粘性土变形和强度参数分析

蒋建平; 罗国煜; 高广运

粘性土变形和强度参数分析

1.
上海海事大学交通运输学院, 上海 200135
2.
南京大学地球科学系, 江苏南京 210093
3.
同济大学地下建筑与工程系, 上海 200092

基金项目:

上海市教委科研项目 05FZ03

国家自然科学基金项目 50678128

上海市交通运输规划与管理重点学科项目 J50601

详细信息

作者简介:
蒋建平(1966-), 男, 湖南邵阳人, 上海海事大学副教授, 工学博士, 从事地基基础与桩基础研究

中图分类号: U443.1
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- 文章访问数: 291
- HTML全文浏览量: 102
- PDF下载量: 228
- 被引次数: 0
出版历程
- 收稿日期: 2007-06-06
- 刊出日期: 2007-12-25

Analysis of deformation and strength parameters for cohesive clay

1.
School of Traffic and Transportation, Shanghai Maritime University, Shanghai 200135, China
2.
Department of Earth Science, Nanjing University, Nanjing 210093, Jiangsu, China
3.
Department of Geotechnical Engineering, Tongji University, Shanghai 200092, China

More Information

Author Bio:
Jiang Jian-ping(1966-), male, EngD, associate professor, + 86-21-65059028, jjpwx@163.com.

摘要

摘要: 为了解长江下游苏通公路大桥地基土工程特性, 基于大量的室内土工试验和回归分析方法, 研究了水下地基粘性土的变形参数和强度参数特性。发现粘性土的变形参数和强度参数的变异系数比物理参数的变异系数大; 压缩模量与天然孔隙比、天然含水量、干密度等物理参数成指数关系, 相关系数大于0.87;压缩系数与3个物理参数成线性关系, 相关系数超过0.91;粘聚力与3个物理参数成较好的指数关系, 相关系数大于0.84, 而内摩擦角与物理参数间的相关关系差, 线性相关系数小于0.41。
- 粘性土 /
- 试验研究 /
- 变形参数 /
- 强度参数
Abstract: In order to understand the engineering properties of cohesive clay in the foundation of Sutong highway large bridge in the lower reaches of Yangtze River, the deformation and strength parameters were studied based on a large number of geotechnical tests and regression analysis method.Study result shows that the variation coefficients of deformation and strength parameters for cohesive clay are larger than those of physical parameters; there is good exponential correlativity between compression module and three physical parameters that are natural pore-solid ratio, natural water content and dry density, the correlativity coefficients are more than 0.87;there is linear correlativity between compression coefficient and three physical parameters, the correlativity coefficients are more than 0.91;there is better exponential correlativity between cohesion and three physical parameters, their correlativity coefficients are more than 0.84;while the correlativity between internal friction angle and three physical parameters is bad, their linear correlativity coefficients are less than 0.41.
- cohesive clay /
- experimental study /
- deformation parameters /
- strength parameters

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图 1 苏通大桥位置Fig.1 Location of Sutong bridge

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图 2 压缩模量与物理参数关系

Figure 2. Relationship between compression module and physical parameters

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图 3 压缩系数与物理参数关系

Figure 3. Relationship between compression coefficient and physical parameters

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图 4 粘聚力与物理参数关系

Figure 4. Relationship between cohesion and physical parameters

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图 5 内摩擦角与物理参数关系

Figure 5. Relationship between internal friction angle and physical parameters

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表 1 参数统计

Table 1. Statistic of parameters

物理力学指标	粘土			粉质粘土
物理力学指标	范围	平均值	变异系数	范围	平均值	变异系数
天然含水量/%	25.3~39.5	33.4	0.10	18.3~39.5	34.3	0.08
天然密度/(g·cm^-3)	1.79~1.99	2.08	0.02	1.79~2.08	1.82	0.02
天然孔隙比	0.517~1.092	0.628	0.05	0.529~1.108	1.004	0.08
压缩系数/MPa^-1	0.06~0.54	0.18	0.12	0.08~0.54	0.36	0.24
压缩模量/MPa	9.49~29.10	14.52	0.14	3.83~21.52	5.82	0.22
粘聚力/kPa	10~165	45	0.15	10~126	39	0.31
内摩擦角/(°)	8.2~28.8	17.4	0.21	7.2~29.4	19.0	0.32

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