| 6,749 | 221 | 174 |
| 下载次数 | 被引频次 | 阅读次数 |
泥沙研究主要是认识水流中的泥沙运动规律、河床演变规律,进而解决水利工程中的泥沙问题。泥沙学科体系始建于20世纪,侧重河流泥沙研究。河流泥沙运动力学基本理论包括:泥沙的沉降特性、泥沙的起动特性、悬移质运动规律、推移质运动规律、水流挟沙力、非平衡输沙、泥沙运动统计理论、异重流运动理论、波流作用下的泥沙运动理论等。在长期的治河实践中,我国的泥沙科学发展迅速,主要进展包括:泥沙运动力学基本理论,高含沙水流的运动机理与理论,河流模拟的理论与技术,水库泥沙的对策与管理,河道演变规律的认识及治河工程技术等。本文对河流泥沙研究的主要进展进行简要综述。
Abstract:To resolve the sediment problems in the hydraulic engineering,sediment research concerns on realizing the rule of sediment movement and fluvial processes.Sediment discipline system was built up in 20 century.In the long history of river regulation practice,sediment science has been developed rapidly in China.The primary accomplishments include: the fundamental theory of sediment movement mechanics,the movement mechanism and theory of hyperconcentrated flow,the theory and technique of river simulating,the countermeasure and management of reservoir sediment problem,the law of river channel evolution,the river regulation techniques and so on.
[1]Ackers P.,White W.R.Sediment transport:new approach and analysis.Journal of Hydraulic Division,ASCE,1973,99(11):2041-2060.
[2]Bagnold R.A.Bedload transport by natural rivers.Water Resources Research,1977,13(2):303-312.
[3]Bagnold R.A.The nature of saltation and of bedload transport in water.Proc.,Royal Soc.London:Ser.A,1973.332:473-504.
[4]Bagnold R.A.An approach to the sediment transport problem from general physics.U.S.Geol.Survey,Prof.Paper,1966,(422):Ⅰ.
[5]Bagnold R.A.Auto-suspension of transported sediment:Turbidity Currents.Proc.of the Royal Society(Series A),1962,265:1332.
[6]Bagnold R.A.The flow of cohesionless grains in fluids.Phil.Trans.,Royal Soc.London:Set.A.,1956,249(964):235-297.
[7]Bagnold R.A.Some flume experiment on large grains but little denser than transporting fluids and their implications.Proc.Inst.Civil Engrs,1955,174-205.
[8]Bagnold R.A.Experiments in a gravity-free dispersion of water flow.Proc.,Royal Soc.London:Ser.A,1954,225.
[9]Brownlie W.R.Prediction of flow depth and sediment discharge in open-channels.Report KK-R-43A,W.M.Kech Lab.Hydraulics and Water Resources,California Inst.of Technology,Pasadena,CA,1981.
[10]Cao Z,Pender G,Wallis S,Carling P.Computational dam-break hydraulics over erodible sediment bed.Journal of HydraulicEngineering,ASCE,2004,130(7):689-703.
[11]Cao Z,Egashira S,Carling P.Role of suspended-sediment particle size in modifying velocity profiles in open channel flows.WaterResources Research,AGU,2003,39(2):1029.
[12]Cao Z,Day R,Egashira S.Coupled and decoupled numerical modelling of flow and morphological evolution in alluvial rivers.Journal of Hydraulic Engineering,ASCE,2002,128(3):306-321.
[13]Cao Z.Equilibrium near-bed concentration of suspended sediment.Journal of Hydraulic Engineering,ASCE,1999,125(12):1270-1278.
[14]Cao Z.Turbulent bursting-based sediment entrainment function.Journal of Hydraulic Engineering,ASCE.1997,123(3):233-236.
[15]Carling P.A.,Cao Z.,Holland M.J.,Ervie D.A.and Babayan Koopaei K.Turbulent flow across a natural compoundchannel.Water Resources Research,AGU.2002,38,6-1-6-11.
[16]Cassells JBC,Lambert MF,Myers RWC.Discharge prediction in straight mobile bed compound channels.PROCEEDINGS OFTHE INSTITUTION OF CIVIL ENGINEERS-WATER AND MARITIME ENGINEERING.2001,148(3):177-188.
[17]Chang HH.Minimum stream power and river channel patterns.Journal of Hydrology.1979,41:303-327.
[18]Chen Li,Liu Qingquan,Zhang Shuofu.Inherent Distribution Law of Turbulent Intensity of Sediment——laden Flow.J.SedimentResearch.1997,12(3).
[19]Davies TRH,Sutherland AJ.Extremal hypotheses for river behavior.Water Resources Research.1983,19(1):141-148.
[20]Du Boys MP.Le rhone et les rivieres a Lit affouillable.Annales de Ponts et Cgausses.1879,18(5):41-195.
[21]Einstein H.A.Formula for the transportation of bed load.Trans.ASCE.1942,07:61-597.
[22]Einstein H.A.,A.E1-Samni.Hydrodynamic forces on a rough wall.Rev.Modern Physics,1949,(3):520-524.
[23]Einstein H.A.,Ning Chien.Effects of sediment concentration near the bed on the velocity and sediment distribution.M.R.D.Sediment Series,No.8,Missouri River Div.,Corps of Engrs.1955,76-76.
[24]Einstein H.A.and Ning Chien.Can the Rate of Wash Load Be Predicted from Bed-Load Function?.Trans.Amer.GeophysicalUnion.1953,34(6):876-882.
[25]Einstein H.A.,Ning Chien.Transport of sediment mixtures with large ranges of grains sizes,Missouri River Div.Sediment Series(2),Missouri River Div.U.S.Corps Engrs.1953,49-49.
[26]Einstein,H.A.,N.Barbarossa.River channel roughness.Transactions,ASCE.1952,117:1121-1146.
[27]Einstein H.A.The bed load function for sediment transportation in open channel flows.U.S.Dept.Agri.,Tech.Bull.1950,1026:71,钱宁译:明渠水流的挟沙力[M].北京:水利出版社,1956.
[28]Engelund F.,J.Fredsoe.Sediment Ripples and Dunes.Annual Review of Fluid Mechanics.1982,14:13-37.
[29]Engelund F.,J.Fredsoe.A sediment transport model for straight alluvial channels.Nordic Hydrology.1976,7:293-306.
[30]Engelund F.,J.Fredsoe.Transition from dunes to plane bed in alluvial channels.Ser.Paper 4,Inst.Hydrodynamics and Hyd.Engin.,Tech.Univ.Denmark.1974,46-46.
[31]Engelund F.,E.Hansen.A monograph on sediment transport in alluvial streams.Teknisk Verlag,Copenhagen.Denmark,1972.
[32]Engelund F.Instability of erodible bed.J.Fluid Mech.1970,42(2):225-244.
[33]Engelund F.Closure to“Hydraulic Resistance of Alluvial Streams”.J.Hyd.Div.,ASCE.1967,93(4):287-296.
[34]Engelund F.Hydraulic resistance of alluvial streams.J.Hydraulics Div.,ASCE.1966,92(2):315-327.
[35]Engelund F.and E.Hansen.Investigation of flow in alluvial streams.Acta Polytechnics Scandinavica,Ci.1966,35.
[36]Fang H.W.and Wang G.Q.3D mathematical model of suspended-sediment transport.ASCE,Journal of HydraulicEngineering.2000,126(8):578-592.
[37]Feldman A D.Hec Models for Water Resources System Simulation:Theory and Experience.The Hydraulic Engineering Center.Davis,California.1981.
[38]Garcia M.and Parker G.Entrainment of bed sediment into suspension.J.Hydr.Engrg.,ASCE.1991,117(4):414-435.
[39]Gilbert G.K.The Transportation of Debris by Running Water.U.S.Geol.Sur.Prof.Paper.1914,86(1)-263.
[40]Guo JK.Logarithmic matching and its applications in computational hydraulics and sediment transport.JOURNAL OFHYDRAULIC RESEARCH,IAHR.2002,40(5):555-565.
[41]Hjelmfelt A.T.,Lenau C.W.Non-equilibrium transport of suspended sediment,Journal of Hydraulics Division,ASCE.1970,96(HY7):1567-1586.
[42]Huang HQ,Nanson GC.Hydraulic geometry and maximum flow efficiency as products of the principle of least action.EarthSurface Processes and Landforms.2000,25(1)-16.
[43]Hunt J.N.The turbulent transport of suspended sediment in open channels.Proc.Roy.Soc.,London:Ser.A.1954,224(1158):322-335.
[44]Kirkby MJ.Maximum sediment efficiency as a criterion for alluvial channels.River Channel Changes.Gregory KJ(ed.).JohnWiley:Chichester.1977,429-442.
[45]Knight D.W.,K.Shiono.Turbulence measurement in a shear layer region of compound channel.J.Hydraul.Res.1990,28(2):175-196.
[46]Knight DW,Brown F.,Valentine E.,Nalluri C.,Bathurst J.,Benson I.,Myers R.,Lyness J.,Cassells J.The response ofstraight mobile bed channels to inbank and overbank flows.PROCEEDINGS OF THE INSTITUTION OF CIVIL ENGINEERS-WATER MARITIME AND ENERGY.1999,136(4):211-224.
[47]Knight DW,Brown FA.Resistance studies of overbank flow in rivers with sediment using the flood channel facility.JOURNAL OFHYDRAULIC RESEARCH,.2001,39(3):283-301.
[48]Lambert MF,Sellin RHJ.Estimating the discharge capacity of doubly sinuous compound channels.PROCEEDINGS OF THEINSTITUTION OF CIVIL ENGINEERS-WATER AND MARITIME ENGINEERING.2000,142(2):103-112.
[49]Lane E.W.,Kalinske A.A.Engineering calculations of suspended sediment Trans.AGU.1941,22:56-65.
[50]Laursen E.M.A concentration distribution formula from the revised theory of Prandtl mixing length.Proc.1st Int.Symp.onRiver Sedimentation,Guanghua Press,Beijing,China,1980.1:237-244.
[51]Li Zhonglong,Alan Gdavies.Towards predicting sediment transport in combined wave-current flow.J.Watway.,Port,Coast.,and Ocean Eng.1996,122(4).
[52]Liu Qingquan,Chen Li,Liu Dayou.Effects of Existence of Sediment Particles on Energy Loss of Sediment-laden Flow.J.SedimentResearch.1996,11(3).
[53]Lyness JF,Myers WRC,O’Sullivan JJ.Hydraulic characteristics of meandering mobile bed compound channels.PROCEEDINGSOF THE INSTITUTION OF CIVIL ENGINEERS-WATER MARITIME AND ENERGY.1998,130(4):179-188.
[54]Meyer-Peter E.and Muller,R.Formulas for bed load transport.Trans.of Int.Association for Hydraulic Res.,Second Meeting.Stockholm.1948,39-65.
[55]Meyer-Peter E.,H.Favre and H.A.Einstein.Neuere versuchsre sultate uber den gesxhiebetrieb.Schwiez.Bauzeitung.1934,103(12):145-150.
[56]Morris G.L.,Fan,J.H.Reservoir sedimentation handbook.McGraw-Hill.1997.
[57]Myers WRC,Knight DW,Lyness JF,Cassells JB,Brown F.Resistance coefficients for inbank and overbank flows.PROCEEDINGS OF THE INSTITUTION OF CIVIL ENGINEERS-WATER MARITIME AND ENERGY.1999,136(2):105-115.
[58]Myrhaug D.et al.Measurements and analysis of flow velocity and sediment concentration at the sea bed.In Sediment transportMechanisms in Coastal Environments and Rivers.Edited by RD Rajaona,Applied Mechanics Reviews.1995,48(9):570-588.
[59]Ni JR,Wang,GQ,Borthwick AGL.Kinetic theory for particles in dilute and dense-solid-liquid flows.JOURNAL OFHYDRAULIC ENGINEERING,ASCE.2000,126(12):893-903.
[60]Nino Y.,Gracia M.H.Experiments on particle-turbulence interactions in the near-wall region of an open channel flow:Implication for sediment transport.J.Fluid Mech.1996,326:285-319.
[61]Rouse H.Experiments on the mechanics of sediment suspension.Proceedings of the 5th international congress for appliedmechanics.1938,550-554.
[62]Rouse H.Modern conceptions of the mechanics of turbulence.Trans.ASCE.1937,102:436-507.
[63]Sellin R,Beesten D.Conveyance of a managed vegetated two-stage river channel.Water Management,PROCEEDINGS OF THEINSTITUTION OF CIVIL ENGINEERS.2004,157:21-33.
[64]Shiono K.,and D.Knight.Turbulent open channel flows with variable depth across the channel.J.Fluid.Mech.1991,222:617-646.
[65]Shvidchenko AB;Pender,G.Flume study of the effect of relative depth on the incipient motion of coarse uniform sediments.WATER RESOURCES RESEARCH.2000,36(2):619-628.
[66]Shvidchenko AB,Pender G.Initial motion of streambeds composed of coarse uniform sediments.PROCEEDINGS OF THEINSTITUTION OF CIVIL ENGINEERS-WATER MARITIME AND ENERGY.2000,142(4):217-227.
[67]Shvidchenko AB,Pender G,Hoey TB.Critical shear stress for incipient motion of sand/gravel streambeds.WATER RESOURCESRESEARCH.2001,37(8):2273-2283.
[68]Tanaka S.,Sugimoto S.On the distribution of suspended sediment in experimental flume flow.Memoirs of the Faculty of Engrg.Kobe Univ.,Kobe,Japan.1958,(5):61-71.
[69]Velikanov M.A.Alluvial Process,State Publishing House for Physical and Mathematical Literature,Moscow.1958,241-245(in Russian).
[70]Tetzlaff D.M.Harbaugh J.W.Simulating clastic sedimentation.New York:Van Nostrand Reinhold.1989.
[71]Van Rijn L.C.Sediment transport,partⅠ:bed load transport.Journal of Hydraulic Engineering,ASCE.1984,110(10):431~1455.
[72]Van Rijn L.C.Sediment transport,partⅡ:Suspended load transport.J.Hydr.Engrg.,ASCE.1984,110(11):1613-1641.
[73]Vajda M.L.Local resistance to turbulent flow over a rough bed.Proc.Euromech 262 on“Sand Transport in Rivers,Estuariesand the Sea.”Ed.by R.Soulsby and R.Bettess,A.A.Balkema.1991.
[74]Wang Guangqian,Xia Junqiang and Zhang Hongwu.Theory and practice of hyperconcentrated sediment-laden flow in China.Theproceedings of the 13th congress of the Asia and Pacific Division(APD)of the International Association for Hydraulic Engineeringand Research,Singapore.2002,1055-1071.
[75]Wang XK,Wang ZY,Yu MZ,Li DX.Velocity profile of sediment suspensions and comparison of log-law and wake-law.J HydrRes,IAHR.2001,39(2):211-217.
[76]Wang XK,Qian N.Velocity profile of sediment-laden flow.Int J Sediment Research.1992,7(1):27-57.
[77]Wang XK,Qian N.Turbulence characteristics of sediment-laden flow.J Hydr Eng,ASCE.1989,115(6):781-800.
[78]White WR,Bettess R.,Paris E.Analytical approach to river regime.Journal of the Hydraulics Division,Proceedings of theAmerican Society of Civil Engineers.1982,108:1179-1193.
[79]Wu W.M.,Rodi W.and Wenka T.3D Numerical modeling of flow and sediment and sediment transport in open channels.Journal of Hydraulic Engineering,ASCE.2000,126(1):4-15.
[80]Xu JX.Hyperconcentrated flows in the slope-channel systems in gullied hilly areas on the loess plateau,China.GeografiskaAnnaler Series A-Physical Geography.2004,86A(4):349-366.
[81]Xu JX.A study of physical-geographical factors for formation of hyperconcentrated flows in the loess plateau of China.Geomorphology.1998,24(2-3):245-255.
[82]Yalin,M.S.River Mechanics.Pergamon Press,Oxford.1972,1-219.
[83]Yang C T.Incipient Motion and Sediment Transport.Journal of Hydraulic Engineering,ASCE.1973,99(HY10).
[84]Yang CT.Minimum unit stream power and fluvial hydraulics.Journal of the Hydraulics Division,Proceedings of the AmericanSociety of Civil Engineers.1976,102:769-784.
[85]Zhang Junhua,Zhao Lianjun,Yang Ming,Ma Huaibao.Impact on movable model of time distortion ratio analysis.29TH IAHRCongress,Beijing.2001.
[86]Zhong DY,Liu J,Zhang H,and Wang GQ.A PDF model for entrainment rate of bed sediment into suspension,Proc.29th IAHRCongress,Theme E,Beijing.2001.
[87]Zhou J.,Lin B.L.and Lin B.Rational Basis for Suspended Sediment Modeling,International Journal of Sediment Research.2003,18(3):Sept.,1-12.
[88]Zhou J.J.and Lin B.N.1D mathematical model for suspended sediment with lateral integration.Journal of HydraulicEngineering,ASCE.1998,124(7):712-717.
[89]Zhou J.J.,Lin B.N.Bed conditions of non-equilibrium transport of suspended sediment.International Journal of SedimentResearch.1997,12(3):241-248.
[90]Zhou J.J.A new approach to the equation for non equilibrium transport of suspended sediment.The Proc.of the 7th Congress ofADP-IWHR,Beijing,China.1990.
[91]Zyserman J.A.,Fredsoe,J.Data analysis of bed concentration of suspended sediment.J.Hydr.Engrg.,ASCE.1994,120(9):1021-1042.
[92]曹如轩,陈景梁.水库高含沙水流冲淤计算问题[A].河流国际泥沙学术讨论会论文集[C].1980,2.783-792.
[93]曹叔尤.Fluvial Hydraulic Geometry(河流水力几何形态学)[M].成都:成都科技大学出版社.1996.
[94]曹叔尤.水力学及河流动力学基本问题研究的现状与任务[J].四川大学学报(工程科学版),2002,(1):1-5.
[95]曹文洪,张启舜.潮流和波浪作用下悬移质挟沙能力的研究[J].泥沙研究,2000,(5):16-21.
[96]长江水利水电科学研究院.水库不平衡输沙的初步研究[A].水库泥沙报告汇编.黄河水库泥沙观测研究成果交流会文集[C].1973.
[97]长江水利水电科学研究院.水库冲淤过程的计算方法及电子计算机的应用[A].长江水利水电科研成果选编[C].1974,2.
[98]陈济生,等.三峡工程泥沙研究,长江三峡工程技术丛书[M].武汉:湖北科学技术出版社.1997.
[99]陈立,林鹏,叶小云.泥沙对挟沙水流流动结构影响的研究[J].水利学报,2003,(9).
[100]陈立,王明甫.水流强度对高含沙水流流变参数影响的实验研究[J].泥沙研究,1993,(2).
[101]陈立.高含沙水流流变参数和阻力的变化规律[J].武汉水利电力学院学报,1992,(4).
[102]陈文彪,王琳,邓家泉,许祥向,钟上海.珠江口伶仃洋的治理研究[J].水利学报,1999,(3):75-81.
[103]陈稚聪,王光谦,詹秀玲.细颗粒塑料沙的群体沉速及起动流速试验研究[J].水利学报,1996,(2):24-29.
[104]丁君松,王树东.漫滩水流的水流结构及其悬沙运动[J].泥沙研究,1989,(1).
[105]丁君松,杨国录,熊治平.分汊河段若干问题的探讨[J].泥沙研究,1982,(4).
[106]丁君松.悬移质含沙量沿垂线分布的研究及其应用[J].武汉水利电力学院学报,1981,(4).
[107]丁君松,丘凤莲.汊道分流分沙计算[J].泥沙研究,1981,(1).
[108]窦国仁.再论泥沙起动流速[J].泥沙研究,1999,(6):1-9.
[109]窦国仁,董凤舞.波浪和潮流的挟沙能力[J].科学通报,1995,40(5).
[110]窦国仁.潮汐水流中悬沙运动及冲淤计算[J].水利学报,1963,(4):13-24.
[111]窦国仁.论泥沙起动流速[J].水利学报,1960,(4):44-60.
[112]窦希萍,张辛农.南科院近10年泥沙研究工作综述[J].泥沙研究,1999,(6):17-20.
[113]范家骅,吴德一,沈受百,姜乃森.浑水异重流实验研究及其应用[A].河流国际泥沙学术讨论会论文集[C].1980,1:227-236.
[114]费祥俊.浆体与粒状物料输送水力学[M].北京:清华大学出版社,1994.1-473.
[115]费祥俊.泥沙的群体沉降—两种典型情况下非均匀沙沉速计算[J].泥沙研究,1992,(3):11-19.
[116]费祥俊.高浓度浑水的粘滞系数[J].水利学报,1982,(3).
[117]韩其为.水库淤积[J].北京:科学出版社,2003.
[118]韩其为,何明民.泥沙起动规律及起动流速[J].北京:科学出版社,1999.
[119]韩其为,何明民.泥沙运动统计理论[J].北京:科学出版社,1984.
[120]韩其为.论挟沙能力级配[A].第六届全国泥沙基本理论研究学术讨论会论文集[C].郑州:黄河水利出版社,2005.1-20.
[121]韩其为.推移质中的几个理论问题研究[J].中国水利,2004,(18):48-52.
[122]韩其为,何明民.恢复饱和系数初步研究[J].泥沙研究,1997,(3):32-40.
[123]韩其为,何明民.非均匀沙起动机理及起动流速[J].长江科学院院报,1996,(3):12-17.
[124]韩其为.非均匀悬移质不平衡输沙的初步研究[J].科学通报,1979,(7):804-808.
[125]韩文亮,董曾南,柴宏恩.含高浓度固体粒状物料管流中水击规律[J].中国科学E辑,1998,(2):183-192.
[126]胡春宏,惠遇甲.明渠挟沙水流运动的力学和统计规律[M].北京:科学出版社,1995,1-343.
[127]胡春宏.我国江河治理与泥沙研究展望[J].水利水电技术,2001,(1):50-52.
[128]胡春宏,周文浩.中国水科院十多年来泥沙研究综述[J].泥沙研究,1999,(6):12-16.
[129]惠遇甲,李义天,胡春宏,等.高含沙水流紊动结构和非均匀沙的运动规律的研究[M].武汉:武汉水利电力大学出版社,2000.
[130]黄胜,卢启苗.河口动力学[M].北京:水利电力出版社,1993.
[131]黄委会.黄河首次调水调沙试验[M].郑州:黄河水利出版社,2003,181-212.
[132]康志成,章书成.泥石流流体特性的初步研究[A].河流国际泥沙学术讨论会论文集[C].1980,1:213-226.
[133]金缪.“导流、挡沙、减淤”——长江口深水航道治理设计思想的新飞跃[J].海洋工程,2001,3:18-19.
[134]李保如.三门峡水库拦沙期下游河道的变化[A].河流泥沙国际学术研讨会论文集[C].1980,1.
[135]李国英.基于空间尺度的黄河调水调沙[J].人民黄河,2004,(2):1-5.
[136]李国英.黄河调水调沙[J].人民黄河,2002,(11):1-5.
[137]林一山.水库长期使用问题[J].人民长江,1978,(2).
[138]刘家驹.粉沙淤泥质海岸的航道淤积[J].水利水运工程学报,2004,(1):6-11.
[139]刘家驹.连云港外航道的回淤计算与预报[J].水利水运科学研究,1980,(4):31-41.
[140]刘金梅,王士强,王光谦.冲积河流长距离冲刷不平衡输沙过程初步研究[J].水利学报,2002,(2):57-53.
[141]刘兴年.宽级配推移质输移特性研究[J].泥沙研究,2000,(4).
[142]刘兴年,曹叔尤,方铎.90年代四川大学泥沙研究回顾与瞻望[J].泥沙研究,1999,(6):33-36.
[143]李义天,邓金运,孙昭华,李荣.河流水沙灾害及其防治[M].武汉:武汉大学出版社,2004.1-284.
[144]李义天,谢鉴衡,王明甫.武汉水利电力大学泥沙研究进展[J].泥沙研究,1999,(6):26-28.
[145]李义天.冲积河道平面变形计算初步研究[J].泥沙研究,1988,(1):34-44.
[146]李义天.冲淤平衡状态下床沙质级配初探[J].泥沙研究,1987,(1):82-87.
[147]罗海超,周学文,等.长江中下游分汊河型成因研究[A].河流泥沙国际学术讨论会论文集[C].光华出版社,1980.
[148]马蔼乃.地理遥感信息模型与地理数学[J].测绘科学,2000,(2):10-15.
[149]倪晋仁,马蔼乃.河流动力地貌学[M].北京:北京大学出版社,1998.
[150]倪晋仁,王光谦,张红武.固液两相流基本理论及其最新应用[M].北京:科学出版社,1991.1-391.
[151]潘庆.长江水利枢纽工程泥沙研究[M].北京:中国水利水电出版社,2003.
[152]潘庆,杨国录,府仁寿.三峡工程泥沙问题研究[M].北京:中国水利水电出版社,1999.
[153]潘庆,等.下荆江裁弯经验总结[J].人民长江,1978,(1).
[154]潘庆,史绍权,段文忠.长江中游河段人工裁弯河道演变研究[J].中国科学,1978,(2).
[155]齐璞,刘月兰.黄河水沙变化与下游河道减淤措施[M].郑州:黄河水利出版社,1997.
[156]钱宁.高含沙水流运动[M].北京:清华大学出版社,1989.1-206.
[157]钱宁,张仁,周志德.河床演变学[M].北京:科学出版社,1989.1-584.
[158]钱宁,万兆惠.泥沙运动力学[M].北京:科学出版社,1983.687.
[159]钱宁,范家骅.异重流[M].北京:水利出版社,1957.
[160]钱宁.推移质公式的比较[J].水利学报,1980,(4):1-11.
[161]秦荣昱.不均匀沙的起动规律[J].泥沙研究,1980,(复刊号).
[162]钱意颖,杨文海,赵文林.高含沙水流的基本特性[A].河流泥沙国际学术研讨会论文集[C].1980.175-184.
[163]饶庆元.粘性土抗冲特性研究[J].长江科学院院报,1987,(4).
[164]沙玉清.泥沙运动学引论[M].北京:中国工业出版社,1996.1-285.
[165]史立人.长江江源地区的河流及其发育[A].长江水利水电科研成果选编[C].1979.6.
[166]谈广鸣,陈立.河床变形混交模型预测技术及其进展[J].水利水电科技进展,2001,(4):14-19.
[167]唐存本.泥沙起动规律[J].水利学报,1963,(2):1-12.
[168]唐日长.泥沙研究,葛洲坝工程丛书[M].北京:水利电力出版社,1990.
[169]唐日长,等.荆江特性研究[J].中国地理学会一九七七年地貌学术讨论会文集[C].科学出版社,1981.
[170]唐日长,潘庆.蜿蜒性河道形成原因及造床试验初步研究[J].人民长江,1964,(2).
[171]万兆惠,宋天成.“揭河底”现象的分析[J].泥沙研究,1991,(3).
[172]万兆惠,宋天成,何青.水压力对细颗粒起动流速影响的试验研究[J].泥沙研究,1990,(4):62-69.
[173]万兆惠,钱意颖.高含沙水流的室内试验研究[J].人民黄河,1979,(1):53-65.
[174]王光谦,张红武,夏军强.游荡型河流演变与模拟[M].北京:科学出版社,2005.
[175]王光谦,张仁,惠遇甲,王桂仙,王兴奎.清华大学泥沙研究回顾[J].泥沙研究,1999,(6):21-25.
[176]王光谦,费祥俊,倪晋仁.快速颗粒流碰撞应力的动理模型[J].力学学报,1993,(3):348-355.
[177]王立新.层移质运动基本规律的试验研究[D].清华大学,1986.
[178]王明甫,陈立,周宜林.高含沙水流游荡型河道滩槽冲淤演变特点及机理分析[J].泥沙研究,2000,(1).
[179]王明甫,段文忠,谈广鸣,等.高含沙水流的水流结构及运动机理[J].中国科学,A辑,1987,(5).
[180]王士强.明槽水流的非均匀挟沙力研究[J].水利学报,1998,(1):1-9.
[181]王士强.黄河泥沙冲淤数学模型研究[J].水科学进展,1996,(3):193-199.
[182]王士强.沙波运动与床沙调整[J].泥沙研究,1992,(4):14-23.
[183]王树东.漫滩水流的二维流速分布与水力学计算[J].水利学报,1986,(11).
[184]王兴奎.河流动力学基础[M].北京:中国水利水电出版社,2002.
[185]王兴奎.悬移质泥沙运动及其对水流结果的影响[D].清华大学,1985.
[186]王兴奎,钱宁,胡维德.黄土丘陵沟壑区高含沙水流的形成及汇流过程[J].水利学报,1982,(7):26-35.
[187]王兆印.中国泥沙研究的几个问题[J].泥沙研究,2003,(4):73-81.
[188]王兆印.泥沙研究的发展趋势和新课题[J].地理学报,1998,(3):245-255.
[189]王兆印,钱宁.高浓度泥沙悬浮液物理特性的实验研究[J].水利学报,1984,(4):1-10.
[190]夏震寰,汪岗.无粘性均质颗粒在细颗粒悬浮液中的沉降[J].泥沙研究,1982,(1):14-23.
[191]谢汉祥.漫滩水流特性与水力学计算[A].河流泥沙国际学术讨论会论文集[C].1980.161-169.
[192]谢鉴衡.江河演变与治理研究[M].武汉:武汉大学出版社,2004.
[193]谢鉴衡.河流模拟[M].北京:水利水电出版社,1990.
[194]谢鉴衡.河流泥沙工程学(上册)[M].北京:水利电力出版社,1983.
[195]谢鉴衡.下荆江蜿蜒型河段成因及发展前景初探[A].长江三峡工程泥沙研究论文集[C].中国科学技术出版社,1989.
[196]徐幕菊.都江堰的泥沙[J].泥沙研究,1981,(1):42-57.
[197]许炯心.黄土高原丘陵沟壑区坡面-沟道系统中的高含沙水流[J].自然灾害学报,2004,(1).
[198]许炯心.黄土高原高含沙水流形成的自然地理因素[J].地理学报,1999,(4).
[199]尹学良.弯曲性河流形成原因及造床试验初步研究[J].地理学报,1965,31.
[200]余文畴,卢金友.长江中下游河道整治和护岸工程实践与展望[J].人民长江,2002,(8):15-17.
[201]余文畴,卢金友.长江河流泥沙研究与河道治理,伟大的事业、光辉的历程[M].北京:中国科学技术出版社,2001.43-59.
[202]余文畴.长江中下游河道水力和输沙特性-初论分汊河道形成条件[J].长江科学院院报,1994,(4).
[203]余文畴.长江分汊河道口门水流及输沙特性[J].长江水利水电科学研究院院报,1.
[204]余文畴,卢金友,龙超平,范北林.长江河流泥沙研究十年[J].泥沙研究,1999,(6):42-45.
[205]杨怀仁,唐日长.长江中游荆江变迁研究[M].北京:中国水利水电出版社,1999.
[206]杨美卿.河流与海岸动力学引论[M].北京:水利电力出版社,1993.
[207]杨美卿,钱宁.紊动对细泥沙浆液絮凝结构的影响[J].水利学报,1986,(8):21-30.
[208]杨国录.平面二维水流挟沙力初探[A].见:中国水利学会编.第2届全国泥沙基本理论研究学术讨论会论文集[C].北京:中国建材工业出版社,1995.359-364.
[209]杨廷瑞,万兆惠,迟耀瑜,徐义安,王在阳,赵乃熊.高含沙浑水利用问题的研究[A].河流国际泥沙学术讨论会论文集[C].1980.93-102.
[210]尹学良.官厅水库修建后永定河下游河道的变化[J].泥沙研究,1958,(2):38-39.
[211]姚文艺,王德昌,侯志军.多沙河流河工动床模型“人工转折设计方法”研究[J].泥沙研究,2002,(5):25-31.
[212]詹义正,王明甫,白永峰.论浆河形成的临界条件[J].泥沙研究,1991,(3).
[213]赵龙保.流动盐水中细颗粒粘性泥沙的沉降速度[A].全国泥沙基本理论研究学术讨论会论文集[C].1992.1.
[214]赵业安.1977年下游高含沙洪水的输移与演变分析[J].泥沙研究,1984,(4).
[215]H.H.Chang.Fluvial Processes in River Engineering.John Wiley&Sons,Inc.1988.方铎,曹叔尤译.河流演变工程学[M].北京:科学出版社,1990.1-333.
[216]张浩,任增海,等.高含沙水流泥沙沉降规律与阻力特性[A].河流国际泥沙学术讨论会论文集[C].1980.1.
[217]张红武,等.黄河高含沙洪水的模型相似律[M].郑州:河南科学技术出版社,1994.1-165.
[218]张红武.河工动床模型相似律研究进展[J].水科学进展,2001,(2):256-263.
[219]张红武,姚文艺,张俊华,钱意颖.黄科院90年代泥沙研究进展[J].泥沙研究,1999,(6):37-41.
[220]张红武,张清.黄河水流挟沙力的计算公式[J].人民黄河,1993,(11):7-9.
[221]张丽春,周建军,府仁寿.时间变态对水流及泥沙运动的影响的初步分析[J].泥沙研究,2000,(5):37-44.
[222]张俊华,张红武.黄河水库泥沙模型相似律的初步研究[J].水利发电学报,2001,(3):52-58.
[223]张启舜.明渠水流泥沙扩散过程的研究及其应用[J].泥沙研究,1980,(复刊号):37-52.
[224]张瑞瑾.河流动力学[M].北京:中国工业出版社,1961.1-302.
[225]张瑞瑾,谢鉴衡,王明甫.河流泥沙动力学[M].北京:水利电力出版社,1989.1-291.
[226]张瑞瑾.高含沙量水流流性初探[J].武汉:武汉水利电力学院学报,1978,(1).
[227]钟德钰,张红武,王光谦.冲积河流混合活动层床沙级配的动力学基本方程[J].水利学报,2004,(9):24-30.
[228]中国科学院地理研究所,长江水利水电科学研究院,长江航道局规划设计研究所.长江中下游河道特性及其演变[M].北京:科学出版社,1985.
[229]周建军.平面二维泥沙数学模型的研究及应用[J].水利学报,1993,(11):10-19.
[230]周济福,李家春.河口混合与泥沙输运[J].力学学报,2000,32(5):523-531.
[231]周济福,刘青泉,李家春.河口混合过程研究[J].中国科学(A辑),1999,29(9):835-843.CHINESE NUCLEUS JOURNAL
基本信息:
DOI:10.16239/j.cnki.0468-155x.2007.02.010
中图分类号:TV143
引用信息:
[1]王光谦.河流泥沙研究进展[J].泥沙研究,2007(02):64-81.DOI:10.16239/j.cnki.0468-155x.2007.02.010.
基金信息: