细粒含量对岛礁吹填珊瑚砂最大动剪切模量影响的试验研究

doi:10.13722/j.cnki.jrme.2021.0115

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Abstract The reef reclamation field survey results indicate that grain size distribution curves of coral sand in partial regions of coral ground layers，composed of coarse-grained and fine-grained particles in different proportions，are quite wide. Moreover，grasping the dynamic properties of coral sand in South China Sea where earthquakes frequently occur is significantly important for ground response analysis of reclamation reef islands. A series of resonant column tests were performed on coral sand-fines mixtures to investigate the influences of the density，the confining pressure and the fine content on their dynamic characteristics at small level strain in this study. The study employs the tamping energy method to prepare the coral sand-fine mixtures at different densities. The results indicate that the maximum dynamic shear modulus increases with increasing the density and the confining pressure. Under the same test condition，the maximum dynamic shear modulus decreases with increasing the amount of fines，due to that the presence of fines between coarse grains changes the contact condition between grains and the skeleton structure. The traditional expression of the void ratio has no capacity of describing the “real” compaction state of coral sand-fine mixtures and characterizing the role of fines in contributing the skeleton structure of sand. Based on the concept of the equivalent skeleton void ratio，an experienced model jointly considering the effects of the fine content，the density and the confining pressure is proposed to estimate the maximum dynamic modulus of coral sand-fine mixtures. This study is expected to provide a database for island reclamation site earthquake response analysis.

Key words： soil mechanics coral sand fines dynamic shear modulus damping ratio equivalent skeleton void ratio

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	Articles by authors
	WU Yang1
	2
	CUI Jie1
	2
	LI Chen2
	WEN Liwei2
	SHAN Zhendong1
	LIAO Jingrong2

Cite this article:

WU Yang1,2,CUI Jie1, et al. Experimental study on the effect of fines on the maximum dynamic shear modulus of coral sand in a hydraulic fill island-reef[J]. , 2022, 41(1): 205-216.

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https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2021.0115 OR https://rockmech.whrsm.ac.cn/EN/Y2022/V41/I1/205

[1] MEJIA L H，YEUNG M R. Liquefaction of coralline soils during the 1993 Guam earthquake[C]// Earthquake-induced Movements and Seismic Remediation of Existing Foundations and Abutments. [S. l.]：ASCE，1995：33–48.
[2] IWASAKI T. TATSUOKA F. Effects of grain size and grading on dynamic shear moduli of sands[J]. Soils and Foundations，1977，17(3)：19–35.
[3] OZTOPRAK S. BOLTON M. Stiffness of sands through a laboratory test database[J]. Géotechnique，2013，63(1)：54–70.
[4] 袁晓铭，孙锐，孙静，等. 常规土类动剪切模量比和阻尼比试验研究[J]. 地震工程与工程振动，2000，20(4)：133–139.(YUAN Xiaoming，SUN Rui，SUN Jing，et al. Experimental study on dynamic shear modulus ratio and damping ratio of Conventional soils[J]. Earthquake Engineering and Engineering Dynamics，2000，20(4)：133–139.(in Chinese))
[5] 陈国兴，刘雪珠. 南京及邻近地区新近沉积土的动剪切模量和阻尼比的试验研究[J]. 岩石力学与工程学报，2004，23(8)：1 403–1 410. (CHEN Guoxing，LIU Xuechu. Experimental study on dynamic shear modulus and damping ratio of newly deposited soils in nanjing and adjacent areas[J]. Chinese Journal of Rock Mechanics and Engineering，2004，23(8)：1 403–1 410.(in Chinese)).
[6] WICHTMANN T. TRIANTAFYLLIDIS T. Influence of the grain-size distribution curve of quartz sand on the small strain shear modulus G max[J]. Journal of Geotechnical and Geoenvironmental Engineering，2009，135(10)：1 404–1 418.
[7] HARDIN B O，DRNEVICH V P. Shear modulus and damping in soils：design equations and curves[J]. Journal of Soil Mechanics and Foundations Division，1972，98(7)：667–692.
[8] 孔令伟，臧濛，郭爱国. 湛江黏土动剪切模量的结构损伤效应与定量表征[J]. 岩土工程学报，2017，39(12)：2 149–2 157.(KONG Lingwei，ZANG Meng，GUO Aiguo. Structural damage effect and quantitative characterization of dynamic shear modulus of Zhanjiang clay[J]. Chinese Journal of Geotechnical Engineering，2017，39(12)：2 149–2 157.(in Chinese)).
[9] 董全杨，蔡袁强，徐长节，等. 干砂饱和砂小应变剪切模量共振柱弯曲元对比试验研究[J]. 岩土工程学报，2013，35(12)：2 283–2 289. (DONG Quanyang，CAI Yuanqiang，XU Changjie，et al. Comparative Experimental study on bending element of dry sand saturated sand resonance column with small strain shear modulus[J]. Chinese Journal of Geotechnical Engineering，2013，35(12)：2 283–2 289.(in Chinese))
[10] YANG J，GU X. Shear stiffness of granular material at small strains：does it depend on grain size[J]. Géotechnique，2013，63(2)：165–179.
[11] 顾晓强，杨峻，黄茂松，等. 砂土剪切模量测定的弯曲元、共振柱和循环扭剪试验[J]. 岩土工程学报，2016，38(4)：740–746.(GU Xiaoqiang，YANG Jun，HUANG Maosong，et al. Bending element，resonance column and cyclic torsional shear test for shear modulus determination of sand[J]. Journal of Geotechnical Engineering，2016，38(4)：740–746.(in Chinese))
[12] 朱长歧，陈海洋，孟庆山，等. 钙质砂颗粒内孔隙的结构特征分析[J]. 岩土力学，2014，35(7)：1 831–1 836.(ZHU Changqi，CHEN Haiyang，MENG Qingshan，et al. Analysis of structural characteristics of pores in calcareous sand particles[J]. Rock and Soil Mechanics，2014，35(7)：1 831–1 836.(in Chinese))
[13] 孙吉主，汪稔. 钙质砂的颗粒破碎和剪胀特性的围压效应[J]. 岩石力学与工程学报，2004，23(4)：641–644.(SUN Jizhu，WANG Ren. Influence of confining pressure on particle breakage and shear expansion of calcareous sand[J]. Chinese Journal of Rock Mechanics and Engineering，2004，23(4)：641–644.(in Chinese))
[14] 叶剑红，曹梦，李刚. 中国南海吹填岛礁原状钙质砂蠕变特征初探[J]. 岩石力学与工程学报，2019，38(6)：1 242–1 251.(YE Jianhong，CAO Meng，LI Gang. Preliminary study on the creep characteristics of calcareous sand from reclaimed coral reef islands in South China Sea[J]. Chinese Journal of Rock Mechanics and Engineering，2019，38(6)：1 242–1 251.(in Chinese))
[15] 张季如，张弼文，胡泳，等. 粒状岩土材料颗粒破碎演化规律的模型预测研究[J]. 岩石力学与工程学报，2016，35(9)：1 898–1 905. (ZHANG Jiru，ZHANG Bizhou，HU Yong，et al. Predicting the particle breakage of granular geomaterials[J]. Chinese Journal of Rock Mechanics and Engineering，2016，35(9)：1 898–1 905.(in Chinese))
[16] 吴杨，崔杰，李能，等. 岛礁吹填珊瑚砂力学行为与颗粒破碎特性试验研究[J]. 岩土力学，2020，41(10)：3 181–3 191.(WU Yang，CUI Jie，LI Neng，et al. Experimental study on the mechanical behavior and particle breakage characteristics of hydraulic filled coral sand on a coral reef island in the South[J]. Rock and Soil Mechanics，2020，41(10)：3 181–3 191.(in Chinese))
[17] GIANG P H H，VAN IMPE P O，VAN IMPE W F，et al. Small-strain shear modulus of calcareous sand and its dependence on particle characteristics and gradation[J]. Soil Dynamics and Earthquake Engineering，2017，100：371–379.
[18] HE H，LI W. SENETAKIS K. Small strain dynamic behavior of two types of carbonate sands[J]. Soils and Foundations，2019，59(3)：571–585.
[19] 刘鑫，李飒，刘小龙，等. 南海钙质砂的动剪切模量与阻尼比试验研究[J]. 岩土工程学报，2019，41(9)：1 773–1 780.(LIU Xin，LI Sa，LIU Xiaolong，et al. Experimental study on dynamic shear modulus and damping ratio of calcareous sand in the south China sea[J]. Chinese Journal of Geotechnical Engineering，2019，41(9)：1 773–1 780.(in Chinese))
[20] 刘汉龙，胡鼎，肖杨，等. 钙质砂动力液化特性的试验研究[J]. 防灾减灾工程学报，2015，35(6)：707–711.(LIU Hanlong，HU Ding，XIAO Yang，et al. Experimental study on dynamic liquefaction characteristics of calcareous sand[J]. Journal of Disaster Prevention and Mitigation Engineering，2015，35(6)：707–711.(in Chinese))
[21] 袁晓铭，张文彬，段志刚，等. 珊瑚土工程场地地震液化特征解析[J]. 岩石力学与工程学报，2019，38(增2)：3 799–3 811.(YUAN Xiaoming，ZHANG Wenbin，DUAN Zhigang，et al. Analysis of seismic liquefaction characteristics of coral soil engineering site[J]. Chinese Journal of Rock Mechanics and Engineering，2019，38(Supp.2)：3 799–3 811.(in Chinese))
[22] 马维嘉，陈国兴，李磊，等. 循环荷载下饱和南沙珊瑚砂的液化特性试验研究[J]. 岩土工程学报，2019，41(5)：981–988.(MA Weijia，CHEN Guoxing，LI Lei，et al. Experimental study on the liquefaction characteristics of saturated coral sand in nansha under cyclic loading[J]. Chinese Journal of Geotechnical Engineering，2019，41(5)：981–988. (in Chinese))
[23] 李立云，崔杰，景立平，等. 饱和粉土振动液化分析[J]. 岩土力学，2005，26(10)：142–145.(LI Liyun，CUI Jie，JING Liping，et al. Vibration liquefaction analysis of saturated silty soil[J]. Rock and Soil Mechanics，2005，26(10)：142–145.(in Chinese))
[24] 戴北冰，杨峻. 含细粒砂土反常剪切行为的数值模拟研究[J]. 岩土力学，2015，36(增1)：619–623.(DAI Beibing，YANG Jun. Numerical simulation of abnormal shear behavior of sandy soil containing fine grains[J]. Rock and Soil Mechanics，2015，36(Supp.1)：619–623.(in Chinese))
[25] SALGADO R，BANDINI P，KARIM A. Shear strength and stiffness of silty sand[J]. Journal of Geotechnical and Geoenvironmental Engineering，2000，126(5)：451–462.
[26] 王勇，王艳丽. 细粒含量对饱和砂土动弹性模量与阻尼比的影响研究[J]. 岩土力学，2011，32(9)：2 623–2 628.(WANG Yong，WANG Yanli. Research on the influence of fine grain content on dynamic elastic modulus and damping ratio of saturated sandy soil[J]. Rock and Soil Mechanics，2011，32(9)：2 623–2 628. (in Chinese))
[27] GOUDARZY M，KÖNIG D，SCHANZ T. Small strain stiffness of granular materials containing fines[J]. Soils and Foundations，2016，56(5)：756–764.
[28] THEVANAYAGAM S，SHENTHAN T，MOHAN S，et al. Undrained fragility of clean sands，silty sands，and sandy silts[J]. Journal of Geotechnical and Geoenvironmental Engineering，2002，128(10)：849–859.
[29] RAHMAN M M，BAKI M，LO S. Prediction of undrained monotonic and cyclic liquefaction behavior of sand with fines based on the equivalent granular state parameter[J]. International Journal of Geomechanics，2014，14(2)：254–266.
[30] 中华人民共和国行业标准编写组. SL237－1999 土工试验规程[S]. 北京：中国水利水电出版社，1999.(The Professional Standards Compilation Group of the People's Republic of China. SL 237－1999 Test methods of soils[S]. Beijing：China Water Power Press，1999.(in Chinese))
[31] NAEINI S，BAZIAR M. Effect of fines content on steady-state strength of mixed and layered samples of a sand[J]. Soil Dynamics and Earthquake Engineering，2004，24(3)：181–187.
[32] KIM U，KIM D，ZHUANG L. Influence of fines content on the undrained cyclic shear strength of sand-clay mixtures[J]. Soil Dynamics and Earthquake Engineering，2016，83：124–134.
[33] 毕昇，陈国兴，周正龙，等. 细粒含量及固结应力对饱和砂土动剪切模量和阻尼比影响试验研究[J]. 岩土工程学报，2017，39(增1)：48–52.(BI Sheng，CHEN Guoxing，ZHOU Zhenglong，et al. Experimental Study on influence of fine grain content and consolidation stress on dynamic shear modulus and damping ratio of saturated sandy soil[J]. Chinese Journal of Geotechnical Engineering，2017，39(Supp.1)：48–52.(in Chinese))
[34] 吴琪，陈国兴，朱雨萌，等. 基于等效骨架孔隙比指标的饱和砂类土抗液化强度评价[J]. 岩土工程学报，2018，40(10)：1 912–1 922. (WU Qi，CHEN Guoxing，ZHU Yumeng，et al. Evaluation of anti-liquefaction strength of saturated sand based on equivalent skeleton pore ratio index[J]. Chinese Journal of Geotechnical Engineering，2012，40(10)：1 912–1 922.(in Chinese))
[35] ZUO L. BAUDET B A. Determination of the transitional fines content of sand-non plastic fines mixtures[J]. Soils and Foundations，2015，55(1)：213–219.