船闸结构时变演化的多场耦合静动力分析与研究
摘要
船闸与周围的地基、水组成一个十分复杂的力学系统,并承受重力场、温度场、渗流场、流场等多种场的综合作用。整个力学系统及其受力具有强烈的时变演化特性,其形成是随混凝土的浇筑施工不断变化,承受的各种场作用也是逐步被施加到结构体系上,其强弱不断变化,并与结构的位移场、应力场等产生极其复杂的随时间不断变化的相互关联和耦合关系,而以往的分析方法难以加以考虑。本文采用多场耦合分析方法,考虑船闸结构系统的时变演化过程,对其进行力学分析,主要研究内容如下:
(1)对修建在软土地基上的船闸结构按照施工过程及时变演化特性进行重力场、渗流场及应力场的多场耦合分析,分析软土地基上船闸底板混凝土产生裂缝的原因,指出底板自重荷载分析的演化特性考虑不全面,建议计算底板负弯矩时宜不计其自重产生的弯矩。
(2)对修建在岩基上的船闸结构按照施工过程及时变演化特性进行温度场、重力场及应力场的多场耦合分析,分析岩基上船闸混凝土产生裂缝的原因,并在此基础上,提出了一种新型的预留宽缝施工方法,这种施工方法既能有效改善结构的受力,又能提高施工质量和施工进度。
(3)以往对船闸输泄水系统的阀门流激振动问题多集中在高水头的反向弧形阀门研究上,本文对中低水头船闸的平面阀门-吊杆-支承梁在水流作用下的混凝土损毁问题进行了研究,指出流激引起阀门、吊杆振动导致支承梁长期承受荷载作用而导致疲劳是发生破坏的重要原因,并提出了相应的改善加固措施。
The mechanical system, being consisted of the lock, the surrounding foundationand the water, is very complex because the structure itself is changing inconstruction period and is influenced synthetically by the gravity field, temperaturefield, seepage field, flow field and so on. With the changing of the concrete pouringconstruction, the mechanical system is being changed. And with the changing ofexternal condition, the physical field’s feature is being changed. At the same time,the above change is gradually exerted on the system and on the physical field. So,the displacement field, stress field and etc of the system and the changing fields forma complicated and time-varying correlative and coupling relationship, which lead tothe time-varying evolution characteristics of the system. It is difficult to analysis thecomplex system with the general method. Thus, in this paper, multi-field couplinganalytic method are used to analysis the time-varying evolution progress and thestress of the lock system. The main research contents are as follows. The system andthe load have a strong time-varying evolution characteristic.
(1)The cause of longitudinal cracks on the top of the large lock built on softfoundation is discussed by comparing the result of the general method and the resultof the simulation method, considerating the construction process and the couplingeffect of gravity field, seepage field and stress field. And it is explained partly that itis an important one of the reasons because of including the effect of the lock floor’sdeadweigh. So, it is suggested that engineers should exclude the lock floor’sdeadweight when computing the negative moment.
(2)The cause of longitudinal cracks on the top of the large lock built on rockfoundation is discussed and explaided by comparing the result of the general methodand the result of the simulation method of considerating the weather, theconstruction process and the coupling effect of temperature field and stress field, etc.Based on the above, the paper proposes a new construction method of setting upconstruction joints on the lock floor that can improve the construction quality andreduce construction time.
(3)Researchers generally concentrate on the flow-induced vibration problemsof the high head lock’s valve that is mostly a reverse arc valve. The paper discussesthe flow-induced vibration problem of the low head lock’s valve and supplementsthe results of research in this area. It is pointed out that the damage cause is mostlybecause the supporting beam was being under long-term vibrating load of the lockLose drain system’s boom and gate. Based on the above, this paper put forwardcorrespond measures to reduce valve’s vibration and improve mechanical propertiesof the supporting beam.
(1)对修建在软土地基上的船闸结构按照施工过程及时变演化特性进行重力场、渗流场及应力场的多场耦合分析,分析软土地基上船闸底板混凝土产生裂缝的原因,指出底板自重荷载分析的演化特性考虑不全面,建议计算底板负弯矩时宜不计其自重产生的弯矩。
(2)对修建在岩基上的船闸结构按照施工过程及时变演化特性进行温度场、重力场及应力场的多场耦合分析,分析岩基上船闸混凝土产生裂缝的原因,并在此基础上,提出了一种新型的预留宽缝施工方法,这种施工方法既能有效改善结构的受力,又能提高施工质量和施工进度。
(3)以往对船闸输泄水系统的阀门流激振动问题多集中在高水头的反向弧形阀门研究上,本文对中低水头船闸的平面阀门-吊杆-支承梁在水流作用下的混凝土损毁问题进行了研究,指出流激引起阀门、吊杆振动导致支承梁长期承受荷载作用而导致疲劳是发生破坏的重要原因,并提出了相应的改善加固措施。
The mechanical system, being consisted of the lock, the surrounding foundationand the water, is very complex because the structure itself is changing inconstruction period and is influenced synthetically by the gravity field, temperaturefield, seepage field, flow field and so on. With the changing of the concrete pouringconstruction, the mechanical system is being changed. And with the changing ofexternal condition, the physical field’s feature is being changed. At the same time,the above change is gradually exerted on the system and on the physical field. So,the displacement field, stress field and etc of the system and the changing fields forma complicated and time-varying correlative and coupling relationship, which lead tothe time-varying evolution characteristics of the system. It is difficult to analysis thecomplex system with the general method. Thus, in this paper, multi-field couplinganalytic method are used to analysis the time-varying evolution progress and thestress of the lock system. The main research contents are as follows. The system andthe load have a strong time-varying evolution characteristic.
(1)The cause of longitudinal cracks on the top of the large lock built on softfoundation is discussed by comparing the result of the general method and the resultof the simulation method, considerating the construction process and the couplingeffect of gravity field, seepage field and stress field. And it is explained partly that itis an important one of the reasons because of including the effect of the lock floor’sdeadweigh. So, it is suggested that engineers should exclude the lock floor’sdeadweight when computing the negative moment.
(2)The cause of longitudinal cracks on the top of the large lock built on rockfoundation is discussed and explaided by comparing the result of the general methodand the result of the simulation method of considerating the weather, theconstruction process and the coupling effect of temperature field and stress field, etc.Based on the above, the paper proposes a new construction method of setting upconstruction joints on the lock floor that can improve the construction quality andreduce construction time.
(3)Researchers generally concentrate on the flow-induced vibration problemsof the high head lock’s valve that is mostly a reverse arc valve. The paper discussesthe flow-induced vibration problem of the low head lock’s valve and supplementsthe results of research in this area. It is pointed out that the damage cause is mostlybecause the supporting beam was being under long-term vibrating load of the lockLose drain system’s boom and gate. Based on the above, this paper put forwardcorrespond measures to reduce valve’s vibration and improve mechanical propertiesof the supporting beam.
引文
[1]杨本新,李江鹰,葛洲坝1号船闸混凝土裂缝成因及加固研究,人民长江[J],2003,34(2):29-31,56
[2]胡文利,李虎章,三峡五级船闸混凝土温度控制措施效果分析,武汉大学学报(工学版)[J],2003,36(5):30-34
[109]叶国华,港工混凝土结构物的温度应力和温度裂缝的研究,水运工程[J],1996,(8):16-26
[3]李晓凌,汪泓,樊口大闸裂缝处理方案研究,水利水电快报[J],2002,23(14):22-24
[4]郑立平,刘俊义,樊口大闸加固工程主要技术措施研究,人民长江[J],2005,36(4):15-16,65
[5]魏涛,蔡胜华,新城船闸下闸首裂缝处理,长江科学院院报[J],2000,17(6):56-57,63
[6]段仲源,石建军,宋会莲等.化学灌浆在船闸裂缝动水封堵中的应用,南华大学学报(理工版)[J],2004,(1):25-27
[7]张彦民,陈峰,董小卓,薄壁混凝土结构裂缝成因分析及防止措施,湖北水力发电[J],2009,(2):16-19
[8]赵全江,陈立军,薄壁结构砼的裂缝与处理,海岸工程[J],2004,23(3):34-41
[116]朱平,王海滨,刘宏新,船闸工程闸室侧墙裂缝分析与处理,水运工程[J],2006,(8):116-119
[9]王昆,船闸混凝土底板裂缝化学灌浆补强处理技术,水运工程[J],2009,(8):146-149
[10]金国强,孙维萍,陈学国,船闸混凝土裂缝机理与控制措施研究,浙江交通科技[J],2006,(4):57-59
[11]辛彦青,李振声,船闸混凝土温度裂缝的经验教训,水运工程[J],2002,(8):78-80,85
[12]陆娟,船闸廊道裂缝预防初探——以京杭运河淮阴三线船闸工程为例,交通标准化[J],2008,(3):175-177
[13]汤凯,陶华,船闸裂缝发生的机理及其防治,徐州建筑职业技术学院学报[J],2006,6(3):23-26
[14]汪国勤,船闸闸首闸室墙面损坏修理技术,水运工程[J],1993,(1):34-36
[15]聂霞,京杭运河谏壁二线船闸闸室墙防裂技术试验研究,中国港湾建设[J],2002,(2):19-23
[16]陆四雄,张廷辉,刘老涧三线船闸上闸首裂缝研究,水利科技与经济[J],2007,13(12):942-945
[17]鲍颖杰,新坝船闸输水廊道混凝土裂缝防治措施,水运工程[J],2007,(7):85-88
[18]高修,颍上船闸闸室边墙裂缝分析,治淮[J],2008,(10):21
[19]方朝阳,段亚辉,三峡永久船闸输水洞衬砌施工期温度与应力监测成果分析,人民长江[J],2004,35(7):13-14
[20]林金良,陈合爱,两种修补材料处理三峡船闸混凝土缺陷的实践,人民长江[J],2006,37(5):34-35
[21]张秋光,场论[M],北京:地质出版社,1988年
[22]卢焕忠,场论及其应用[M],北京:地质出版社,1981年
[23]宋少云,多场耦合问题的分类及其应用研究,武汉工业学院学报[J],2008,27(3):46-49
[24]Felippa C A, Park K C, Farhat C. Partitioned analysis of coupled mechanicalsystems[J].Computer Methods in Applied Mechanics and Engineering.2001,190(24-25):3247-3270
[25]宋少云,多场耦合问题的协同求解方法研究与应用:[博士学位论文],武汉;华中科技大学,2007
[26]朱伯芳,王同生,丁宝瑛,郭之章水工混凝土结构的温度应力与温度控制[M],北京水利电力出版社,1976
[27] Wilson E L. The determination of temperatures within mass concrete structures(SESM Report No.68-17),Structures and Materials Research. Department of CivilEngineering, University of California,Berkeley,Dec.1968
[28]Tatro Stephen B,Schrader Ernest K. Thermal considerations for roller-compactedconcrete,ACI Journal,March~Aprial,1988
[29]P.R Barrett, H Foadian, R.J. James, Y.R. Rashid.Thermal–structural analysismethods for RCC dams.Roller compacted concrete III, ASCE, New York (1992), pp.407–422
[30]Barrett P K,et al. Thermal structure analysis methods for RCC dams,Proceedingof conference of roller compacted concrete Ⅲ,Sam Diedo,California,1992:389-406
[31]Tohru Kawaguchi,Sunao Nakane,Investigations on determining thermal stress inmassive concrete structures,ACI. Vol93,1996(1):96-101
[32]Kim Jang-Ho Jay, Jeon, Sang-Eun, Kim. Development of new device formeausuring thermal stress,Cement and Concrete Research,2002,32(10):1651-1654
[33] Zhu Bofang. Computation of thermal stresses in mass concrete withconsideration of creep effect[c].Fifteenth International Congress on LargeDams,Lausanne,Suisse,June,1985:24-28
[34]朱伯芳,多层混凝土结构仿真分析的并层算法,水力发电学报[J],1994,(3):21-30
[35]朱伯芳,许平,混凝土坝仿真计算的并层算法和分区异步长算法[J],水力发电,1996,(1):38-43
[36]朱伯芳,不稳定温度场数值分析的时间域分区异步长算法[J],水利学报,1995,(8):40-52
[37]朱伯芳,弹性徐变体的分区异步长算法[J],水利学报,1995,(7):23-27
[38]朱伯芳,RCC坝仿真计算非均匀单元的初始条件[J],水力发电学报,2000,68(3):81-85
[39]Li Shouyi,Chen Yaolong,Zhang Xiaofei,et al. Study on contraction joints for theLongtan RCC gravity[J].Dam Engineering,2004,93(4):295-301
[40]何劲,陈尧隆,李守义,寒潮引起的碾压混凝土坝温度应力计算[J],西安理工大学学报,1999,15(4):91-94
[41]Yaolong Chen,Changjiang Wang,Shouyi Li,Simulation analysis of thermalstress of RCC dams using3-D finite element relocating mesh method,Advances inEngineering Software,2001,32(9):677-680
[42]张晓飞,大体积混凝土结构温度场和应力场仿真计算研究:[硕士学位论文],西安:西安理工大学,2009
[43]王建红,陆述远,魏锦萍,RCCD温度应力分析的非均质单元方法[J],力学与实践,1995,17(3):41-44
[44]李克亮,方憬,洪晓林,用并层非均质单元法分析碾压混凝土拱坝的温度应力[J],水利水运工程学报,2001,(3):41-47
[45]刘西军,大体积混凝土温度场温度应力仿真分析:[博士学位论文],杭州:浙江大学,2005
[46]黄达海,殷福新,宋玉普,碾压混凝土坝温度场仿真分析的波函数法[J],大连理工大学学报,2001,(3):214-217
[47]高政国,黄达海等,沙牌碾压混凝土拱坝温度场仿真计算[J],大连理工大学学报,2001,41(1):116-122
[48]黄达海,高政国,沙牌碾压混凝土拱坝损伤开裂分析[J],大连理工大学学报,2001,41(2):244-248
[49]刘光廷,麦家煊,张国新,溪柄碾压混凝土薄拱坝的研究[J],水力发电学报,1997,57(2):19-28
[50]陈里红,傅作新,大体积混凝土结构施工期软化开裂分析[J],水利学报,1992,(3):70-74
[51]侯朝胜,赵代深,混凝土坝温控三维仿真敏感分析及其凝聚方程[J],天津大学学报,2001,34(5):605-610
[52]赵代深,混凝土坝温控因素敏感分析及其在多维空间的凝聚方程[J],水利水电技术,2001,32(11):14-19
[53]刘有志,水工混凝土温控和湿控防裂方法研究:[博士学位论文],南京:河海大学,2006
[54]邢景棠,周盛,崔尔杰,流固耦合力学概述[J],力学进展,1997,27(1):19-38
[55]L anchester FW,To rsional vibration of the tail of an airp lane. A RC R. and M.276, part1(1916)
[56]Bairstow L,Fage A. O scillations of the tailp lane and body of an aerop lane infligh t. A RC R. and M.276, part2(1916). In:Technical Repo rt of the A dviso ryComm ittee fo r A erodynam ics, fo r the year1916-1917. II, H isM ajesty’s StationaryOffice, London (1920):461-467
[57]Theodo rsen T. General theory of aerodynam ic instability and themechanism offlutter,N A CA T R496(1934). In:Twen2tieth A nnaul Repo rt of theN ationalAdviso ry Comm ittee fo rA erodynam ics1934, U S Government P rinting Office, Wash2ington (1935):413-433
[58]居荣初,曾心传,弹性结构与液体的耦联振动理论[M],北京:地震出版社,1983
[59]Westergaard H M. Water pressures on dams during earthquakes. Trans Amer. SocCiv. Eng.,98(1933):418-433
[60]Chopra A K,Earthquake Response of Concrete Gravity Dams,AD709640,California University, Berkeley,1970
[61]居荣初,黄振平,杜瑞明,水中圆柱体结构的自由振动[M],地震工程研究报告集,第一集,科学出版社,北京,1962,
[62]王前信,王考信.伸臂梁在一侧有水时的自振特性与地震荷载[M].地震工程研究报告集,第一集,科学出版社,北京,1962
[63]郑哲敏,马宗魁,悬臂梁在一侧受有液体时的自由振动[J],力学学报,3,2(1959):111-119
[64]李遇春,朱暾,白冰,悬臂梁-流体-悬臂梁耦联系统的湿模态相互作用[J],工程力学,1998,15(1):58-65
[65]王建伟,徐晖,马宁,开放式内嵌流体柔性悬臂梁振颤失稳分析[J],应用力学学报,2010,27(2):259-264
[66]黄志祥,徐晖,徐立勤,内嵌黏性流体欧拉梁的自适应减振模式研究[J],西安交通大学学报,2006,40(9):1009-1103
[67]刘志宏,黄玉盈,Chater梁屈曲传播的动态分析[J],力学学报,1993,25(4):460-467
[68]王建伟,徐晖,马宁,主共振激励下内嵌流体悬臂欧拉梁自适应减振性能研究[J],振动与冲击,2011,30(8):41-44
[69]鲁丽,杨翊仁,无粘流中非线性板梁结构的分叉[J],西南交通大学学报,2004,39(5):641-644
[70]赵文胜,轴向流中板结构流固耦合动力学研究:[博士学位论文],武汉:武汉大学,2011
[71]张杰,流固耦合平板绕流的格子波尔兹曼数值研究:[博士学位论文],合肥:中国科学技术大学,2009
[72]鲁丽,非线性板状结构流固耦合复杂响应研究:[博士学位论文],成都:西南交通大学,2006
[73]王刚,深海采矿作业过程扬矿管线系统空间构形与动态特性研究:[博士学位论文],长沙:中南大学,2008
[74]李小超海底管线悬跨段涡激振动响应的实验研究与数值预报:[博士学位论文],大连:大连理工大学,2011
[75]刘正刚,基于流固耦合的小型旋翼式机械内部水流特性的研究:[博士学位论文],济南:山东大学,2008
[76]郝双户,深水重力式网箱浮架的流固耦合研究:[博士学位论文],大连:大连理工大学,2008
[77]雷凡,水下柔性结构流固耦合动力效应研究:[博士学位论文],武汉:武汉理工大学,2011
[78]徐梦华,大型渡槽梁壳流固耦合动力模型及其工程应用研究:[博士学位论文],广州:华南理工大学,2009
[79]王文全,薄壁结构流固耦合数值模拟及计算方法研究:[博士学位论文],昆明:昆明理工大学,2008
[80]刘建军,地下水渗流的流-固耦合理论及数值方法[J],勘察科学技术,2000,(4):7-10
[81]Hiroshi Y, Hurofuni N. Consolidation of soils by vertical drain well with finitepermeability,Soil and Foundation,1974,6:35-46
[82]刘广生,赵维炳,朱国忠,固结、渗流和沉积控制方程研究[J],南京水利科学研究院,水利水运科技研究,1999,2:207-212
[83]陶震宇,沈小莹,库区应力场的耦合分析[J],武汉水利电力学院学报,1988,(1):8-14
[84]罗晓辉,深基坑开挖渗流与应力耦合分析[J],工程勘察,1996,(6):37-41
[85]陈平,张有天,裂隙岩体渗流与应力耦合分析[J],岩石力学与工程学报,1994,13(4):209-308
[86]李尧臣,陈洁,周顺华,铁路路基施工的渗流——应力耦合模型分析[J],岩土工程学报,2004,26(4):565-568
[87]李术才,李树忱等,泰安抽水蓄能电站围堰稳定性的流——固耦合分析[J],岩石力学与工程学报,2004,23(8):1275-1279
[88]章梦涛,潘一山等,煤岩流体力学[M],北京:北京科学出版社,1995
[89]赵阳升,矿山岩石流体力学[M],北京:煤炭工业出版社,1995
[90]汪有刚,刘建军等,煤与瓦斯流——固耦合渗流的数值模拟[J],煤炭学报,2001,2,6(3):285-289
[91]赵国景,丁继辉,煤与瓦斯突出的固─流两相介质力学理论及数值分析[J],工程力学,1995,12(2):1-7
[92]丁继辉,李凤莲等,有限变形下煤与瓦斯突出的固流两相介质耦合失稳理论[J],工程力学,2008,(25):33-37
[93]丁继辉,麻玉鹏等,煤与瓦斯突出的固一流耦合失稳理论及数值分析[J],水利水电技术,2004,35(11):18-21
[94]王自明,油藏热流一固耦合模型研究及应用初探:[博士学位论文],南充:西南石油学院博士学位论文,
[95]刘建军,裂缝性低渗透油藏流-固耦合理论与数值模型[J],力学学报,2003:614
[96] Jian Jun,Liu etc. Theoretical and experimental studies on the fluid-solid couplingprocess for oil recovery from low permeability fractured International Journal of RockMechanics and Mining science,2004
[97]袁弈群,黑油模型在油田开发中的应用[M],北京:石油工业出版社,1995
[98]赵颖,填埋场渗滤液污染物释放传输的耦合动力学模型及应用研究:[博士学位论文],阜新:辽宁工程技术大学,2008
[99]薛新华,岩土介质流-固耦合非线性损伤力学理论与数值分析:[博士学位论文],杭州:浙江大学,2008
[100]Terzaghi K. Theoretical Soil Mechanics,New York:Tiho Wiley,1943
[101]Biot M A. Theory of elasticity and consolidation for a porous anisotropic solie,Jour Appl Phys,1954,26:182-191
[102]Lubinski A. Theory of elasticity of porous dodies displaying a strong porestructure, Proc.U.S.National Congress of Applied Mechanics,1954,247-256
[103]Geertsman J. A remark on the analogy between thermo-elasticity and theelasticity of saturated porous medial,J.Mech.Phys.Solids,1957,6:13-16
[104]Gibson.R.E.,R.L.Schiffman, K.W.Cargill. The theory of finite one-dimentionalconsolidation of saturated clays,Can. Geotech,1981,19(1)
[105]Zienkiewicz O C, Shiomi T. Dynamic behaviour of satureatied porous media:thegeneralized Biot foumulation and its numerical solution,Int.J Num. and AnalysisMech. in Geomech.1984,8:71-96
[106]Savage W Z,Braddock W A,A model for hydorstaitc consolidation fo Pierreshale,Int. J. Rock Mech. Min. Sci and Geomech,Absrt,1991,28:345-354
[107]Swenson D V,et al. A coupled model of fluid flow in jointed rock applied tosimulation of a hot dry rock reservoir [J].Int. J. Rock Mech Min Sci1997,34.
[108] Pao WKS, Lewis RW, Masters I. A fully coupled hydrothermo-poro-mechanicalmodel for black oil reservoir simulation,International Journal for Numerical andAnalytical Methods in Geomechanics,2001,25(12):1229-1256.
[109]Lewis R W,Finite element modeling of two-phase heat and fluid flow indeforming porous media[J]. Trans Porous Media,1989,4:319~334.
[110]Koutsabeloulis N C, Hope S A. Coupled stress fluid thermal multiphasereservoir simulation studies incorporating rock mechanics [A].Proceedings ofSPE/ISRM EUROCK-98Symposium [C].Norway1998,449.
[111] A Pak, D H Chan,A fully implicit single phase T-H-M fracture model formodeling hydraulic fracturing in oil sands[J], Journal of Canadian PetroleumTechnology,2004,43(6):35-44
[112]王自明,杜志敏,弹性油藏中多相渗流的流-固-热耦合数学模型[J],大庆石油地质与开发,2003,22(1):29-31.
[113]孔祥言,李道伦,徐献芝,热-流-固耦合渗流的数学模型研究[J],水动力学研究与进展,2005,20(2):269-275.
[114]盛金昌,廖秋林,刘继山,速宝玉.基于FEMLAB的钻井过程中流固热耦合响应分析[J],工程力学,2008,25(2):219-223
[115] http://www.ansys.com.cn
[116] http://www.adina.com.cn
[117] http://www.abaqus.com.cn
[118] http://www.mscsoftware.com
[119] http://www.physica.com
[120] http://www.cntech.com.cn
[121] http://www.flormerics.com
[122] http://www.algor.com
[123] http://www.spectrum.com
[124]陈慧远,摩擦接触单元及其分析方法[J],水利学报,1985(4):44-49.
[125]杜成斌、任青文,用于接触面模拟的三维非线性接触单元[J],东南大学学报(自然科学版),2001.7,Vol.31No.4.
[126]邵炜,金峰,王光纶,用于接触面模拟的非线性薄层单元[J],清华大学学报(自然科学版),1999,VOI.39No.2.
[127]王勖成,邵敏,有限单元法基本原理和数值方法[J],北京:清华大学出,1997:1-2
[128]赵光恒,张子明,地基模型和基础梁板分析[J],河海大学科技情报,1990,10(2):18-22
[129]苏超,姜弘道,弹恩会,基于粘弹性基础梁计算的地基参数反分析方法及其应用[J],岩土工程学报,2000,,22(2):186-189
[130]袁勇,混凝土早期裂缝裂缝控制[M],北京:科学出版社,2004.4
[131]王铁梦,工程结构裂缝控制[M],北京:中国建筑工业出版社,1997
[132]曹周红,刘晓平,温度应力对坞式船闸底板开裂影响分析[J],水运工程,2006,(5):70-73
[133]傅作新,彭宣茂,基底剪力对基础梁反力和内力的影响[J],河海大学学报,1993,21(2):78-82
[134]王振喜,弹性地基梁设计中边载影响及参数选择,水运工程,1990,(4):7-11.
[135]河海大学水港系港工教研室,泗阳复线船闸原模试验报告[R],河海大学水港系港工教研室,1988
[136]傅作新,张子明,大型船闸底板分缝施工方案的研究[J],土木工程学报,1992,25(1):45-51
[137]刘晓平,曹周红,不同地基坞式船闸结构底板预留宽缝施工方法效果分析[J],水力发电学报,2007,26(3):54-58
[138]蒋国盛,基坑工程[M],合肥:中国地质大学出版社,2000
[139] James M. Duncan,G. Wayne Clough,Finite element analyses of Port Allenlock,Journal of the Soil Mechanics and Foundations Division,1971,97(8):1053-1068
[140]洪承礼,深埋基础的接触应力[J],大连工学院学刊,1957:83-95
[141]《三峡水利枢纽混凝土工程温度控制研究》编辑委员会,三峡水利枢纽混凝土工程温度控制研究[M],北京:中国水利水电出版社,2001
[142]长沙理工大学,长沙综合枢纽复杂地基多线船闸有限元计算分析[R],长沙理工大学,2011
[143]惠容炎,黄国兴,易冰若,混凝土的徐变[M],北京:中国铁道出版社,1988
[144]A.M.Neville, W.H.Dilger,J.J.Brooks,Creep of plain and structural Concrete,Construction Press. London and New York,1983
[145]龚召熊,水工混凝土的温控与防裂[M],北京:中国水利水电出版社,1999
[146]王雍,三峡工程永久船闸输水洞衬砌混凝土温控研究:[硕士学位论文].武汉:武汉大学,2001,26-33
[147]朱伯芳,混凝土绝热温升的新计算模型与反分析[J],水力发电,2003,29(4):29-32
[148]张子明,宋智通,黄海燕,混凝土绝热温升和热传导方程的新理论[J],河海大学学报,2002,30(3):1-6
[149]李东,潘育耕,混凝土水化热瞬态温度场数值计算过程中的水化放热规律及水化速率问题[J],西安建筑科技大学学报,1999,31(3):277-279
[150]中国水电顾问集团中南勘测设计研究院,湘江长沙综合枢纽工程船闸大体积混凝土温度监测成果报告[R],中国水电顾问集团中南勘测设计研究院,2011
[151]李云,胡亚安,宣国详,通航船闸水力学研究进展[J],水动力学研究与进展,1999,14(2):232-239
[152]长沙理工大学,中低水头船闸平板输水阀门下层支承梁破坏机理及其改善措施研究[R],长沙理工大学,2008
[153]李世琴,吴一红,谢省宗,五强溪水电站高水头船闸输水系统动水压力与反向弧门流激振动[J],水利学报,1998,(12):28-33
[154]谢省宗,李世琴,陈文学,三峡永久船闸输水反向弧门流激振动问题研究[J],中国水利水电科学研究院学报,2003,1(1):36-44
[155]阎诗武,船闸阀门振动研究的发展与成就[J],振动、测试与诊断,1998,18(1):16-22,71
[156]水利部国际合作与科技司,当代水利科技前沿[M],北京:中国水利水电出版社,2006
[157]杨敏,练继建,林继镛,水流诱发平板闸门垂向振动的分析与计算[J],应用基础与工程科学学报,1995,3(3):283-288
[158]杨敏,练继建,林继镛,水流诱发平板闸门振动的激励机理[J],水动力学研究与进展。1997,12(4):437-449
[159]练继建,彭新民,崔广涛,水工闸门振动稳定性研究[J],天津大学学报,1999,32(2):171-176
[160]陈吉蓉,葛洲坝船闸输水阀门门楣补气方案与实施[J],武汉水利电力大学学报,1997,19(1):12-16
[161]周华兴,船闸通航水力学研究[M],哈尔滨:东北林业大学出版社,2007
[2]胡文利,李虎章,三峡五级船闸混凝土温度控制措施效果分析,武汉大学学报(工学版)[J],2003,36(5):30-34
[109]叶国华,港工混凝土结构物的温度应力和温度裂缝的研究,水运工程[J],1996,(8):16-26
[3]李晓凌,汪泓,樊口大闸裂缝处理方案研究,水利水电快报[J],2002,23(14):22-24
[4]郑立平,刘俊义,樊口大闸加固工程主要技术措施研究,人民长江[J],2005,36(4):15-16,65
[5]魏涛,蔡胜华,新城船闸下闸首裂缝处理,长江科学院院报[J],2000,17(6):56-57,63
[6]段仲源,石建军,宋会莲等.化学灌浆在船闸裂缝动水封堵中的应用,南华大学学报(理工版)[J],2004,(1):25-27
[7]张彦民,陈峰,董小卓,薄壁混凝土结构裂缝成因分析及防止措施,湖北水力发电[J],2009,(2):16-19
[8]赵全江,陈立军,薄壁结构砼的裂缝与处理,海岸工程[J],2004,23(3):34-41
[116]朱平,王海滨,刘宏新,船闸工程闸室侧墙裂缝分析与处理,水运工程[J],2006,(8):116-119
[9]王昆,船闸混凝土底板裂缝化学灌浆补强处理技术,水运工程[J],2009,(8):146-149
[10]金国强,孙维萍,陈学国,船闸混凝土裂缝机理与控制措施研究,浙江交通科技[J],2006,(4):57-59
[11]辛彦青,李振声,船闸混凝土温度裂缝的经验教训,水运工程[J],2002,(8):78-80,85
[12]陆娟,船闸廊道裂缝预防初探——以京杭运河淮阴三线船闸工程为例,交通标准化[J],2008,(3):175-177
[13]汤凯,陶华,船闸裂缝发生的机理及其防治,徐州建筑职业技术学院学报[J],2006,6(3):23-26
[14]汪国勤,船闸闸首闸室墙面损坏修理技术,水运工程[J],1993,(1):34-36
[15]聂霞,京杭运河谏壁二线船闸闸室墙防裂技术试验研究,中国港湾建设[J],2002,(2):19-23
[16]陆四雄,张廷辉,刘老涧三线船闸上闸首裂缝研究,水利科技与经济[J],2007,13(12):942-945
[17]鲍颖杰,新坝船闸输水廊道混凝土裂缝防治措施,水运工程[J],2007,(7):85-88
[18]高修,颍上船闸闸室边墙裂缝分析,治淮[J],2008,(10):21
[19]方朝阳,段亚辉,三峡永久船闸输水洞衬砌施工期温度与应力监测成果分析,人民长江[J],2004,35(7):13-14
[20]林金良,陈合爱,两种修补材料处理三峡船闸混凝土缺陷的实践,人民长江[J],2006,37(5):34-35
[21]张秋光,场论[M],北京:地质出版社,1988年
[22]卢焕忠,场论及其应用[M],北京:地质出版社,1981年
[23]宋少云,多场耦合问题的分类及其应用研究,武汉工业学院学报[J],2008,27(3):46-49
[24]Felippa C A, Park K C, Farhat C. Partitioned analysis of coupled mechanicalsystems[J].Computer Methods in Applied Mechanics and Engineering.2001,190(24-25):3247-3270
[25]宋少云,多场耦合问题的协同求解方法研究与应用:[博士学位论文],武汉;华中科技大学,2007
[26]朱伯芳,王同生,丁宝瑛,郭之章水工混凝土结构的温度应力与温度控制[M],北京水利电力出版社,1976
[27] Wilson E L. The determination of temperatures within mass concrete structures(SESM Report No.68-17),Structures and Materials Research. Department of CivilEngineering, University of California,Berkeley,Dec.1968
[28]Tatro Stephen B,Schrader Ernest K. Thermal considerations for roller-compactedconcrete,ACI Journal,March~Aprial,1988
[29]P.R Barrett, H Foadian, R.J. James, Y.R. Rashid.Thermal–structural analysismethods for RCC dams.Roller compacted concrete III, ASCE, New York (1992), pp.407–422
[30]Barrett P K,et al. Thermal structure analysis methods for RCC dams,Proceedingof conference of roller compacted concrete Ⅲ,Sam Diedo,California,1992:389-406
[31]Tohru Kawaguchi,Sunao Nakane,Investigations on determining thermal stress inmassive concrete structures,ACI. Vol93,1996(1):96-101
[32]Kim Jang-Ho Jay, Jeon, Sang-Eun, Kim. Development of new device formeausuring thermal stress,Cement and Concrete Research,2002,32(10):1651-1654
[33] Zhu Bofang. Computation of thermal stresses in mass concrete withconsideration of creep effect[c].Fifteenth International Congress on LargeDams,Lausanne,Suisse,June,1985:24-28
[34]朱伯芳,多层混凝土结构仿真分析的并层算法,水力发电学报[J],1994,(3):21-30
[35]朱伯芳,许平,混凝土坝仿真计算的并层算法和分区异步长算法[J],水力发电,1996,(1):38-43
[36]朱伯芳,不稳定温度场数值分析的时间域分区异步长算法[J],水利学报,1995,(8):40-52
[37]朱伯芳,弹性徐变体的分区异步长算法[J],水利学报,1995,(7):23-27
[38]朱伯芳,RCC坝仿真计算非均匀单元的初始条件[J],水力发电学报,2000,68(3):81-85
[39]Li Shouyi,Chen Yaolong,Zhang Xiaofei,et al. Study on contraction joints for theLongtan RCC gravity[J].Dam Engineering,2004,93(4):295-301
[40]何劲,陈尧隆,李守义,寒潮引起的碾压混凝土坝温度应力计算[J],西安理工大学学报,1999,15(4):91-94
[41]Yaolong Chen,Changjiang Wang,Shouyi Li,Simulation analysis of thermalstress of RCC dams using3-D finite element relocating mesh method,Advances inEngineering Software,2001,32(9):677-680
[42]张晓飞,大体积混凝土结构温度场和应力场仿真计算研究:[硕士学位论文],西安:西安理工大学,2009
[43]王建红,陆述远,魏锦萍,RCCD温度应力分析的非均质单元方法[J],力学与实践,1995,17(3):41-44
[44]李克亮,方憬,洪晓林,用并层非均质单元法分析碾压混凝土拱坝的温度应力[J],水利水运工程学报,2001,(3):41-47
[45]刘西军,大体积混凝土温度场温度应力仿真分析:[博士学位论文],杭州:浙江大学,2005
[46]黄达海,殷福新,宋玉普,碾压混凝土坝温度场仿真分析的波函数法[J],大连理工大学学报,2001,(3):214-217
[47]高政国,黄达海等,沙牌碾压混凝土拱坝温度场仿真计算[J],大连理工大学学报,2001,41(1):116-122
[48]黄达海,高政国,沙牌碾压混凝土拱坝损伤开裂分析[J],大连理工大学学报,2001,41(2):244-248
[49]刘光廷,麦家煊,张国新,溪柄碾压混凝土薄拱坝的研究[J],水力发电学报,1997,57(2):19-28
[50]陈里红,傅作新,大体积混凝土结构施工期软化开裂分析[J],水利学报,1992,(3):70-74
[51]侯朝胜,赵代深,混凝土坝温控三维仿真敏感分析及其凝聚方程[J],天津大学学报,2001,34(5):605-610
[52]赵代深,混凝土坝温控因素敏感分析及其在多维空间的凝聚方程[J],水利水电技术,2001,32(11):14-19
[53]刘有志,水工混凝土温控和湿控防裂方法研究:[博士学位论文],南京:河海大学,2006
[54]邢景棠,周盛,崔尔杰,流固耦合力学概述[J],力学进展,1997,27(1):19-38
[55]L anchester FW,To rsional vibration of the tail of an airp lane. A RC R. and M.276, part1(1916)
[56]Bairstow L,Fage A. O scillations of the tailp lane and body of an aerop lane infligh t. A RC R. and M.276, part2(1916). In:Technical Repo rt of the A dviso ryComm ittee fo r A erodynam ics, fo r the year1916-1917. II, H isM ajesty’s StationaryOffice, London (1920):461-467
[57]Theodo rsen T. General theory of aerodynam ic instability and themechanism offlutter,N A CA T R496(1934). In:Twen2tieth A nnaul Repo rt of theN ationalAdviso ry Comm ittee fo rA erodynam ics1934, U S Government P rinting Office, Wash2ington (1935):413-433
[58]居荣初,曾心传,弹性结构与液体的耦联振动理论[M],北京:地震出版社,1983
[59]Westergaard H M. Water pressures on dams during earthquakes. Trans Amer. SocCiv. Eng.,98(1933):418-433
[60]Chopra A K,Earthquake Response of Concrete Gravity Dams,AD709640,California University, Berkeley,1970
[61]居荣初,黄振平,杜瑞明,水中圆柱体结构的自由振动[M],地震工程研究报告集,第一集,科学出版社,北京,1962,
[62]王前信,王考信.伸臂梁在一侧有水时的自振特性与地震荷载[M].地震工程研究报告集,第一集,科学出版社,北京,1962
[63]郑哲敏,马宗魁,悬臂梁在一侧受有液体时的自由振动[J],力学学报,3,2(1959):111-119
[64]李遇春,朱暾,白冰,悬臂梁-流体-悬臂梁耦联系统的湿模态相互作用[J],工程力学,1998,15(1):58-65
[65]王建伟,徐晖,马宁,开放式内嵌流体柔性悬臂梁振颤失稳分析[J],应用力学学报,2010,27(2):259-264
[66]黄志祥,徐晖,徐立勤,内嵌黏性流体欧拉梁的自适应减振模式研究[J],西安交通大学学报,2006,40(9):1009-1103
[67]刘志宏,黄玉盈,Chater梁屈曲传播的动态分析[J],力学学报,1993,25(4):460-467
[68]王建伟,徐晖,马宁,主共振激励下内嵌流体悬臂欧拉梁自适应减振性能研究[J],振动与冲击,2011,30(8):41-44
[69]鲁丽,杨翊仁,无粘流中非线性板梁结构的分叉[J],西南交通大学学报,2004,39(5):641-644
[70]赵文胜,轴向流中板结构流固耦合动力学研究:[博士学位论文],武汉:武汉大学,2011
[71]张杰,流固耦合平板绕流的格子波尔兹曼数值研究:[博士学位论文],合肥:中国科学技术大学,2009
[72]鲁丽,非线性板状结构流固耦合复杂响应研究:[博士学位论文],成都:西南交通大学,2006
[73]王刚,深海采矿作业过程扬矿管线系统空间构形与动态特性研究:[博士学位论文],长沙:中南大学,2008
[74]李小超海底管线悬跨段涡激振动响应的实验研究与数值预报:[博士学位论文],大连:大连理工大学,2011
[75]刘正刚,基于流固耦合的小型旋翼式机械内部水流特性的研究:[博士学位论文],济南:山东大学,2008
[76]郝双户,深水重力式网箱浮架的流固耦合研究:[博士学位论文],大连:大连理工大学,2008
[77]雷凡,水下柔性结构流固耦合动力效应研究:[博士学位论文],武汉:武汉理工大学,2011
[78]徐梦华,大型渡槽梁壳流固耦合动力模型及其工程应用研究:[博士学位论文],广州:华南理工大学,2009
[79]王文全,薄壁结构流固耦合数值模拟及计算方法研究:[博士学位论文],昆明:昆明理工大学,2008
[80]刘建军,地下水渗流的流-固耦合理论及数值方法[J],勘察科学技术,2000,(4):7-10
[81]Hiroshi Y, Hurofuni N. Consolidation of soils by vertical drain well with finitepermeability,Soil and Foundation,1974,6:35-46
[82]刘广生,赵维炳,朱国忠,固结、渗流和沉积控制方程研究[J],南京水利科学研究院,水利水运科技研究,1999,2:207-212
[83]陶震宇,沈小莹,库区应力场的耦合分析[J],武汉水利电力学院学报,1988,(1):8-14
[84]罗晓辉,深基坑开挖渗流与应力耦合分析[J],工程勘察,1996,(6):37-41
[85]陈平,张有天,裂隙岩体渗流与应力耦合分析[J],岩石力学与工程学报,1994,13(4):209-308
[86]李尧臣,陈洁,周顺华,铁路路基施工的渗流——应力耦合模型分析[J],岩土工程学报,2004,26(4):565-568
[87]李术才,李树忱等,泰安抽水蓄能电站围堰稳定性的流——固耦合分析[J],岩石力学与工程学报,2004,23(8):1275-1279
[88]章梦涛,潘一山等,煤岩流体力学[M],北京:北京科学出版社,1995
[89]赵阳升,矿山岩石流体力学[M],北京:煤炭工业出版社,1995
[90]汪有刚,刘建军等,煤与瓦斯流——固耦合渗流的数值模拟[J],煤炭学报,2001,2,6(3):285-289
[91]赵国景,丁继辉,煤与瓦斯突出的固─流两相介质力学理论及数值分析[J],工程力学,1995,12(2):1-7
[92]丁继辉,李凤莲等,有限变形下煤与瓦斯突出的固流两相介质耦合失稳理论[J],工程力学,2008,(25):33-37
[93]丁继辉,麻玉鹏等,煤与瓦斯突出的固一流耦合失稳理论及数值分析[J],水利水电技术,2004,35(11):18-21
[94]王自明,油藏热流一固耦合模型研究及应用初探:[博士学位论文],南充:西南石油学院博士学位论文,
[95]刘建军,裂缝性低渗透油藏流-固耦合理论与数值模型[J],力学学报,2003:614
[96] Jian Jun,Liu etc. Theoretical and experimental studies on the fluid-solid couplingprocess for oil recovery from low permeability fractured International Journal of RockMechanics and Mining science,2004
[97]袁弈群,黑油模型在油田开发中的应用[M],北京:石油工业出版社,1995
[98]赵颖,填埋场渗滤液污染物释放传输的耦合动力学模型及应用研究:[博士学位论文],阜新:辽宁工程技术大学,2008
[99]薛新华,岩土介质流-固耦合非线性损伤力学理论与数值分析:[博士学位论文],杭州:浙江大学,2008
[100]Terzaghi K. Theoretical Soil Mechanics,New York:Tiho Wiley,1943
[101]Biot M A. Theory of elasticity and consolidation for a porous anisotropic solie,Jour Appl Phys,1954,26:182-191
[102]Lubinski A. Theory of elasticity of porous dodies displaying a strong porestructure, Proc.U.S.National Congress of Applied Mechanics,1954,247-256
[103]Geertsman J. A remark on the analogy between thermo-elasticity and theelasticity of saturated porous medial,J.Mech.Phys.Solids,1957,6:13-16
[104]Gibson.R.E.,R.L.Schiffman, K.W.Cargill. The theory of finite one-dimentionalconsolidation of saturated clays,Can. Geotech,1981,19(1)
[105]Zienkiewicz O C, Shiomi T. Dynamic behaviour of satureatied porous media:thegeneralized Biot foumulation and its numerical solution,Int.J Num. and AnalysisMech. in Geomech.1984,8:71-96
[106]Savage W Z,Braddock W A,A model for hydorstaitc consolidation fo Pierreshale,Int. J. Rock Mech. Min. Sci and Geomech,Absrt,1991,28:345-354
[107]Swenson D V,et al. A coupled model of fluid flow in jointed rock applied tosimulation of a hot dry rock reservoir [J].Int. J. Rock Mech Min Sci1997,34.
[108] Pao WKS, Lewis RW, Masters I. A fully coupled hydrothermo-poro-mechanicalmodel for black oil reservoir simulation,International Journal for Numerical andAnalytical Methods in Geomechanics,2001,25(12):1229-1256.
[109]Lewis R W,Finite element modeling of two-phase heat and fluid flow indeforming porous media[J]. Trans Porous Media,1989,4:319~334.
[110]Koutsabeloulis N C, Hope S A. Coupled stress fluid thermal multiphasereservoir simulation studies incorporating rock mechanics [A].Proceedings ofSPE/ISRM EUROCK-98Symposium [C].Norway1998,449.
[111] A Pak, D H Chan,A fully implicit single phase T-H-M fracture model formodeling hydraulic fracturing in oil sands[J], Journal of Canadian PetroleumTechnology,2004,43(6):35-44
[112]王自明,杜志敏,弹性油藏中多相渗流的流-固-热耦合数学模型[J],大庆石油地质与开发,2003,22(1):29-31.
[113]孔祥言,李道伦,徐献芝,热-流-固耦合渗流的数学模型研究[J],水动力学研究与进展,2005,20(2):269-275.
[114]盛金昌,廖秋林,刘继山,速宝玉.基于FEMLAB的钻井过程中流固热耦合响应分析[J],工程力学,2008,25(2):219-223
[115] http://www.ansys.com.cn
[116] http://www.adina.com.cn
[117] http://www.abaqus.com.cn
[118] http://www.mscsoftware.com
[119] http://www.physica.com
[120] http://www.cntech.com.cn
[121] http://www.flormerics.com
[122] http://www.algor.com
[123] http://www.spectrum.com
[124]陈慧远,摩擦接触单元及其分析方法[J],水利学报,1985(4):44-49.
[125]杜成斌、任青文,用于接触面模拟的三维非线性接触单元[J],东南大学学报(自然科学版),2001.7,Vol.31No.4.
[126]邵炜,金峰,王光纶,用于接触面模拟的非线性薄层单元[J],清华大学学报(自然科学版),1999,VOI.39No.2.
[127]王勖成,邵敏,有限单元法基本原理和数值方法[J],北京:清华大学出,1997:1-2
[128]赵光恒,张子明,地基模型和基础梁板分析[J],河海大学科技情报,1990,10(2):18-22
[129]苏超,姜弘道,弹恩会,基于粘弹性基础梁计算的地基参数反分析方法及其应用[J],岩土工程学报,2000,,22(2):186-189
[130]袁勇,混凝土早期裂缝裂缝控制[M],北京:科学出版社,2004.4
[131]王铁梦,工程结构裂缝控制[M],北京:中国建筑工业出版社,1997
[132]曹周红,刘晓平,温度应力对坞式船闸底板开裂影响分析[J],水运工程,2006,(5):70-73
[133]傅作新,彭宣茂,基底剪力对基础梁反力和内力的影响[J],河海大学学报,1993,21(2):78-82
[134]王振喜,弹性地基梁设计中边载影响及参数选择,水运工程,1990,(4):7-11.
[135]河海大学水港系港工教研室,泗阳复线船闸原模试验报告[R],河海大学水港系港工教研室,1988
[136]傅作新,张子明,大型船闸底板分缝施工方案的研究[J],土木工程学报,1992,25(1):45-51
[137]刘晓平,曹周红,不同地基坞式船闸结构底板预留宽缝施工方法效果分析[J],水力发电学报,2007,26(3):54-58
[138]蒋国盛,基坑工程[M],合肥:中国地质大学出版社,2000
[139] James M. Duncan,G. Wayne Clough,Finite element analyses of Port Allenlock,Journal of the Soil Mechanics and Foundations Division,1971,97(8):1053-1068
[140]洪承礼,深埋基础的接触应力[J],大连工学院学刊,1957:83-95
[141]《三峡水利枢纽混凝土工程温度控制研究》编辑委员会,三峡水利枢纽混凝土工程温度控制研究[M],北京:中国水利水电出版社,2001
[142]长沙理工大学,长沙综合枢纽复杂地基多线船闸有限元计算分析[R],长沙理工大学,2011
[143]惠容炎,黄国兴,易冰若,混凝土的徐变[M],北京:中国铁道出版社,1988
[144]A.M.Neville, W.H.Dilger,J.J.Brooks,Creep of plain and structural Concrete,Construction Press. London and New York,1983
[145]龚召熊,水工混凝土的温控与防裂[M],北京:中国水利水电出版社,1999
[146]王雍,三峡工程永久船闸输水洞衬砌混凝土温控研究:[硕士学位论文].武汉:武汉大学,2001,26-33
[147]朱伯芳,混凝土绝热温升的新计算模型与反分析[J],水力发电,2003,29(4):29-32
[148]张子明,宋智通,黄海燕,混凝土绝热温升和热传导方程的新理论[J],河海大学学报,2002,30(3):1-6
[149]李东,潘育耕,混凝土水化热瞬态温度场数值计算过程中的水化放热规律及水化速率问题[J],西安建筑科技大学学报,1999,31(3):277-279
[150]中国水电顾问集团中南勘测设计研究院,湘江长沙综合枢纽工程船闸大体积混凝土温度监测成果报告[R],中国水电顾问集团中南勘测设计研究院,2011
[151]李云,胡亚安,宣国详,通航船闸水力学研究进展[J],水动力学研究与进展,1999,14(2):232-239
[152]长沙理工大学,中低水头船闸平板输水阀门下层支承梁破坏机理及其改善措施研究[R],长沙理工大学,2008
[153]李世琴,吴一红,谢省宗,五强溪水电站高水头船闸输水系统动水压力与反向弧门流激振动[J],水利学报,1998,(12):28-33
[154]谢省宗,李世琴,陈文学,三峡永久船闸输水反向弧门流激振动问题研究[J],中国水利水电科学研究院学报,2003,1(1):36-44
[155]阎诗武,船闸阀门振动研究的发展与成就[J],振动、测试与诊断,1998,18(1):16-22,71
[156]水利部国际合作与科技司,当代水利科技前沿[M],北京:中国水利水电出版社,2006
[157]杨敏,练继建,林继镛,水流诱发平板闸门垂向振动的分析与计算[J],应用基础与工程科学学报,1995,3(3):283-288
[158]杨敏,练继建,林继镛,水流诱发平板闸门振动的激励机理[J],水动力学研究与进展。1997,12(4):437-449
[159]练继建,彭新民,崔广涛,水工闸门振动稳定性研究[J],天津大学学报,1999,32(2):171-176
[160]陈吉蓉,葛洲坝船闸输水阀门门楣补气方案与实施[J],武汉水利电力大学学报,1997,19(1):12-16
[161]周华兴,船闸通航水力学研究[M],哈尔滨:东北林业大学出版社,2007
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |