地震作用下多锚点桩加固土质边坡的抗震优化对比振动台试验研究

doi:10.13722/j.cnki.jrme.2020.0634

Abstract
Figure/Table
References (0)
Related Citation (0)

Download: PDF (4596 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract To study the distribution characteristics and spatial variations of the acceleration and dynamic soil pressure responses of slopes strengthened by multi-anchor piles under earthquake action，the optimal seismic performances of multi-anchor piles were discussed. In this paper，the regional spatial distribution characteristics along the pile elevation were obtained through the preliminary analysis of time-domain characteristics of the stability，the acceleration and the dynamic earth pressure of a multi-anchor pile slope model by large shaking table test. Then，the correlation of the damage level of the slope strengthened by multi-anchor piles was obtained by using Fourier change and statistical probability scatter matrix operation. Finally，regional differences of seismic deformation Sd were calculated by SPECTR with or without optimization of multi-anchored pile slope model. The results show that，under the action of different earthquake intensities，the slope model shows a continuous spatial deformation effect of regional damage and failure，and the spatial distributions of the acceleration and the dynamic earth pressure show an outstanding response to the unoptimized lateral amplitude of the pile structure. The acceleration lag difference along the elevation is mainly caused by the propagation stage after the main earthquake，the correlation between the seismic earth pressure and the acceleration response of each group before the pile in the same earthquake area is very weak，and the ground motion characteristic of the foreshock is not simply repeated superposition of the ground motion sequence of all levels. The shock absorbing layer with polystyrene foam(EPS plate) and multi-anchor piles with energy dissipation spring as self-coordination device of the anchor head play a buffering and energy dissipation role on the deformation of slope body under earthquake action，and the optimization effect is related to the position of the shock absorbing layer. Under the actions of low and medium strength earthquakes，the telescopic deformation of the energy-dissipating spring device of the anchor head improves the deformation coordination of the multi-anchor pile along the elevation and the seismic wave propagation characteristics of the pile. Under the action of a high-strength earthquake，the sliding surface of the pile is highly sensitive to the earthquake and EPS has plastic deformation，which increases the relative displacement value on the optimized side and is easy to cause“bulging”failure or shear failure on the sliding surface of the multi-anchor pile easily forming the seismic weak link of the multi-anchor pile. These results are helpful to provide theoretical basis for the optimal seismic design of multi-anchor piles.

Key words： slope engineering shaking table test soil-pile system seismic response acceleration response dynamic earth pressure response damage assessment

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	PAI Lifang1
	2
	WU Honggang2
	3
	4
	MA Huimin5

Cite this article:

PAI Lifang1,2,WU Honggang2, et al. Shaking table test study on seismic optimization comparisons of multi-anchor piles for strengthening soil slopes under earthquake[J]. , 2021, 40(4): 751-765.

URL:

https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2020.0634 OR https://rockmech.whrsm.ac.cn/EN/Y2021/V40/I4/751

[1] VELASCO A A，AMMON C J，LAY T. Recent large earthquakes near Cape Mendocino and in the Gorda plate：broadband source time functions，fault orientations，and rupture complexities[J]. Journal of Geophysical Research Solid Earth，1994，99(B1)：711–728.
[2] 牌立芳，吴红刚，杨涛. 高填方滑坡抗滑桩地震动力响应分析[J].中国地质灾害与防治学报，2018，29(5)：126–134.(PAI Lifang，WU Honggang，YANG Tao. Seismic dynamic response analysis of anti-slide piles in high-fill landslides[J]. Chinese Journal of Geological Hazards and Prevention，2018，29(5)：126–134.(in Chinese))
[3] CHEN Y H，WANG Y W. The analysis on the deformation predition of pile-anchor retaining structure in deep foundation pit in Kunming[J]. Applied Mechanics and Materials，2012，166–169：1 222–1 225.
[4] 任国强. 考虑地震作用的锚索抗滑桩设计方法研究[硕士学位论文][D]. 哈尔滨：中国地震局工程力学研究所，2014.(REN Guoqiang. Research on design method of anchor cable anti-slide pile considering earthquake action[M. S. Thesis][D]. Harbin：Institute of Engineering Mechanics，China Earthquake Administration，2014.(in Chinese))
[5] 秦晓睿. 预应力锚索抗滑桩加固边坡优化设计研究[硕士学位论文][D]. 北京：中国地质大学，2015.(QIN Xiaorui. Research on optimization design of slope reinforcement with prestressed anchor cable anti-slide piles[M. S. Thesis][D]. Beijing：China University of Geosciences，2015.(in Chinese))
[6] ZHANG C. Analysis of the research status and trends of anti-slide pile with prestressed anchor cable[J]. Applied Mechanics and Materials，2014，638–640：338–342.
[7] 刘小丽，张占民，周德培. 预应力锚索抗滑桩的改进计算方法[J]. 岩石力学与工程学报，2004，23(15)：2 568–2 572.(LIU Xiaoli，ZHANG Zhanmin，ZHOU Depei. Improved calculation method of prestressed anchor cable anti-slide piles[J]. Journal of Rock Mechanics and Engineering，2004，23(15)：2 568–2 572.(in Chinese))
[8] 范刚，张建经，付晓，等. 双排桩加预应力锚索加固边坡锚索轴力地震响应特性研究[J]. 岩土工程学报，2016，38(6)：1 095–1 103. (FAN Gang，ZHANG Jianjing，FU Xiao，et al. Study on the seismic response characteristics of the axial force of anchor cable reinforced by double-row piles and prestressed anchor cables[J]. Chinese Journal of Geotechnical Engineering，2016，38(6)：1 095–1 103.(in Chinese))
[9] 郑桐，刘红帅，袁晓铭，等. 锚索抗滑桩地震响应的离心振动台模型试验研究[J]. 岩石力学与工程学报，2016，35(11)：2 276–2 286. (ZHENG Tong，LIU Hongshuai，YUAN Xiaoming，et al. Centrifugal shaking table model test study on seismic response of anchor cable anti-slide piles[J]. Chinese Journal of Rock Mechanics and Engineering，2016，35(11)：2 276–2 286.(in Chinese))
[10] MARTIN G R，CHEN C Y. Response of piles due to lateral slope movement[J]. Computers and Structures，2005，(83)：588–598.
[11] 黄士奎，赵杰，刘道勇. 基于FLAC3D预应力锚杆抗滑桩支护边坡地震响应分析[J]. 地震研究，2016，39(1)：74–78.(HUANG Shikui，ZHAO Jie，LIU Daoyong. Seismic response analysis of slopes supported by anti-sliding piles with prestressed anchor rods based on FLAC3D[J]. Earthquake Research，2016，39(1)：74–78.(in Chinese))
[12] 王引生，王恭先，王祯，等. 预应力锚索抗滑桩结构优化[J]. 中国铁道科学，2007，28(5)：11–14.(WANG Yinsheng，WANG Gongxian，WANG Zhen，et al. Structural optimization of prestressed anchor anti-slide piles[J]. China Railway Science，2007，28(5)：11–14.(in Chinese))
[13] 邓安. 多锚点抗滑桩在北京戒台寺滑坡治理工程中的应用研究[硕士学位论文][D]. 北京：铁道部科学研究院，2007.(DENG An. Application study of multi-anchor anti-slide piles in Beijing Jietaisi landslide control project[M. S. Thesis][D]. Beijing：Academy of Railway Sciences，2007.(in Chinese))
[14] 王桢. 全埋式多锚点抗滑桩的发展及应用[J]. 岩土工程学，2011，33(增1)：319–324.(WANG Zhen. Development and application of fully buried multi-anchor anti-slide piles[J]. Geotechnical Engineering，2011，33(Supp.1)：319–324.(in Chinese))
[15] 艾挥. 高烈度地震区锚索抗滑桩加固边坡的应用与优化研究[硕士学位论文][D]. 兰州：兰州交通大学，2017.(AI Hui. Application and optimization of slope reinforcement with anchor cable anti-slide piles in high-intensity earthquake areas[M. S. Thesis][D]. Lanzhou：Lanzhou Jiaotong University，2017.(in Chinese))
[16] 冯帅，吴红刚，艾挥，等. 预应力锚索抗滑桩抗震优化设计与试验研究[J]. 科学技术与工程，2018，18(12)：248–255.(FENG Shuai，WU Honggang，AI Hui，et al. Seismic optimization design and experimental study of prestressed anchor cable anti-slide piles[J]. Science Technology and Engineering，2018，18(12)：248–255.(in Chinese))
[17] WU Z J，LEI T，CHEN Y J，et al. Deformation and instability characteristics of loess slope based on shaking table model test[J]. Journal of Shanghai Jiaotong University，2015，7(3)：1–17.
[18] MA N，WU H G，MA H M，et al. Examining dynamic soil pressures and the effectiveness of different pile structures inside reinforced slopes using shaking table tests[J]. Soil Dynamics and Earthquake Engineering，2019，116：293–303.
[19] DOU H，BYRNE P M. Model studies of boundary effect on dynamic soil response[J]. Canadian Geotechnical Journal，1997，34(3)：460–465.
[20] KOSTYUKOV N A. Effect of the initial density of a substance on the conditions of oblique collision of shock waves[J]. Journal of Applied Mechanics and Technical Physics，1977，18(3)：379–384.
[21] 徐炳伟. 大型复杂结构–桩–土振动台模型试验研究[博士学位论文][D]. 天津：天津大学，2010.(XU Bingwei. Shaking table model test of large-scale complex structure-pile-soil[Ph. D. Thesis][D]. Tianjin：Tianjin University，2010.(in Chinese))
[22] LIN M L，WANG K L. Seismic slope behaviour in a large-scale shaking table model test[J]. Engineering Geology，2006，86(2/3)：118–33.
[23] RAMU M，RAJA V P，THYLA P R. Establishment of Structural Similitude for Elastic Models and Validation of Scaling Laws[J]. Ksce Journal of Civil Engineering，2013，17(1)：139–144.
[24] AYRES J，MOURA R，SANTOS P，et al. Exploring similarity relations according to different contexts in mining；generalized association rules[J]. Lecture Notes in Business Information Processing，2013，141：137–152.
[25] CHE A L，YANG H K，WANG B，et al. Wave propagations through jointed rock masses and their effects on the stability of slopes[J]. Engineering Geology，2016，201：45–56.
[26] IKUO T. Seismic wave propagation in elastic soil with continuous variation of shear modulus in the vertical direction[J]. Soils and Foundations，1996，36(1)：61–72.
[27] CESCA S，GRIGOLI F. Full waveform seismological advances for microseismic monitoring[J]. Advances in Geophysics，2014，56(12)：169–228.
[28] 傅健翎. 不同结构的EPS防震包装材料特性的研究[硕士学位论文][D]. 长沙：湖南大学，1990.(FU Jianling. Research on the characteristics of EPS shock-proof packaging materials with different structures[M. S. Thesis][D]. Changsha：Hunan University，1990.(in Chinese))
[29] 潘作舟. 基于BP网络的地震预测算法分析与实现[硕士学位论文][D]. 合肥：安徽大学，2013.(PAN Zuozhou. Analysis and implementation of seismic prediction algorithm based on BP network[M. S. Thesis][D]. Hefei：Anhui University，2013.(in Chinese))
[30] BAKER J W，CORNELL C A. Correlation of response spectral values for multi component ground motions[J]. Bulletin of the Seismological Society of America，2006，96(1)：215–227.
[31] 李恒，李龙安，冯谦. 用位移反应谱研究长周期设计地震反应谱[J]. 地震工程与工程振动，2012，(4)：49–55.(LI Heng，LI Long¢an，FENG Qian. Using displacement response spectrum to study long-period design seismic response spectrum[J]. Earthquake Engineering and Engineering Vibration，2012，(4)：49–55.(in Chinese))