Rock and Soil Mechanics ›› 2023, Vol. 44 ›› Issue (S1): 50-62.doi: 10.16285/j.rsm.2022.1352

• Fundamental Theroy and Experimental Research • Previous Articles     Next Articles

Dynamic response characteristics of tunnel portal slope reinforced by prestressed anchor sheet-pile wall

FENG Hai-zhou1, 2, JIANG Guan-lu1, 2, HE Zi-lei1, 2, GUO Yu-feng1, 2, HU Jin-shan3, LI Jie4, YUAN Sheng-yang1, 2   

  1. 1. Key Laboratory of High-Speed Railway Engineering, Ministry of Education, Southwest Jiaotong University, Chengdu, Sichuan 610106, China; 2. School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031; 3. China Railway First Survey and Design Institute Group Co., Ltd, Xi’an, Shaanxi 710043, China; 4. China Railway 18TH Bureau Group Corporation Limited, Tianjin, 30022, China
  • Received:2022-09-02 Accepted:2022-11-27 Online:2023-11-16 Published:2023-11-16
  • Supported by:
    The work was supported by the National Natural Science Foundation of China (N0. 51878577) and Study on Service Behavior Evolution and Control of New Reinforced Soil Retaining Walls for Highspeed Railway Based on Performance Design (No. 2022YFE0104600).

PDF (Chinese)

74

Abstract: The tunnel slope is prone to be damaged under the action of earthquakes and rainfall. It is necessary to study the dynamic response characteristics of the reinforcement structure of the tunnel portal slope. A tunnel portal slope in southwest China is experimentally studied as an example. The dynamic response and failure mode of the tunnel portal slope reinforced by prestressed anchor sheet-pile wall under earthquakes and rainfall are analyzed through shaking table test. The main conclusions include: (1) The failure process of the slope can be summarized as: tension cracks at the slope crest-shear cracks shear cracking, the foot of the slope, and overall sliding failure of the slope. Under the seismic action, the local damage occurs easily near the slope surface due to the infiltration of rainfall. The failure mode is tension-shear. (2) The peak acceleration amplification factors along the pile shaft increase significantly with the increase of peak acceleration, thus the inertial amplification effect of the structure should be considered properly. (3) The peak earth pressures behind the pile increase as the input peak acceleration becomes larger and the earth pressure changes from the S-shaped distribution to the inverted triangle distribution. When the peak acceleration is greater than 0.4 g, the axial force of anchor cable increases gradually and the tension effect is fully exerted. (4) The amplitude of Fourier spectrum of soil pressure and acceleration of pile are concentrated in the low frequency band. There is a high-frequency filtering effect of seismic wave propagation along the elevation. (5) The displacement spectrum amplitude of the pile increases as the peak acceleration becomes greater and increases larger along the pile height. The main frequency of the displacement spectrum is 1–4 Hz and the dominant frequency is 2.5 Hz, which is close to the dominant frequency of the seismic load. (6) The correlation between pile accelerations is well related and the correlations of pile acceleration, dynamic soil pressure, strain and axial force of anchor cable decrease with the increase of peak acceleration.

Key words: prestressed anchor sheet pile, tunnel portal slope, earthquake and rainfall, dynamic response, shaking table test

CLC Number: 

  • TU 473
[1] WANG Tong, LIU Xian-feng, YUAN Sheng-yang, JIANG Guan-lu, HU Jin-shan, SHAO Zhu-jie, TIAN Shi-jun. Large-scale shaking table test on the seismic response of dip and anti-dip layered fractured structural slopes [J]. Rock and Soil Mechanics, 2024, 45(2): 489-501.
[2] WANG Rui, HU Zhi-ping. Current situation and prospects of 2.5D finite element method for the analysis of dynamic response of railway subgrade [J]. Rock and Soil Mechanics, 2024, 45(1): 284-301.
[3] LI Xiao-xin, HE Chao, ZHOU Shun-hua, LI Hui, . Thin layer method for three-dimensional dynamic response of layered foundation with irregular interfaces [J]. Rock and Soil Mechanics, 2023, 44(S1): 655-668.
[4] WANG Zhi-ying, GUO Ming-zhu, ZENG Jin-yan, WANG Chen, LIU Huang. Experimental study on dynamic response of bedding rock slope with weak interlayer under earthquake [J]. Rock and Soil Mechanics, 2023, 44(9): 2566-2578.
[5] WANG Xiao-lei, LIU Li-teng, LIU Run, LIU Li-bo, DONG Lin, REN Hai. Shaking table test study on the influence of seismic history on liquefaction resistance of soils at different depths [J]. Rock and Soil Mechanics, 2023, 44(9): 2657-2666.
[6] JIA Ke-min, XU Cheng-shun, DU Xiu-li, ZHANG Xiao-ling, SONG Ji, SU Zhuo-lin, . Mechanism of liquefaction-induced lateral spreading in liquefiable inclined sites [J]. Rock and Soil Mechanics, 2023, 44(6): 1837-1848.
[7] ZHANG Shuo-cheng, CHEN Wen-hua. Dynamic response of a lined tunnel in cold regions considering anisotropic frost heave [J]. Rock and Soil Mechanics, 2023, 44(5): 1467-1476.
[8] WANG Li-yan, JI Wen-wei, TAO Yun-xiang, TANG Yue, WANG Bing-hui, CAI Xiao-guang, ZHANG Lei, . Experimental study on seismic performances of geogrid striped-reinforced waste tire-faced retaining walls [J]. Rock and Soil Mechanics, 2023, 44(4): 931-940.
[9] ZHANG Cong, FENG Zhong-ju, WANG Fu-chun, KONG Yuan-yuan, WANG Xi-qing, MA Xiao-qian, . Shaking table test of dynamic response of a single pile under different thicknesses of soft soil layers in a strong earthquake area [J]. Rock and Soil Mechanics, 2023, 44(4): 1100-1110.
[10] LIU Xin-rong, GUO Xue-yan, XU Bin, ZHOU Xiao-han, ZENG Xi, XIE Ying-kun, WANG Yan, . Investigation on dynamic cumulative damage mechanism of the dangerous rock slope including deteriorated rock mass in hydro-fluctuation belt [J]. Rock and Soil Mechanics, 2023, 44(3): 637-648.
[11] YAN Zhi-xiao, LI Yu-run, WANG Dong-sheng, WANG Yong-zhi, . Centrifugal experimental study on seismic response of bridge pile group foundation in overlaying water sandy field [J]. Rock and Soil Mechanics, 2023, 44(3): 861-872.
[12] XU Ming, YU Xiao-yue, ZHAO Yuan-ping, HU Jia-ju, ZHANG Xiao-ting. Analysis of seismic dynamic response and failure mode of bedding rock slope with laminated fractured structure [J]. Rock and Soil Mechanics, 2023, 44(2): 362-372.
[13] XIN Chun-lei, YANG Fei, FENG Wen-kai, LI Wen-hui, LIAO Jun. Shattering failure mechanism of step-like bedding rock slope under multi-stage earthquake excitations [J]. Rock and Soil Mechanics, 2023, 44(12): 3481-3494.
[14] HU Yao, LEI Hua-yang, LEI Zheng, LIU Ying-nan, . Shaking table test on seismic response of stacked tunnels under three-directional earthquake wave excitation [J]. Rock and Soil Mechanics, 2022, 43(S2): 104-116.
[15] LIU Si-hong, LI Bo-wen, LU Yang, SHEN Chao-min, FANG Bin-xin, HANG Dan, . Shaking table tests on liquefaction resistance performance of soilbag-stacked cushion [J]. Rock and Soil Mechanics, 2022, 43(S2): 183-192.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] WANG Chuan-ying, HU Pei-liang, SUN Wei-chun. Method for evaluating rock mass integrity based on borehole camera technology[J]. , 2010, 31(4): 1326 -1330 .
[2] LI Hua-ming, JIANG Guan-lu, LIU Xian-feng. Study of dynamic characteristics of saturated silty soil ground treated by CFG columns[J]. , 2010, 31(5): 1550 -1554 .
[3] WANG Yun-gang, XIONG Kai, LING Dao-sheng. Upper bound limit analysis of slope stability based on translational and rotational failure mechanism[J]. , 2010, 31(8): 2619 -2624 .
[4] LONG Zhao,ZHAO Ming-hua,ZHANG En-xiang,LIU Jun-long. A simplified method for calculating critical anchorage length of bolt[J]. , 2010, 31(9): 2991 -2994 .
[5] SHI Dan-da, ZHOU Jian, JIA Min-cai, YANG Yong-xiang. Back analysis of parameters and long-term settlement prediction of harbor soft ground considering its creep behavior[J]. , 2009, 30(3): 746 -750 .
[6] DING Zhou-xiang,QIU Yu-liang,LI Tao. Spatial asymmetry of excess pore pressure during nonlinear consolidation with two-way drainage[J]. , 2012, 33(6): 1829 -1838 .
[7] TIAN Kan-liang , ZHANG Hui-li , MA Jun . Test study of loess structure based on static strength conditions[J]. , 2012, 33(7): 1993 -1999 .
[8] FEI Kang ,WANG Jun-jun ,CHEN Yi . A simplified method for analyzing soil arching effect in pile-supported embankments[J]. , 2012, 33(8): 2408 -2414 .
[9] FU Hua, HAN Hua-qiang, LING Hua. Effect of grading scale method on results of laboratory tests on rockfill materials[J]. , 2012, 33(9): 2645 -2649 .
[10] WANG Xue-bin, WU Xiao-lin, PAN Yi-shan, ZHANG Chun-ye. Evolution of stress and strain in surrounding rock of a circular tunnel based on a grain-interface-matrix model[J]. , 2012, 33(S2): 314 -320 .
Copyright © Rock and Soil Mechanics, All Rights Reserved.
Tel: 027-87198484, 87199252, 87199253, 87198752 E-mail: ytlx@whrsm.ac.cn
Powered by Beijing Magtech Co. Ltd