Total stress approach for stability of seabed under wave loads

YU Bo; FENG Tu-gen; XIONG Zhong-hua

doi:10.11779/CJGE201405014

Volume 36 Issue 5

Turn off MathJax

Article Contents

Abstract

References

Chinese Journal of Geotechnical Engineering > 2014 > 36(5): 905-909. > DOI: 10.11779/CJGE201405014

YU Bo, FENG Tu-gen, XIONG Zhong-hua. Total stress approach for stability of seabed under wave loads[J]. Chinese Journal of Geotechnical Engineering, 2014, 36(5): 905-909. DOI: 10.11779/CJGE201405014

Citation:

PDF (496 KB)

Total stress approach for stability of seabed under wave loads

YU Bo^{1, 2},
FENG Tu-gen^1,2,,
XIONG Zhong-hua^{1, 2}

1. Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University, Nanjing 210098, China; 2. Research Institute of Geotechnical Engineering, Hohai University, Nanjing 210098, China

More Information

Received Date: August 18, 2013
Published Date: May 20, 2014

Graphical Abstract

Abstract

Abstract

The evaluation of seabed stability is an important part for the design of various marine facilities. Based on the classic theory of elasticity, the total stress solutions for layered elastic seabed under linear wave loads are derived by means of the semi-inverse method, and then according to the Mohr-Coulomb failure criterion, seabed shear failure is analyzed on the basis of the solutions. The results show that the shear modulus of soils which increases linearly along with the seabed depth has a significant effect on the distribution of stress angle, especially when the seabed thickness is less than a half times the wavelength. The easiest place to initiate shear failure is located at a certain depth below the seabed surface. However, for the homogeneous seabed, it is located at the surface of seabed . The stability of seabed is also affected by weak interlayer. The more shallow the depth of the weak interlayer, the more easily the shear failure of soil layer occurs on the weak interlayer.
- seabed,
- wave load,
- total stress method,
- stability

FullText(HTML)

References (15)

References

[1]	RAHMAN M S. Wave-induced instability of seabed: Mechanism and conditions[J]. Marine Geotechnology, 1991, 10(3/4): 277-299.
[2]	KOUKI Z, JENG D S, HSU J R C, et al. Wave-induced seabed instability: Difference between liquefaction and shear failure[J]. Soils and Foundations, 1998, 38(2): 37-47.
[3]	OKUSA S. Wave-induced stress in unsaturated submarine sediments[J]. Géotechnique, 1985, 35(4): 517-532.
[4]	TSAI C P. Wave-induced liquefaction potential in a porous seabed in front of a breakwater[J]. Ocean Engineering, 1995, 22(1): 1-18.
[5]	ZEN K, YAMAZAKI H. Mechanism of wave-induced liquefaction and densification in seabed[J]. Soils and Foundations, 1990, 30(4): 161-179.
[6]	JENG D S. Wave-induced seabed instability in front of a breakwater[J]. Ocean Engineering, 1997, 24(10): 887-917.
[7]	HENKEL D J. The role of waves in causing submarine landslides[J]. Géotechnique, 1970, 20(1): 75-80.
[8]	YAMAMOTO T, KONING H L, SELLMEJJER H. On the response of a poro-elastic bed to water waves[J]. Fluid Mechanics, 1978, 87(1): 193-206.
[9]	JENG D S. Porous models for wave-seabed interactions[M]. Shanghai: Shanghai Jiao Tong University Press, 2013.
[10]	栾茂田, 张晨明, 王栋, 等. 波浪作用下海床孔隙水压力发展过程与液化的数值分析[J]. 水利学报, 2004, 35(2): 94-101. (LUAN Mao-tian, ZHANG Chen-ming, WANG Dong, et al. Numerical analysis residual pore water pressure development and evaluation of liquefaction potential of seabed under ware loading[J]. Journal of Hydraulic Engineering, 2004, 35(2): 94-101. (in Chinese))
[11]	刘红军, 王虎, 张民生, 等. 波浪作用下黄河三角洲粉质土海床动力响应分析[J]. 岩土力学, 2013, 34(7): 2065-2071. (LIU Hong-jun, WANG Hu, ZHANG Min-sheng, ea al. Analysis of wave-induced dynamicl responsa of silty seabed in Yellow River delta[J]. Rock and Soil Mechanics, 2013, 34(7): 2065-2071. (in Chinese))
[12]	张永利, 李杰. 基于总应力法的波致海床剪切破坏准则[J]. 力学季刊, 2010, 31(3): 342-349. (ZHANG Yong-li, LI Jie. Wave-induced sealed shear failure criterion based on total stress approach[J]. Chinese Quarterly of Mechanics, 2010, 31(3): 342-349. (in Chinese))
[13]	李广信. 岩土工程50讲[M]. 北京: 人民交通出版社, 2010. (LI Guang-xin. 50 Geotechnical lectures[M]. Beijing: China Communications Press, 2010. (in Chinese))
[14]	JENG D S, LEE T L. Dynamic response of porous seabed to ocean waves[J]. Computers and Geotechnics, 2001, 28(2): 99-128.
[15]	郭秀军, 朱大伟, 孟庆生, 等. 波浪作用下黄河口多层粉质土海床动力响应特征差异性分析[J]. 岩土工程学报, 2012, 34(12): 2270-2276. (GU Xiu-jun, ZHU Da-wei, MENG Qing-sheng, et al. Differences in dynamic response characteristics of multi-lager silty seabed under waves in Yellow River Estuary[J]. Chinese Journal of Geotechnical Engineering, 2012, 34(12): 2270-2276. (in Chinese))

Supplements (0)

Cited By

Cited by

Periodical cited type(7)

1.	刘志，杨阳. 黄原胶联合微生物加固改善混合砂蓄水特性试验研究. 土木与环境工程学报(中英文). 2025(03): 49-57 .
2.	梁越，冉裕星，许彬，张鑫强，何慧汝. 细颗粒含量影响渗流侵蚀规律的细观机理研究. 岩土工程学报. 2025(05): 1099-1106 . 本站查看
3.	高霞，梅雯艳，吴强，崔祥龙. 球度和扁平度对含瓦斯水合物煤体宏细观力学性质影响研究. 中国安全生产科学技术. 2025(05): 86-94 .
4.	蔡国庆，刁显锋，杨芮，王北辰，高帅，刘韬. 基于CFD-DEM的流-固耦合数值建模方法研究进展. 哈尔滨工业大学学报. 2024(01): 17-32 .
5.	程建毅，郭晓军，李泳. 泥石流物源土体标度分布参数与粘聚力的关系. 山地学报. 2024(03): 401-410 .
6.	孙增春，刘汉龙，肖杨. 砂-粉混合料的分数阶塑性本构模型. 岩土工程学报. 2024(08): 1596-1604 . 本站查看
7.	孙建强. 颗粒形状对黄土干密度与抗剪强度的影响. 黑龙江工程学院学报. 2024(06): 8-15+23 .

Other cited types(5)

Get Citation

PDF

XML

Article views PDF downloads Cited by(12)

Total stress approach for stability of seabed under wave loads

Abstract

References

Cited by

Periodical cited type(7)

Other cited types(5)

Catalog

Related

Total stress approach for stability of seabed under wave loads

Abstract

References

Cited by

Periodical cited type(7)

Other cited types(5)

Catalog

Related

Export File

Citation

Format

Content