冲击压实路基黄土的微观特征研究

详细信息 本馆镜像全文    |  推荐本文 | | 获取馆网全文

英文篇名：Microstudy on roadbed loess improvement by impact compaction technology 中文刊名：岩土力学 英文刊名：Rock and Soil Mechanics 作者：王生新 ; 韩文峰 ; 谌文武 ; 梁庆国 英文作者：WANG Sheng-xin1 ; 2 ; HAN Wen-feng1 ; 3 ; CHEN Wen-wu1 ; 2 ; LIANG Qing-guo1(1.School of Civil Engineering and mechanics ; Lanzhou University ; Lanzhou 730000 ; China ; 2.Key Laboratory of Mechanics on Western Disasterand Environment ; Ministry of Education ; Lanzhou University ; Lanzhou 730000 ; China ; 3.Department of Civil Engineering ; Tianjin College of Urban Construction ; Tianjin 300381 ; China) 中文关键词：路基黄土 ; 冲击压实 ; 扫描电镜 ; 压汞分析 ; 孔径分布 英文关键词：roadbed loess ; impact compaction ; scanning electron microscope(SEM) ; mercury intrusion porosimetry(MIP) ; pore size distribution 出版日期：2006-06-10 机构：兰州大学土木工程与力学学院,兰州大学土木工程与力学学院,兰州大学土木工程与力学学院,兰州大学土木工程与力学学院 兰州730000,兰州大学西部灾害与环境力学教育部重点实验室,兰州730000,兰州730000,天津城市建设学院土木工程系,天津300381,兰州730000,兰州大学西部灾害与环境力学教育部重点实验室,兰州730000,兰州730000 年：2006 期：06 出版单位：岩土力学

摘要

采用扫描电镜和压汞试验研究了天然黄土和冲击压实8～40遍路基黄土的微观结构和孔隙特征。结果表明:天然黄土和冲击压实8遍的路基黄土,其微结构以粒状架空结构为主;冲击压实16～40遍,土的微结构变成粒状镶嵌结构。冲击压实16遍前后,土的孔隙直径分布在0.006～164μm之间,平均孔径从0.767 9μm降低到0.0 711μm,中等孔径从5.264μm减少到0.568 4μm;但孔隙表面积从0.624 m2/g增加到7.517 m2/g。孔径分布在10μm和2μm处出现分界值,16遍前2The microstructure and pore characteristics of natural loess and roadbed loess improved by impact compaction after 8-40 compactor passes were qualitatively and quantitatively studied on the basis of the test results from scanning electron microscope(SEM) and mercury intrusion porosimetry(MIP).The results show that open structure is the main structure type of natural loess and roadbed loess after 8 compactor passes;and inter-particle inlaid structure is the main type of roadbed loess after 16-40 compactor passes;The pore size distribution is within the range of 0.006~164 μm before and after 16 compactor passes,the average pore diameter has been lowered from 0.767 9 μm to 0.071 1 μm;the median pore diameter has been decreased from 5.264 μm to 0.5684 μm.The pore surface area has been increased from 0.624 m2/g to 7.517 m2/g;there are two dividing pore diameters of 10 μm and 2 μm for all types of loess,and for the loess before 16 compactor passes,the pores with diameter between 2 to 10μm cover 67.53 % of all the pores,while the pores with diameter less than 2μm cover 68.07 % for loess after 16 compactor passes.Therefore the optimum compactor pass is 16 and the improvement mechanism of impact compaction is change in loess microstructure and increase of micropores.

引文

[1]张洪,孙斌煜,朱维高.滚动冲击压实技术及其机械设计研究[J].中国机械工程,1999,10(3):256-260.ZHANG Hong,SUN Bin-yu,ZHU Wei-gao.Research on the technology and machine design of rolling impact compaction[J].China Mechanical Engineering,1999,10(3):256-260.
    [2]方其杭,张展,陆磊.蓝派冲击式压实机技术特性及应用[J].交通科技与经济,2002,13(1):13-14.FANG Qi-hang,ZHANG Zhan,LU Lei.The performance and applcation of Aubrey berrange-percussive-compactor[J].Technology&Economy in Areas of communications(TEAC),2002,13(1):13-14.
    [3]杨人风,张永新,赵新荣.土的冲击压实试验研究[J].中国公路学报,2003,16(3):31-34.YANG Ren-feng,ZHANG Yong-xin,ZHAO Xin-rong.Research on test of impact compaction about soil[J].China Journal of Highway and Transport,2003,16(3):31-34.
    [4]杨世基.冲击压实技术在路基工程中的应用[J].公路,1999,(7):1-4.YANG Shi-ji.Application of impact compaction technology in roadbed engineering[J].Highway,1999,(7):1-4.岩土力学2006年
    [5]史保华,司剑峰,朱小力,等.冲击压实技术在机场工程软基处理中的应用研究[J].中国公路学报,2001,14(3):33-38.SHI Bao-hua,SI Jian-feng,ZHU Xiao-li,et al.Application study of impact compaction technology in airport soft ground engineering[J].China Journal of Highway and Transport,2001,14(3):33-38.
    [6]刘若琪,华遵梦,沈秋武.黄土路基冲击碾压检测成果分析[A].罗宇生,汪国烈主编.湿陷性黄土研究与工程[C].北京:中国建筑工业出版社,2001.237-244.
    [7]高国瑞.我国黄土湿陷性质的形成研究[J].南京建筑工程学院学报,1994,(2):1-8.GAO Guo-rui.The formation of collapsibility of loess soils in China[J].Journal of Nanjing Architectural and Civil Engineering Institute,1994,(2):1-8.
    [8]高国瑞.黄土湿陷变形的结构理论[J].岩土工程学报,1990,12(4):1-10.GAO Guo-rui.A Structure theory for collapsing deformation of loess soils[J].Chinese Journal of Geotechnical Engineering,1990,12(4):1-10.
    [9]高国瑞.中国黄土的微结构[J].科学通报,1980,(24):945-948.GAO Guo-rui.Microstructure of loess soils in China[J].China Science Bulletin,1980,(24):945-948.
    [10]高国瑞.黄土显微结构分类与湿陷性[J].中国科学,1980,(12):1 203-1 209.GAO Guo-rui.Microstructure classification and collapsibility of loess soils[J].Science in China,1980,(12):1 203-1 209.
    [11]苗天德.黄土湿陷变形机理的研究现状[A].罗宇生,汪国烈主编.湿陷性黄土研究与工程[C].北京:中国建筑工业出版社,2001.73-82.
    [12]MIAO T D,NIU Y H,LIU Z Y.Unified catastrophic model for collapsible loess[J].Journal of Engineering Mechanics,2002,128(5):595-598.
    [13]Rogers C D F,Dijkstra T A,Smalley I J.Hydroconsolidation and subsidence of loess:studies from China,Russia,North America and Europe[J].Engineering Geology,1994,37:83-113.
    [14]杨运来.黄土湿陷机理的研究[J].中国科学(B辑),1988,(7):756-766.YANG Yun-lai.Study of the mechanism of loess collapse[J].Science in China(Series B),1988,(7):756-766.
    [15]雷祥义.中国黄土的孔隙类型与湿陷性[J].中国科学(B辑),1987,(12):1 309-1 315.LEI Xiang-yi.Pore types and collapsibility of loess soils in China[J].Science in China(Series B),1987,(12):1 309-1 315.
    [16]李云峰.黄土渗透性与空隙性关系的研究[M].北京:地质出版社,1994.10-31.
    [17]齐吉琳,谢定义,石玉成.土结构性的研究方法及现状[J].西北地震学报,2001,23(1):99-103.QI Ji-lin,XIE Ding-yi,SHI Yu-cheng.Status quo and method of quantitative study on soil structure[J].Northwestern Seismological Journal,2001,23(1):99-103.
    [18]沈珠江.土体结构性的数学模型—21世纪土力学的核心问题[J].岩土工程学报,1996,18(1):95-97.SHEN Zhu-jiang.Mathematical model of soil mass structure—core problems of soil mechanics in 21st century[J].Chinese Journal of Geotechnical Engineering,1996,18(1):95-97.
    [19]谢定义.试论我国黄土力学研究中的若干新趋向[J].岩土工程学报,2001,23(1):1-13.XIE Ding-yi.Exploration of some new tendencies in research of loess soil mechanics[J].Chinese Journal of Geotechnical Engineering,2001,23(1):1-13.