[1]张磊,王运生,罗永红,等.芦山地震仁家村斜坡地震动监测[J].山地学报,2015,(03):339.
 ZHANG Lei,WANG Yunsheng,LUO Yonghong.Monitoring Result Analysis of Renjia Village Slope Ground Shock Response of Lushan Earthquake in Sichuan,China[J].Mountain Research,2015,(03):339.
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芦山地震仁家村斜坡地震动监测()
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《山地学报》[ISSN:1008-2186/CN:51-1516]

卷:
期数:
2015年03期
页码:
339
栏目:
山地灾害
出版日期:
2015-06-01

文章信息/Info

Title:
Monitoring Result Analysis of Renjia Village Slope Ground Shock Response of Lushan Earthquake in Sichuan,China
作者:
张磊;王运生;罗永红;
地质灾害防治与地质环境保护国家重点实验室/成都理工大学;
Author(s):
ZHANG LeiWANG YunshengLUO Yonghong
State Key Laboratory of Geohazard Prevention and Geoenvironment Protection(Chengdu University of Technology),Chengdu 610059,China
关键词:
芦山地震仁家村斜坡地震动应监测地形放大效应
Keywords:
Lushan earthquakeRenjia villageslope ground shock responsemonitoring resulttopography amplification effect
分类号:
P642.2
文献标志码:
A
摘要:
芦山地震次生地质灾害一个显著特点是地形放大效应。震后第二天,课题组在极震区仁家村斜坡局部孤突地带谷底基岩及斜坡中部坡折部位各放置一台地震监测仪,捕捉到一系列余震数据。数据显示,坡折(2#监测点)相对谷底监测点(1#监测点,二级阶地高程)的最大峰值加速度一般放大最大可达3.4,最小为1,说明坡折部位的地震动能量大于谷底部位。阿里亚斯强度计算显示,坡折部位阿里亚斯强度最大值为0.004 855 m/s,谷底部位阿里亚斯强度值最大为0.003 145 m/s,前者约为后者的1.5倍,阿里亚斯强度放大系数最大可达6.9。傅里叶频谱分析可知,1#监测点主频范围为4.81~22.81 Hz,2#监测点主频...
Abstract:
A illustrious phenomenon of the disaster induced by Lushan earthquake is the topography amplification effect. The research group,just in the next day after “4·20” Lushan earthquake,assigned two seismic instruments at the bottom of the valley(1# monitoring point) and the middle of the slope(2# monitoring point) respectively in the Renjia village meizoseismal area and collected a amount of data. The paper seeks to research the seismic response characteristics and topographic amplification effect through the analysis of the monitoring data. The analysis of the data indicates that the amplification coefficient of 2# monitoring point’s PGA is from 1 to 3.4,illustrating that the seismic energy of the 2# monitoring point is much more than #1 monitoring point. The computation of the Arias intensity shows that the maximum of 2# monitoring point’s Arias intensity is 0.004 855 m/s and the counterpart of 1# monitoring point is 0.003145 m/s,the former is as 1.5 times as the latter. The maximum of the Arias intensity amplification coefficient is 6.9. According to the fouriers spectrum analysis,it represents that the dominant frequency of 1# monitoring point is 4.81~22.81 Hz and that of 2# monitoring point is 3.31~20.94 Hz,which indicates that the protrusion terrain has not influence on the number of earthquake waves. By comparison with Qingchuan monitoring achievement,it has been verified that the soft covering layer amplifies the low frequency part of seismic wave and filters the high frequency part;threeside hanging mountain shows much more fierce amplification effect. Due to the monitoring data’s computation and analysis,it is concluded that,under earthquake condition,the protrusion terrain has obvious amplification effect on the ground acceleration. Therefore,the rock mass in this area is much more easier to reach the strength limitation,increasing the number and the scale of the collapse,the landslide and the crack. It is suggested that we should take full consideration of the topography amplification effect,when we choose the field and make the urban plan in the mountain areas.

参考文献/References:

[1] Ak K. Local site effects on weak and strong ground motion[J]. Tectonophysics,1933,218:93-111
[2] Bard P Y. Effects surface geology on ground motion:recent results and remaining issues [G]//Proc. 10th European Conference On Earth Quake Energy. Vienna,1994:305-323
[3] B Kennett. seismic wave propagation on stratified media[M]. New York:Cambridge University Press,1983.
[4] J H Steidl. Site response in southern California for probabilistic seismic hazard analysis [J]. Bulletin of the Seismological Society of America,2000,90(6B,Suppl.):149-S169
[5] Celebi. The effects of topography on earthquake ground motion:a review and new results[J]. Bulletin of the Seismological Society of America,1988,78:42-63
[6] Celebi. Topographic and geological amplification determined from strongmotion and aftershock records of 3 March 1985 Chile earthquake[J]. Bulletin of the Seismological Society of America,1987,77:1147-1107
[7] Luo Yonghong,Wang Yunsheng,HE Yuan,et al. Monitoring result analysis of Lengzhuguan slope ground shock response of Lushan earthquake of Sichuan,China[J]. Journal of Chengdu University of Technology:Science & Technology Edition,2013,40(3):232-241[罗永红,王运生,何源,等. “4·20”芦山地震冷竹关斜坡地震动响应监测成果分析[J]. 成都理工大学学报:科学技术版,2013,40(3):232-241]
[8] Huang Runqiu,Li Guo,Ju Nengpan. Shaking table test on strong earthquake response of stratified rock slopes[J].Chinese Journal of Rock Mechanics and Engineering,2013,32(5):865-875 [黄润秋,李果,巨能攀.层状岩体斜坡强震动力响应的振动台试验[J] 岩石力学与工程学报,2013,32(5):865-875]
[9]Dominic Assimaki,Eduardo. Kausel. Modified Topographic amplification Factors for a Single-Faced Slope due to Kinematic Soil-Structure Interaction [G]//Journal of Geotechnical and Geoenvironmental Engineering,2007:1414-1431
[10] Zhang Li,Liu Jianhua,Fu Hongyuan,et al. Analysis on dynamic stability of rock slope in Seismic Area in Sichuan Province[G]//Advances in Unsaturated Soil,Geo-Hazard,and Geo-Environmental Engineering,2011:188-194
[11] Yang Guoxiang,Ye Hailin,Wu Faquan,et al.Shaking table model test on dynamic response characteristics and failure mechanism of antidip layered rock slope[J]. Chinese Journal of Rock Mechanics and Engineering,2013,31(11):2214-2221 [杨国香,叶海林,伍法权,等.反倾层状岩质边坡动力响应特性及破坏机制振动台模型试验研究[J]. 岩石力学与工程学报,2012,31(11):2214-2221]
[12] Huang Runqiu,Li Weile. Research on development and distribution rules of geohazards induced by Wen Chuan earthquake on 12th May,2008[J]. Chinese Journal of Rock Mechanics and Engineering,2008,27(12):2585-2592[黄润秋,李为乐.“5.12”汶川大地震触发地质灾害的发育分布规律研究[J].岩石力学与工程学报,2008,27(12):2585-2592]
[13] Shi Chong,Zhou Jiawen,Ren Qiang,et al. Ran theory solution of the elevation amplification effect on a single free face slope[J]. Journal of Hohai University:Natural Science,2008,36(2):238-241 [石崇,周家文,任强,等. 单面边坡高程放大效应的射线理论解[J] .河海大学学报:自然科学版,2008,36(2):238-241]
[14] Qi Shengwen,Wu Faquan,Yan Fuzhang,et al. Rock slope dynamic response analysis[M]. Beijing:Science Press,2007.[ 祁生文,伍法权,严福章,等. 岩质边坡动力反应分析[M]. 北京:科学出版社,2007.]
[15] DT/T5416-2009,中华人民共和国电力行业标准/水工建筑物强震动安全监测技术规范[S].DT/T5416-2009,The Electric Power Industry Standard of the People's Republic of China/Specification of Strong Motion Safety Monitoring for Hydraulic Structures[S].
[16] Luo Yonghong,Wang Yunsheng. Moutain slope ground motion topography amplification effect induced by Wenchuan earthquake[J].Mountain Research,2013,31(2):200-210[ 罗永红,王运生. 汶川地震诱发山地斜坡地震动地形放大效应研究[J]. 山地学报,2013,31(2):200-210]
[17] Zhang Yumin,Li Huan,Zhu Zeqi. Study on propagation characteristics of horizontal peak acceleration in gorge site[J]. World Earthquake Engineering,2011,27(3):114-119[ 张玉敏,李幻,朱泽奇. 高山峡谷场地地震动水平峰值加速度传播特性研究[J]. 世界地震工程,2011,27(3):114-119]
[18] Luo Yonghong,Wang Yunsheng,Wang Fuhai,et al. Monitoring of slope seismic response during aftershocks of Wenchuan earthquake in Qingchuan county[J]. Mountain Research,2010,18(1):27-34[罗永红,王运生,王福海,等. 青川县桅杆梁斜坡地震动响应监测研究[J]. 山地学报,2010,18(1):27-34]

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备注/Memo

备注/Memo:
收稿日期(Received date):2014-04-04;改回日期(Accepted):2014-08-20。
基金项目(Foundation item):中国地调局项目(1212011220154;12120113009700);深切河谷强震条件下谷坡地震动响应监测研究(ZS0060)。[The research is supported by the China Geological Survey Program(1212011220154;12120113009700)and the research of the response of deep river valley brae under intense earthquake(ZS0060).]
作者简介(Biography):张 磊(1988-),男,硕士研究生,研究方向:地质灾害防治。[Zhang Lei(1988-),male,master,majoring in geological hazards.]TEL: 15828075004. E-mail: 455313682@qq.com *
通信作者(Corresponding author):王运生 [Wang Yunsheng] wangys60@163.com
更新日期/Last Update: 1900-01-01