圆柱绕流的非交错多层笛卡尔网格混合有限分析法[J],三峡大学学报(自然科学版),2004,23(3):214-218.
[21] 袁竹林,蔡桂英.圆柱绕流现象的格子玻尔兹曼数值模拟[J],中国电机工程学报,2004(8):162-166.
[22] 吴剑,齐鄂荣,李炜等.应用PIV系统研究横流中近壁水平圆柱绕流旋涡特性[J],水科学进展,2005,16(5):268-274.
[23] 张军.用HLLC方法处理运行边界[J],力学与实践,2004(6):22-26.
[24] 薛雷平,刘桦,刘海江.床面上直立圆柱的三维湍流数值模拟[J],力学学报,2004,36(6):649-655.
[25] 李晓渝,索奇峰,强士中.钝体绕流的随机涡方法[J],西南交通大学学报,2002,37(1):40-44.
[26] Walther J H. Discrete vortex method for two-dimensional flow past bodies of arbitrary shape undergoing prescribed rotary and traaslation motion[D]. Doctoral Dissertation, Technical University of Denmark,DK-2800, Lyngby Denmark, 1994.
[27] 宋红军,王肇,尹协振.二维翼型非定常运动数值模拟[J],水动力学研究与进展,2004(12)896-903.
[28] 徐元利,徐元春,梁兴等.FLUENT软件在圆柱绕流模拟中的应用[J],水利电力机械,2005,27(1):39-42.
[29] 李寿英,顾明.斜直圆柱绕流的CFD模拟[J],空气动力学学报,2005,23(2):222-228.
[30] 施卫平,祖迎庆.用Lattice Bo ltzm ann方法计算流体对曲线边界的作用力[J],吉林大学学报(理学版),2005,43(2):132-137.
[31] 苏铭德,康钦军.亚临界雷诺数下圆柱绕流的大涡模拟[J],力学学报,1999,31(1):100-106.
[32] 万德成.用水深平均雷诺方程模拟有限长直立圆柱绕流[J],上海大学学报(自然科学版),1995(6):259-269.
[33] 仇轶,由长福,祁海鹰等.用无网格法求解不同Re下圆柱绕流问题[J],清华大学学报(自然科学版),2005,45(2):220-224.
[34] 王革,赖国璋,李玉成等.有限元—有限差分法对振荡流加任意方向均匀来流中圆柱绕流的数值模拟分析[J],水动力学研究与进展A辑,1994(4):224-234.
[35] 樊洪明,王小华,何钟怡.粘性流体圆柱绕流的有限元模拟[J],哈尔滨建筑大学学报,2001(2):62-67.
[36] 范明.高雷诺数圆柱绕流的二维大涡模拟[J],水动力学研究与进展,1992(A辑增刊):614-622.
[37] T.Sarpkaya. M. Isaacson. On Stationary and Traveling Vortex Breakdowns. Journal of Fluid Mechanics. 1971, 45: 545-568.
[38] R.W.Wardlaw. Approaches to the Suppression of Wind-induced Vibrations of Structures. E.Naudascher. D. Rockwell. In Practical Experiences with Flow-induced Vibrations, Berlin, 1980: 650-752.
[39] S. Ziada, A. Oengoren, Vortex Shedding in an In-line Tube Bundle with Large Spaces Journal of Fluid Structure. 1993,7:661—687.
[40] M. M. Zdravkovich. Review of Flow around Interference between Tow Circular Cylinders in Various Arrangements. Journal of Fluid Engineering. 1977,99: 618-633.
[4l] A. Slaoutiand, P. K. Stansby. Flow around Two Circular Cylinders by the Random Vortex Method. Journal of Fluid Structure. 1992,6:641-670.
[42] P. K. Stansby. A Numerical Study of Vortex Shedding from One and Two Circular Cylinders. Aeronautical Quarterly, 1981,32:48-71.
[43] C.H.Williamson. Evolution of a Single Wake behind a Pair of Bodies. Journal of Fluid Mechanics. 1985,159:1-18.
[44] M. D. Palmer, J.F.Keffer. An Experimental Investigation of an Asymmetrical Turbulent Wake. Journal of Fluid Mechanics. 1972.53:593-610.
[45] T.Farrant, M. Tan, W. G. Price. A Cell Boundary Element Method Applied to Laminar Vortex-Shedding from Arrays of Cylinder in Various Arrangements. Journal of Fluids and Structures. 2000,14(3): 375-402.
[46] K.Lam, X. Fang. The Effect of Interference of Four Equispaced Cylinders in Cross Flow on Pressure and Force Coefficients. Journal of Fluids and Structures. 1995,9(2): 195-214.
[47] 李椿萱,彭少波,吴子牛.附属小圆柱对主圆柱绕流问题影响的数值模拟[J],北京航空航天大学学报,2003(11):951-958.
[48] ZOU Jian-feng,REN An-lu,DENG Jian. A Forced System of Two Cylinders with Various Spacings[J]. China Ocean Engineering, 18(3): 391-402.
[49] 邓见,黄钰期,任安禄.分块法研究圆柱绕流升阻力[J],力学与实践,2004(26):143-146.
[50] 陈文曲,任安禄,邓见.下游圆柱涡致振动的升阻力特性及涡脱落模态分析[J],浙江大学学报(工学版),2005(8):1254-1259.
[51] 陈文曲,任安禄,李广望.串列双圆柱绕流下游圆柱两自由度涡致振动研究[J],力学学报,2004(11):732-739.
[52] 刘明侯,Y.Zhou,陈义良.圆柱绕流复杂尾迹的试验研究[J],中国科学技术大学学报,2000,30(3):318-324.
[53] 刘松,符松.串列双圆柱绕流问题的数值模拟[J],计算力学学报.2000,17(3):260-266.
[54] 廖俊,景思睿.高雷诺数下双圆柱的数值模拟[J],华中理工大学学报,1998,26(9):44-48.
[55] 顾志福,孙天风.三圆柱绕流的实验研究[J],空气动力学学报,2000(12):441-448.
[56] 李景银,K.Lam,K.ZChan,R.M.C.So.绕正方形排列的顺排的四个圆柱的流动研究[J],工程热物理学报,2004,25(1):59-62.
[57] 李会知,谢长天.高雷诺数下三圆柱的压力分布及气动力[J],流体力学实验与测量,1997,11 (2):43-47.
[58] 陈斌,郭烈锦,杨晓刚.圆柱绕流的离散涡数值模拟[J],自然科学进展,2002(9):143-149.
[59] 张爱社,张陵.等边布置三圆柱绕流的数值分析[J],应用力学学报,2003,20(1):142-150.
[60] 徐有恒,黄东群.侧柱对串列双柱脉动压力的干扰[J],力学学报,1997,29(1):30-38.
[61] 徐有恒,张德龙,马健.三圆柱绕流压力的脉动幅度及其与RMS值数值关系的实验研究[J],水动力学研究与进展,1997,A辑12(4):419-428.
[62] 楼小峰,曹丰产,林志兴.串列钝体绕流的数值计算[J],同济大学学报,2002,30(5):604-610.
[63] 吴文权.流体绕多个钝体不稳定分离流动数值仿真[J],华东工业大学学报,19(3):1-8.
[64] 陈炬桦,熊盛武.绕三圆柱流体的LB模拟[J],武汉大学学报(自然科学版),1998(2):37-41.
[65] Hoerner, S. F. Fluid Dymamic Drag[M], 1958.
[66] David J. Ball. Simulation of Piers in Hydraulic Models, Jourmal of the Waterways Harbors and Coastal Engineering Division, ASCE, Vol. 100, No WW1, February, 1974.
[67] Davil J. Ball and Clifford D. Hall, Drag of Yawed pile Groups at Low Roynolds Numbers, ASCE, Vol. 106, No.WW2, May, 1980.229-238.
[68] D. J. Ball, R. B. J. penoyre and B. A. O'connor, Numerical Modelling of the Hydrodynamics of Complex Civil Engineering Structures, International Conference on Hydralic Modelling of CivilEngineering Structures, England, September 22-24, 1982.
[69] C. DALON. Drag force of the group of Cylinder[J], Journal of Pressure Vessel Technology, 1977(2).
[70] 陈志昌.杨林口石油勘探码头模型试验报告[R],南京:南京水利科学研究院,1982.
[71] A.Bokaian.两个圆柱上的水动力[J],OTC,1985,50(7):13-25.
[72] J.C.Heideman.密集圆柱群上的水动力[J],OTC,1985,50(7):36-49.
[73] 徐立论,王爱群,赵林等.垂直圆柱群波浪作用力的研究[J],青岛海洋大学学报,1991,21(1):1-14.
[74] 杨正己,左其华,苏伟东.作用于群桩上的波浪力[J],南京水利科学研究院,水利水运科学研究,1992(9):231-243.
[75] 赵晓冬.桩群阻力研究及模型码头桩群计算[R],南京:南京水利科学研究院,1996.
[76] 唐士芳.二维潮流数值水槽的桩群数值模拟[J],中国港湾建设,2002(6):14-18.
[77] 唐士芳,李蓓.桩群阻力影响下的潮流数值模拟研究[J],中国港湾建设,2001(10):25-30
[78] 唐士芳.桩和桩群的水流阻力及其在潮流数值模拟中的应用[D],大连理工大学,2002.
[79] 周华兴,孙玉萍.墩柱受水流作用时阻力系数的试验研究[R],天津:交通部天津水运科学研究所,1985.
[80] 李光炽.高桩码头对河道流场影响的数值模拟[J],河海大学学报(自然科学版),2004,32(2): 216-220.
[81] 李文文,黄本胜等.高桩码头桩群水流特性的试验研究[J],新疆农业大学学报(自然科学版),2004,27(4):78-81.
[82] 王智辉,王震.桩群阻力数值模拟与物理模型比较研究[M].南京:江苏省海洋湖沼学会第一届青年学术研讨会文集.2004.
[83] 张金善,刘卫平,戴贤凯.外高桥顺岸桩基码头泥沙回淤及分析[J],水利水运工程学报,2004(3).53-58.
[84] Bayram, Atilla; Larson, Magnus. Analysis of scour around a group of vertical piles in the field[J]. Journal of Waterway, Port, Coastal and Ocean Engineering, 16 (4): 215-220.
[85] Coleman, Stephen E. Clearwater local scour at complex piers[J]. Journal of Hydraulic Engineering, 131 (4): 330-334.
[86] B.Mutlu.Sumer, Klavs Bunlgard. Global and Local Scour at Pile Groups[J]. International Journal of Offshore and PolarEngineering, 15(3): 204-209.
[87] 胡江,杨胜发,周华君等.群桩阻力损失与桩前冲刷研究[J].水动力学研究与进展(A),2006(11),776-781.
[88] 李昌华,孙梅秀.《河港工程总体设计规范》修订中的码头高程壅水试验研究[R],南京水利科学研究院报告,1993(5):1-10.
[89] 孙梅秀.南京港新生于码头桩群对港区水流的影响试验[R],南京水利科学研究院报告,1983(12):1-8.
[90] 孙梅秀,杨永荻,应强.南京港新生王于码头桩群对港区河段影响的动床模型试验研究[R],南京水利科学研究院,1985(6):2-10.
[91] 孔祥柏,吴济难,王亚林.哈尔滨港七道街码头壅水定床模型试验报告[R],南京水利科学研究院报告,1985(6):1-8.
[92] 孔祥柏,吴济难,王亚林.码头桩群壅水试验的相似条件[R],南京水利科学研究院报告,1985(11):1-10.
[93] 华绍曾.实用阻力手册[M],北京,国防工业出版社,1985.
[94] 夏震寰.现代水力学[M],北京,高等教育出版社,1990.
[95] Dey S. Local scour at piers, Part Ⅰ: A review of developments of research. Int J Sediment Rcs, 1997,12(2):23-46.
[96] Melville BW, Raudkivi AJ. Flow characteristics in local scour at bridge piers, J Hydr Res, 1977, 15(4):373-380.
[97] Dargahi B. The turbulent flow field around a circular cylinder. Exp Fluids, 1989,8:1-12.
[98] Dargahi B.Controlling mechanism of local scouring. ASCE J Hydr Engrg, 1990, 116(10): 1197~1214.
[99] Graf WH, Yulistiyanto B. Experiment on flow around a cylinder, the velocity and vorticity fields. J Hydr Res, 1998, 36(4): 637-653.
[100] Graf WH, Istiarto I, Flow pattern it., the scour hole around a cylinder. J Hydr Res, 2002, 40(1): 13-20.
[101] 高正荣,黄建维,卢中一.长江河口跨江大桥桥墩局部冲刷及防护研究[M].海洋出版社,北京,2005.
[102] 赵威,呼和敖德.圆柱绕流局部冲刷机制的试验研究[J]_力学学报,2006(9):577-586.
[103] 胡江,杨胜发,周华君等.群桩阻力损失与桩前冲刷研究[J].水动力学研究与进展,2006(11):776-781.
[104] Melville B.Wo,"Local scour at bridge abutments",Journal of Hydraulic Engineering, Vol, 118,No.4,(1992).
[105] Melville B.W.,and Raudkivi A.J.,"Effects of foundation geometry on bridge pier scour",Journal of Hydraulic Engineering, ASCE, Vol. 122,No.4,pp.203~209(1996).
[106] Melville B. W. and Chiew Yee-meng, "Time scale for local scour at bridge piers",Journal of Hydraulic Engineering, "Vol,125,No. 1.(1999).
[107] Raudkivi A.J.,"Clear-water scour at cylindrical piers",Journal of Hydraulic Engineering,ASCE, Vol. 109, No.3, pp.338~350(1983).
[108] Raudkivi A.J.,"Founctional trends of scour at bridge piers",Journal of Hydraulic Engineering, ASCE,Vol. 112,No.3,pp. 1~13(1986).
[109] Raudkivi A.J., Ettema R.,"Effect of sediment gradation on clear water scour",Joumal of Hydraulic Division,ASCE, Vol. 103,No.NY 10,pp. 1209~1213,(1977).
[110] Raudkivi A.Land Ettema R.,"Clear-water scour at cylindrical piers",Journal of Hydraulic Engineering,ASCE,Vol. 109,No.3,pp.5;38~349.(1983).
[111] 刘长龄,詹元豪,黄进坤.桥墩单桩与桩群之冲刷研究[J],第七届水利工程研讨会论文集(1994).
[112] McNeil J., Taylor C., and Lick W., "Measurements of erosion of undisturbed bottom sediments with depth", Journal of Hydraulic Division, ASCE, Vol, 122, No. 6, pp.316-324,(1996).
[113] 赖进松,胡瑞麟.泥沙起动条件相关研究之探讨[J],第十届水利工程研讨会论文集,逢甲大学,pp.D62-D67(1999).
[114] 张艺馨.不均匀圆形桥墩之局部冲刷研究[M],台湾国立中央大学硕士论文,2000.
[115] 刘佩伦.不均匀桥墩及群桩基础之局部冲刷研究[M],台湾国立中央大学硕士论文,2001.
[116] 沙玉清.泥沙运动学引论[M],北京,中国工业出版社,1965.
[117] 张瑞瑾,谢鉴衡,王明甫等.河流泥沙运动力学[M],北京,水利水电出版社,1989.
[118] 王兴奎,邵学军,李丹勋.河流动力学基础[M],北京,清华大学出版社,2002.
[119] 韩玉芳,罗晓峰,陈志昌等.大丰港一期工程模型试验研究[R],南京,南京水利科学研究院,2005.
[120] 韩玉芳,罗小峰.大丰港二期工程数学模型和物理模型试验研究[R],南京水利科学研究院研究报告,南京,2006(7).