Dynamic analyses of a high earth-rockfill dam considering effects of solid-fluid coupling

WU Yong-kang; WANG Xiang-nan; DONG Wei-xin; YU Yu-zhen

doi:10.11779/CJGE201511010

Volume 37 Issue 11

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Chinese Journal of Geotechnical Engineering > 2015 > 37(11): 2007-2013. > DOI: 10.11779/CJGE201511010

WU Yong-kang, WANG Xiang-nan, DONG Wei-xin, YU Yu-zhen. Dynamic analyses of a high earth-rockfill dam considering effects of solid-fluid coupling[J]. Chinese Journal of Geotechnical Engineering, 2015, 37(11): 2007-2013. DOI: 10.11779/CJGE201511010

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Dynamic analyses of a high earth-rockfill dam considering effects of solid-fluid coupling

State Key Laboratory of Hydroscience and Engineering, Department of Hydraulic Engineering, Tsinghua University, Beijing 100084, China

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Received Date: September 07, 2014
Published Date: November 19, 2015

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Abstract

In the process of construction, impounding or action of earthquake, the solid-fluid coupling has a significant influence on the static and dynamic responses of earth-rockfill dams, which should be considered in the seismic analysis. Taking the Nuozhadu high earth-rockfill dam as an example, static and seismic analyses are conducted by using the solid-fluid coupling method. The Mohr-Coulomb elasto-plastic model is employed to describe the mechanical properties of dam materials. The construction of the dam and the impounding of the reservoir are simulated in the static analysis, then on the basis of the static stress field, the dynamic response of the dam during an earthquake is investigated using the fully-coupled nonlinear method. The evolution of residual deformations and the accumulation and dissipation of excess pore water pressure can be calculated more reasonably. The results show that the excess pore water pressure accumulates gradually with earthquake, and the maximum value occurs at the bottom of core. The acceleration amplification reaches the maximum at the crest as a result of whiplash effect. The horizontal and vertical permanent displacements both reach the maximum values at the dam crest.
- solid-fluid coupling,
- earth-rockfill dam,
- dynamic analysis,
- initial stress field,
- construction,
- impoundment

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[1]	YASUDA N, MATSUMOTO N. Dynamic deformation characteristics of sands and rockfill materials[J]. Canadian Geotechnical Journal, 1993; 30(5): 747-757.
[2]	HUNTER G, FELL R. Rockfill modulus and settlement of concrete face rockfill dams[J]. Journal of Geotechnical and Geoenvironmental Engineering, 2003; 129(10): 909-917.
[3]	LI H, MANUEL P, LI T. Application of a generalized plasticity model to ultra-high rockfill dam[C]// Earth & Space 2010 ASCE. Honolulu, 2010: 385-398.
[4]	SOROUSH A, JANNATIAGHDAM R. Behavior of rockfill materials in triaxial compression testing[J]. International Journal of Civil Engineering, 2012; 10(2): 153-161.
[5]	CHEN M. Response of an earth dam to spatially varying earthquake ground motion[D]. East Lansing: Civil and Environmental Engineering, Michigan State University, 1995.
[6]	COSTA L, ALONSO E, Predicting the behavior of an earth and rockfill dam under construction[J]. Journal of Geotechnical and Geoenvironmental Engineering, 2009; 135(7): 851-862.
[7]	SEO M W, HA I S. Behavior of concrete-faced rockfill dams during initial impoundment[J]. Journal of Geotechnical and Geoenvironmental Engineering, 2009, 135(8): 1070-1081.
[8]	PREVOST J H, ABDEL-GHAFFAR A M, LACY S J. Nonlinear dynamic analyses of an earth dam[J]. Journal of Geotechnical Engineering, 1985, 111(7): 882-897.
[9]	SEED H B, MARTIN G R. The seismic coefficient in Earth dam design[J]. Journal of the Soil Mechanics and Foundations Division, 1966, 92 (SM3): 25-58.
[10]	董威信. 高心墙堆石坝流固耦合弹塑性地震动力响应分析[D]. 北京: 清华大学, 2015. (DONG Wei-xin. Elasto- plastic fluid-solid coupling analysis of seismic response of high core-wall rockfill dam[D]. Beijing: Tsinghua University, 2015. (in Chinese))
[11]	齐文浩, 薄景山. 土层地震反应等效线性化方法综述[J]. 世界地震工程, 2007, 23(4): 221-226. (QI Wen-hao, BO Jing-shan. Summarization on equivalent linear method of seismic responses for soil layers[J]. World Earthquake Engineering, 2007, 23(4): 221-226. (in Chinese))
[12]	沈珠江, 徐刚. 堆石料的动力变形特性[J]. 水利水运科学研究, 1996(2): 143-150. (SHEN Zhu-jiang, XU Gang. Dynamic deformation characteristics of rockfill[J]. Journal of Nanjing Hydraulic Research Institute, 1996(2): 143-150. (in Chinese))
[13]	SCHNABEL P B, LYSMER J, SEED H B. SHAKE: a computer program for earthquake response analysis of horizontally layered sites[R]. Berkeley: Earthquake Engineering Research Center, University of California, 1972.
[14]	Itasca Consulting Group. Fast Lagrangian analysis of continua[M]. Minneapolis: Itasca Consulting Group, 2005.
[15]	朱亚林, 孔宪京, 邹德高, 等. 高土石坝地震反应和破坏机理分析[J]. 岩土工程学报, 2010, 32(9): 1362-1367. (ZHU Ya-lin, KONG Xian-jing, ZOU De-gao, et al. Dynamic response and failure mechanism of high earth-rockfill dams[J]. Chinese Journal of Geotechnical Engineering, 2010, 32(9): 1362-1367. (in Chinese))
[16]	SEED H B. A method for earthquake resistant design of earth dams[J]. Journal of the Soil Mechanics and Foundations Division, 1966, 92(1): 13-41.
[17]	FINN W D, MARTIN G R, LEE K W. An effective stress model for liquefaction[J]. Journal of the Geotechnical Engineering Division, 1977, 103(6): 517-533.
[18]	GAZETAS G. Seismic response of earth dams: some recent developments[J]. Soil Dynamics and Earthquake Engineering, 1987, 6(1): 2-47.

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