攀西地区昔格达土工程力学特性试验研究
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摘要
昔格达土广泛分布于四川攀枝花、西昌地区。由于昔格达土遇水易软化、泥化,因此常形成众多的滑坡,且攀西地区沿安宁河一带都处于大断裂带,因此有必要对昔格达土的工程力学特性进行试验研究。
通过测定,分析了昔格达土的物理化学成分,并通过常规试验得出了昔格达土的一系列常规参数。
在回顾前人研究成果的基础上,使用微机控制电磁式动三轴仪,对昔格达土进行了大量的动强度液化和动模量阻尼试验,确定了昔格达土的动强度和动力参数,并对其影响因素做了一定的探讨。
影响土体抗液化特性的主要因素有:土性条件、起始应力条件、动荷条件等。本文主要考察了固结围压力、控制干密度、饱和度对昔格达土抗液化特性的影响。动剪应力τ_d随固结围压力σ_(3c)增大而增大。动应力比R_o随控制干密度的增大而增大,随饱和度的增大而减小。
动模量阻尼比的影响因素有10多个。动应变水平影响动模量阻尼成倍增减;固结围压力对动模量阻尼比的影响也非常大,动模量随着固结围压力的增大而增大,阻尼比随固结围压力的增大而减小;动模量随着控制干密度和饱和度的增减而增减,阻尼比随着控制干密度和饱和度的增大而略有减小。
Xigeda soil widely exists in Panzhihua-Xichang area of Sichuan province. Because it often forms numerous landslides for it's apt to intenerate and become mud when meeting water and there is a big rupture alone Anning river in Panzhihua-Xichang area, we should investigate it's characteristic in engineering and dynamic through experiment.
On the base of pre-production, tests of dynamic modulus ,damping ratio and dynamic intensity of Xigeda soil through the cyclic triaxial instrument. Dynamic intensity and seismic parameters are ensured and some affecting factors are discussed.
Among many factors affecting the resisting fluidify characteristic of the soil., soil character, initial stress and dynamic load are the primary. Mainly seeing about the factors affecting the resisting fluidify characteristic such as confining stress, controlling dry density and saturation in this paper. Cyclic stress" τ d" increases while confining stress" σ3c" increasing. Cyclic stress ratio"R@" increase while controlling dry density increasing and decreases while saturation increasing
More than 10 factors affect the dynamic modulus and damping ratio Dynamic strain level can make dynamic modulus and damping ratio multiple. Confining stress has much effect on dynamic modulus and damping ratio. Dynamic modulus increases while confining stress increasing and damping ratio decreases while confining stress increasing. Dynamic modulus increases while controlling dry density or saturation increasing and damping ratio decreases little while controlling dry density or saturation increasing.
通过测定,分析了昔格达土的物理化学成分,并通过常规试验得出了昔格达土的一系列常规参数。
在回顾前人研究成果的基础上,使用微机控制电磁式动三轴仪,对昔格达土进行了大量的动强度液化和动模量阻尼试验,确定了昔格达土的动强度和动力参数,并对其影响因素做了一定的探讨。
影响土体抗液化特性的主要因素有:土性条件、起始应力条件、动荷条件等。本文主要考察了固结围压力、控制干密度、饱和度对昔格达土抗液化特性的影响。动剪应力τ_d随固结围压力σ_(3c)增大而增大。动应力比R_o随控制干密度的增大而增大,随饱和度的增大而减小。
动模量阻尼比的影响因素有10多个。动应变水平影响动模量阻尼成倍增减;固结围压力对动模量阻尼比的影响也非常大,动模量随着固结围压力的增大而增大,阻尼比随固结围压力的增大而减小;动模量随着控制干密度和饱和度的增减而增减,阻尼比随着控制干密度和饱和度的增大而略有减小。
Xigeda soil widely exists in Panzhihua-Xichang area of Sichuan province. Because it often forms numerous landslides for it's apt to intenerate and become mud when meeting water and there is a big rupture alone Anning river in Panzhihua-Xichang area, we should investigate it's characteristic in engineering and dynamic through experiment.
On the base of pre-production, tests of dynamic modulus ,damping ratio and dynamic intensity of Xigeda soil through the cyclic triaxial instrument. Dynamic intensity and seismic parameters are ensured and some affecting factors are discussed.
Among many factors affecting the resisting fluidify characteristic of the soil., soil character, initial stress and dynamic load are the primary. Mainly seeing about the factors affecting the resisting fluidify characteristic such as confining stress, controlling dry density and saturation in this paper. Cyclic stress" τ d" increases while confining stress" σ3c" increasing. Cyclic stress ratio"R@" increase while controlling dry density increasing and decreases while saturation increasing
More than 10 factors affect the dynamic modulus and damping ratio Dynamic strain level can make dynamic modulus and damping ratio multiple. Confining stress has much effect on dynamic modulus and damping ratio. Dynamic modulus increases while confining stress increasing and damping ratio decreases while confining stress increasing. Dynamic modulus increases while controlling dry density or saturation increasing and damping ratio decreases little while controlling dry density or saturation increasing.
引文
[1] 赵剑明、汪闻韶.关于水利工程震害及抗震研究的及点思考,清华大学学报(自然科学版),2000年第40卷第S1期.
[2] 谢定义.21世纪土力学的思考.岩士工程学报,1997年7月,第19卷第4期.
[3] 尼汗根、金崇磐.大坝抗震特性与抗震计算,大连理工大学出版社,1994年12月.
[4] 王杰贤主编.动力地基与基础,科学出版社,2001年.
[5] 巫志辉,谢定义,余雄飞.洛川黄土的动变形和强度特性.水利学报,1994年12月,第12期:67~71.
[6] 王兰民等.饱和黄土液化机理与特性的试验研究.岩土工程学报,2000年1月,第22卷第1期:89~94.
[7] 雷胜友,李克钏.膨胀土动力性质的研究.成都科技大学学报,1995年第3期:20~24.
[8] 徐学燕,仲从利.冻土的动力特性研究及其参数确定.岩土工程学报,1998年9月,第20卷第5期:77~81.
[9] 王余庆,辛鸿博.中国尾矿坝地震安全度(10)—用动单剪仪研究大石河尾矿砂的动特性.工业建筑,1995年第25卷第3期:37~40.
[10] 周健,白冰.粉煤灰作为筑坝排水垫层的动力特性试验研究.勘查科学技术,2000年第5期:7~11.
[11] 周健,董鹏,戚佩江.灰渣坝抗震稳定性的三维有效应力动力分析.水利学报,2000年7月,第7期:44~48.
[12] 简连贵,张上君,胡渊男.初始剪应力对海外回填土壤动态特性之影响.岩土工程学报,1999年7月,第21卷第4期:420~426.
[13] 周健等.垃圾土室内动力试验研究.岩土力学,1999年12月,第20卷第4期:1~5.
[14] 牛建新,汪闻韶.循环扭剪试验中饱和砂土的某些动力特性.水利学报,1994年5月,第5期:77~83.
[15] 王洪瑾等.土在复杂应力状态下的动力特性研究.水利学报,1996年4月,第4期:57~64.
[16] 常亚萍等.高土石坝坝料及地基土动力工程性质研究报告.中国水利水
电科学研究院,1995年4月,北京.
[17] 杨桂芳.静力本构模型试验、参数确定及参数对计算结果的影响分析.四川大学硕士学位论文,1999年5月.
[18] Goto, S. and Tatsuoka, F., etal. A simple gauge for local small strain measurements in the laboratory. Soil and Foundations, 1991, 31(1).
[19] 何昌荣等.高应力水平下堆石料垫层料或过渡料的动变形特性研究报告.四川联合大学水电学院,1994年10月,成都.
[20] 谢定义.土动力学,西安交通大学出版社,1988年9月.
[21] 吴世明等.土动力学.中国建筑工业出版社会,2000年12月.
[22] Bobby O. Hardin and Vincent P. Drnevich. Shear modulus and damping in soils: measurement and parameter effects. Journal of the Soil Mechanics and Foundations Division, ASCE, 1972, 98(SM6): 603~624.
[23] 吴世明,徐攸在.土动力学现状与发展.岩土工程学报,1998年5月,第20卷第3期:125~130.
[24] 彭盛恩.昔格达组粘土的工程地质特性研究,水文地质工程地质,1986年,第2期.
[25] 李小泉.栗子坪水电站厂基昔格达土的工程特性,广州水利水电,1996年,第1期.
[26] 水利部.土工试验规程,SL237—1999.
[27] 水电部.土工试验规程,SD128—84.
[28] Seed H B,I M.Simplified procedure for evaluation soil liquefaction potential. J Soil Mech Found Div, ASCE, 1971,97(SM7).
[29] 汪闻韶.土的动力强度和液化特性,中国电力出版社,1997年3月.
[30] The Committee on Soil Dynamics of Geotechnical Engineering Division, ASCE. Definition of terms related to liquefaction. Journal of Geotechnical Engineering Division, ASCE, 1979, 104(GTg): 1197~1200.
[31] Casagrande A. Charateristics of cohesionless soils affecting the stability of slopes and earthfills. Journal of the Boston Society of Civil Engineers, 1936, 23(1): 257~276.
[32] Casagrande A. Liquefaction and cyclic deformation of sands, a critical review.
Proc 5th Pan-American Conference on Soil Mechanics and Foundation Engineering, Buenos Aires, Argentina, 1975.
[33] Castro G. Liquefaction and cyclic mobility of saturated sands. Journal of Geotechnical Engineering Division, ASCE, 1975, 101(6): 551~569.
[34] Poulos S J, Castro G, France J W. Liquefaction evaluation procedure. Journal of Geotechnical Engineering Division, ASCE, 1985, 111(6): 772~791.
[35] Castro G, Seed R B, Keller T O, Seed H B. Steady-state strength analysis of Lower San Fernando dam slide. Journal of Geotechnical Engineering Division, ASCE, 1992, 118(3): 406~427.
[36] Ishihara K. Liquefaction and flow failure during earthquakes. Geotechnique, 1993, 43(3): 351~415.
[37] Bazier M H, Dobry R. Residual strength and large-deformation potential of loose silty sands. Journal of Geotechnical Engineering Division, ASCE, 1995, 121(12): 896~906.
[38] Lee, K. L. and Seed, H. B. Cyclic Stress Conditions Causing Liquefaction of Sand. Journal of the Soil Mechanics and Foundations Division, ASCE, 1967, 93(SM1): 47~70.
[39] 谢定义.饱和砂土体液化的若干问题.岩土工程学报,1992年5月,第14卷第3期:90~98.
[40] 张建红,何吕荣.往返荷载作用下非饱和砂性土的液化强度和孔压规律.成都科技大学学报,1994年第1期:1~8.
[41] Seed H B,Lee K L.Liquefaction of saturated sands during cyclic Ioading.J Soil Mech Found Div, A SCE, 1966,92(SM6): 105~134.
[42] Peacock W H,Seed H B. Sand liquefaction under cyclic loading simple shear conditions.J Soil Mech Found Div, ASCE,1968,94(SM3):689~708.
[43] DeAlba P, Seed H B,Chan C K. Sand liquefaction in large-scale simple shear tests.J Geotech Engng Div, ASCE,1976,102(GT9):909~927.
[44] Tokimatsu K,Yoshimi Y. Empirical correlation of soil liquefaction based n SPT N-value and fines content. Soils and Foundations, 1983,23(4): 56~74.
[45] Pillai V S, Byrne P M. Effect of overburden stress on liquefaction resistance of sand.Can Geotech J,1994,31:53~60.
[46] 刘小生等.吉林台水电站心墙堆石坝心墙土料动力特性试验研究报告.中国水利水电科学研究院抗震防护研究所,1994年10月.
[47] 胡元芳.粉煤灰筑坝的工程性质与稳定性分析.四川联合大学硕士学位论文,1995年5月.
[48] 何昌荣等.泥石流砾石土液化机理试验研究报告.四川大学水电学院,2001年9月.
[49] 余湘娟等.砂土的振动孔压增长模式与液化剪应力的试验研究.东南大学学报(自然科学版),2000年5月,第30卷第3A期:39~42.
[50] Seesd H B, Martin P P, Lysmer J. The generation and dissipation of pore water pressures during soil liquefaction. Report No EERC 75-26,Earthquake Engineering Research Center, University of California at Brekely, U S A. 1975.
[51] Finn W D L, Lee K W, Martin G R. An effective stress model for liquefaction. J Geotech Engng Div, ASCE, 1977, 103(GT6):517-533.
[52] 徐志英、沈珠江.地震液化的有效应力二维动力分析方法.华东水利学院学报,1981a,(3).
[53] Martin G R, Finn W D L, Seed H B. Undrained deformation of liquefaction of sand under cyclic stress.Soils and Foundations, 1975,15(1):423~438.
[54] Ishihara K, Yatsuoka, Yasuda S. Undrained deformation and liquefaction of sand under cyclic stress. Soils and Foundations, 1975, 15(1):29~44.
[55] Nasser S N, Shokooh A. A unified approach to densification and liquefaction of cohesionless sand in cyclic shearing. Can Geotch J, 1979,16:659~678.
[56] Davis R O, Berrill J B. Energy dissipation and seismic liquefaction in sands. Earthquake Engng Struct Dyn, 1982,(10).
[57] 曹亚林、何广讷、林皋.土中振动孔隙水压力增长程度的能量分析法.土木工程学报,1987。26(3).
[58] Finn W D L, Bhatia S K. Endochronic theory of sand liquefaction. In:Proc 7th World Conf on Earthquake Engng, Istanbul, Turkey, 1980.
[59] 谢定义、张建民.往返荷载下饱和砂土强度形变瞬态变化机理.土木工程学报,1987,20(3).
[60] 于濂洪,王波.饱和粉土振动孔隙水压力的试验研究.大连大学学报,1999
年8月,第20卷第4期:59~62.
[61] 孙明权,顾淦臣.堤坝边坡地震液化失稳有效应力法分析研究.水利学报,1994年4月,第4期:63~68.
[62] 许才军,周红波.不排水循环荷载作用下饱和软粘土的孔压增长模型.勘查科学技术,1998年第1期:3~7.
[63] 顾淦臣.论土石坝的地震液化验算和坝坡抗震稳定计算.岩土工程学报,1981年第4期.
[64] 孙明权,顾淦臣.土坝抗震的有效应力动力分析研究.人民黄河,1990年12月,第6期:18~24.
[65] 沈珠江.砂土动力变形计算参数的室内测定.水利水运科学研究,1984年第2期:10~17.
[66] 沈珠江.一个计算砂土液化变形的等价粘弹性模式.南京水利科学研究所,1983.
[67] Hardin B O, Black W L. Vibration modulus of normal consolidated clay. J Soil Mech Found Div, ASCE,1968,94(SM2).
[68] Whitman R V, Richart F E, Jr. Design procedures for dynamically loaded foundations.J Soil Mech Found Div, ASCE,1967a,93(SM6).
[69] Richart F E, Jr, Whitman R V. Comparison of footing vibration test with theory. J Soil Mech Found Div, ASCE, 1967b,83(SM6).
[70] Seed H B, Idriss l M. Soil moduli and damping factors for dynamic response analysis. Report No EERC 70-10, Earthquake Engineering Research Center, University of California Berkely, U S A, 1970.
[71] 何昌荣等.高应力水平下堆石料垫层料或过渡料的动变形特性研究报告.四川联合大学水电学院,1994年10月,成都.
[72] 何昌荣等。攀钢马家田尾矿坝尾矿土试验研究报告.四川大学水电学院,2000年2月,成都.
[73] 何昌荣.动模量何阻尼的动三轴试验研究.岩土工程学报,第19卷第2期,1997年3月:39~48.
[74] Bobby O. Hardin and Vincent P. Drnevich. Shear modulus and damping in soils: measurement and parameter effects. Journal of the Soil Mechanics and Foundations Divisions ASCE, 1972, 98(SM6): 603~624.
[75] 陈国兴等.土的动模量何阻尼比的经验估计.地震工程与振动,第15卷第1期,1995年3月:73~83.
[76] 牟崇元等.等幅循环荷载作用下土的动剪模和阻尼.华南地震,第11卷第2期,1991年6月:13~21.
[77] Vucetic M and R Dobry. Effect of soli Plasticity on Cyclic Response. ASCE. Vol.117.No. GT1,1991:89~107.
[2] 谢定义.21世纪土力学的思考.岩士工程学报,1997年7月,第19卷第4期.
[3] 尼汗根、金崇磐.大坝抗震特性与抗震计算,大连理工大学出版社,1994年12月.
[4] 王杰贤主编.动力地基与基础,科学出版社,2001年.
[5] 巫志辉,谢定义,余雄飞.洛川黄土的动变形和强度特性.水利学报,1994年12月,第12期:67~71.
[6] 王兰民等.饱和黄土液化机理与特性的试验研究.岩土工程学报,2000年1月,第22卷第1期:89~94.
[7] 雷胜友,李克钏.膨胀土动力性质的研究.成都科技大学学报,1995年第3期:20~24.
[8] 徐学燕,仲从利.冻土的动力特性研究及其参数确定.岩土工程学报,1998年9月,第20卷第5期:77~81.
[9] 王余庆,辛鸿博.中国尾矿坝地震安全度(10)—用动单剪仪研究大石河尾矿砂的动特性.工业建筑,1995年第25卷第3期:37~40.
[10] 周健,白冰.粉煤灰作为筑坝排水垫层的动力特性试验研究.勘查科学技术,2000年第5期:7~11.
[11] 周健,董鹏,戚佩江.灰渣坝抗震稳定性的三维有效应力动力分析.水利学报,2000年7月,第7期:44~48.
[12] 简连贵,张上君,胡渊男.初始剪应力对海外回填土壤动态特性之影响.岩土工程学报,1999年7月,第21卷第4期:420~426.
[13] 周健等.垃圾土室内动力试验研究.岩土力学,1999年12月,第20卷第4期:1~5.
[14] 牛建新,汪闻韶.循环扭剪试验中饱和砂土的某些动力特性.水利学报,1994年5月,第5期:77~83.
[15] 王洪瑾等.土在复杂应力状态下的动力特性研究.水利学报,1996年4月,第4期:57~64.
[16] 常亚萍等.高土石坝坝料及地基土动力工程性质研究报告.中国水利水
电科学研究院,1995年4月,北京.
[17] 杨桂芳.静力本构模型试验、参数确定及参数对计算结果的影响分析.四川大学硕士学位论文,1999年5月.
[18] Goto, S. and Tatsuoka, F., etal. A simple gauge for local small strain measurements in the laboratory. Soil and Foundations, 1991, 31(1).
[19] 何昌荣等.高应力水平下堆石料垫层料或过渡料的动变形特性研究报告.四川联合大学水电学院,1994年10月,成都.
[20] 谢定义.土动力学,西安交通大学出版社,1988年9月.
[21] 吴世明等.土动力学.中国建筑工业出版社会,2000年12月.
[22] Bobby O. Hardin and Vincent P. Drnevich. Shear modulus and damping in soils: measurement and parameter effects. Journal of the Soil Mechanics and Foundations Division, ASCE, 1972, 98(SM6): 603~624.
[23] 吴世明,徐攸在.土动力学现状与发展.岩土工程学报,1998年5月,第20卷第3期:125~130.
[24] 彭盛恩.昔格达组粘土的工程地质特性研究,水文地质工程地质,1986年,第2期.
[25] 李小泉.栗子坪水电站厂基昔格达土的工程特性,广州水利水电,1996年,第1期.
[26] 水利部.土工试验规程,SL237—1999.
[27] 水电部.土工试验规程,SD128—84.
[28] Seed H B,I M.Simplified procedure for evaluation soil liquefaction potential. J Soil Mech Found Div, ASCE, 1971,97(SM7).
[29] 汪闻韶.土的动力强度和液化特性,中国电力出版社,1997年3月.
[30] The Committee on Soil Dynamics of Geotechnical Engineering Division, ASCE. Definition of terms related to liquefaction. Journal of Geotechnical Engineering Division, ASCE, 1979, 104(GTg): 1197~1200.
[31] Casagrande A. Charateristics of cohesionless soils affecting the stability of slopes and earthfills. Journal of the Boston Society of Civil Engineers, 1936, 23(1): 257~276.
[32] Casagrande A. Liquefaction and cyclic deformation of sands, a critical review.
Proc 5th Pan-American Conference on Soil Mechanics and Foundation Engineering, Buenos Aires, Argentina, 1975.
[33] Castro G. Liquefaction and cyclic mobility of saturated sands. Journal of Geotechnical Engineering Division, ASCE, 1975, 101(6): 551~569.
[34] Poulos S J, Castro G, France J W. Liquefaction evaluation procedure. Journal of Geotechnical Engineering Division, ASCE, 1985, 111(6): 772~791.
[35] Castro G, Seed R B, Keller T O, Seed H B. Steady-state strength analysis of Lower San Fernando dam slide. Journal of Geotechnical Engineering Division, ASCE, 1992, 118(3): 406~427.
[36] Ishihara K. Liquefaction and flow failure during earthquakes. Geotechnique, 1993, 43(3): 351~415.
[37] Bazier M H, Dobry R. Residual strength and large-deformation potential of loose silty sands. Journal of Geotechnical Engineering Division, ASCE, 1995, 121(12): 896~906.
[38] Lee, K. L. and Seed, H. B. Cyclic Stress Conditions Causing Liquefaction of Sand. Journal of the Soil Mechanics and Foundations Division, ASCE, 1967, 93(SM1): 47~70.
[39] 谢定义.饱和砂土体液化的若干问题.岩土工程学报,1992年5月,第14卷第3期:90~98.
[40] 张建红,何吕荣.往返荷载作用下非饱和砂性土的液化强度和孔压规律.成都科技大学学报,1994年第1期:1~8.
[41] Seed H B,Lee K L.Liquefaction of saturated sands during cyclic Ioading.J Soil Mech Found Div, A SCE, 1966,92(SM6): 105~134.
[42] Peacock W H,Seed H B. Sand liquefaction under cyclic loading simple shear conditions.J Soil Mech Found Div, ASCE,1968,94(SM3):689~708.
[43] DeAlba P, Seed H B,Chan C K. Sand liquefaction in large-scale simple shear tests.J Geotech Engng Div, ASCE,1976,102(GT9):909~927.
[44] Tokimatsu K,Yoshimi Y. Empirical correlation of soil liquefaction based n SPT N-value and fines content. Soils and Foundations, 1983,23(4): 56~74.
[45] Pillai V S, Byrne P M. Effect of overburden stress on liquefaction resistance of sand.Can Geotech J,1994,31:53~60.
[46] 刘小生等.吉林台水电站心墙堆石坝心墙土料动力特性试验研究报告.中国水利水电科学研究院抗震防护研究所,1994年10月.
[47] 胡元芳.粉煤灰筑坝的工程性质与稳定性分析.四川联合大学硕士学位论文,1995年5月.
[48] 何昌荣等.泥石流砾石土液化机理试验研究报告.四川大学水电学院,2001年9月.
[49] 余湘娟等.砂土的振动孔压增长模式与液化剪应力的试验研究.东南大学学报(自然科学版),2000年5月,第30卷第3A期:39~42.
[50] Seesd H B, Martin P P, Lysmer J. The generation and dissipation of pore water pressures during soil liquefaction. Report No EERC 75-26,Earthquake Engineering Research Center, University of California at Brekely, U S A. 1975.
[51] Finn W D L, Lee K W, Martin G R. An effective stress model for liquefaction. J Geotech Engng Div, ASCE, 1977, 103(GT6):517-533.
[52] 徐志英、沈珠江.地震液化的有效应力二维动力分析方法.华东水利学院学报,1981a,(3).
[53] Martin G R, Finn W D L, Seed H B. Undrained deformation of liquefaction of sand under cyclic stress.Soils and Foundations, 1975,15(1):423~438.
[54] Ishihara K, Yatsuoka, Yasuda S. Undrained deformation and liquefaction of sand under cyclic stress. Soils and Foundations, 1975, 15(1):29~44.
[55] Nasser S N, Shokooh A. A unified approach to densification and liquefaction of cohesionless sand in cyclic shearing. Can Geotch J, 1979,16:659~678.
[56] Davis R O, Berrill J B. Energy dissipation and seismic liquefaction in sands. Earthquake Engng Struct Dyn, 1982,(10).
[57] 曹亚林、何广讷、林皋.土中振动孔隙水压力增长程度的能量分析法.土木工程学报,1987。26(3).
[58] Finn W D L, Bhatia S K. Endochronic theory of sand liquefaction. In:Proc 7th World Conf on Earthquake Engng, Istanbul, Turkey, 1980.
[59] 谢定义、张建民.往返荷载下饱和砂土强度形变瞬态变化机理.土木工程学报,1987,20(3).
[60] 于濂洪,王波.饱和粉土振动孔隙水压力的试验研究.大连大学学报,1999
年8月,第20卷第4期:59~62.
[61] 孙明权,顾淦臣.堤坝边坡地震液化失稳有效应力法分析研究.水利学报,1994年4月,第4期:63~68.
[62] 许才军,周红波.不排水循环荷载作用下饱和软粘土的孔压增长模型.勘查科学技术,1998年第1期:3~7.
[63] 顾淦臣.论土石坝的地震液化验算和坝坡抗震稳定计算.岩土工程学报,1981年第4期.
[64] 孙明权,顾淦臣.土坝抗震的有效应力动力分析研究.人民黄河,1990年12月,第6期:18~24.
[65] 沈珠江.砂土动力变形计算参数的室内测定.水利水运科学研究,1984年第2期:10~17.
[66] 沈珠江.一个计算砂土液化变形的等价粘弹性模式.南京水利科学研究所,1983.
[67] Hardin B O, Black W L. Vibration modulus of normal consolidated clay. J Soil Mech Found Div, ASCE,1968,94(SM2).
[68] Whitman R V, Richart F E, Jr. Design procedures for dynamically loaded foundations.J Soil Mech Found Div, ASCE,1967a,93(SM6).
[69] Richart F E, Jr, Whitman R V. Comparison of footing vibration test with theory. J Soil Mech Found Div, ASCE, 1967b,83(SM6).
[70] Seed H B, Idriss l M. Soil moduli and damping factors for dynamic response analysis. Report No EERC 70-10, Earthquake Engineering Research Center, University of California Berkely, U S A, 1970.
[71] 何昌荣等.高应力水平下堆石料垫层料或过渡料的动变形特性研究报告.四川联合大学水电学院,1994年10月,成都.
[72] 何昌荣等。攀钢马家田尾矿坝尾矿土试验研究报告.四川大学水电学院,2000年2月,成都.
[73] 何昌荣.动模量何阻尼的动三轴试验研究.岩土工程学报,第19卷第2期,1997年3月:39~48.
[74] Bobby O. Hardin and Vincent P. Drnevich. Shear modulus and damping in soils: measurement and parameter effects. Journal of the Soil Mechanics and Foundations Divisions ASCE, 1972, 98(SM6): 603~624.
[75] 陈国兴等.土的动模量何阻尼比的经验估计.地震工程与振动,第15卷第1期,1995年3月:73~83.
[76] 牟崇元等.等幅循环荷载作用下土的动剪模和阻尼.华南地震,第11卷第2期,1991年6月:13~21.
[77] Vucetic M and R Dobry. Effect of soli Plasticity on Cyclic Response. ASCE. Vol.117.No. GT1,1991:89~107.