高烈度地震区高路堤桩板墙的动力响应研究

摘要
图/表
参考文献
相关文章 (6)

全文: PDF (762 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要

研究目的：玉蒙铁路位于云南省境内，地质环境错综复杂并且活跃的新构造运动使得该区域地震多发。对于玉蒙铁路陡坡高路堤工点，设计采用路堤桩板式挡土墙支挡结构加固。为评价路堤桩板结构的抗震性能，研究支挡结构在地震动荷载作用下的稳定、沉降和变形，进行室内振动台模型试验，分析路堤桩板式挡土墙在不同地震加速度作用的动力响应，研究支挡结构的抗震可靠性，并与现行的设计计算方法进行对比分析。

研究结论：(1)桩板式挡土墙的水平位移、桩身弯矩、挡土板的土压力随加速度增大而增大；（2)当地震烈度大于等于8度时，试验得到的桩身弯矩和挡土板土压力均较目前规范的拟静力法的计算设计值大，说明地震烈度小于等于7度时，可以按照传统的拟静力法进行设计，而当烈度大于等于8度时，则应该适当增大结构的安全系数；（3）该研究成果已成功应用于广大新双线铁路等高烈度地震区的路堤支挡加固工程中。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

关键词 ：地震, 路堤, 桩板墙, 高烈度, 振动台

Abstract：Abstract：Research purposes：Yuxi-Mengzi Railway located in Yunnan province belongs to south extension of Qinghai-〖JP〗Tibet Plateau, where as the geological environment is complicated there is active neotectonics, earthquake strikes frequently in this region. The high-slope embankment on Yuxi-Mengzi Railway is strengthened by pile-plank wall in the design. For the seismic performance evaluation of pile-plank wall, the vibrating table test was conducted to study the stability, settlement and displacement of pile-plank wall of retaining structure under the seismic load and analyze dynamic response of pile-plank wall under different seismic acceleration. The anti-seismic reliability of the retaining structure is researched, compared and analyzed with the current design and calculation method.
Research conclusions：（1）The horizontal displacement of pile-plank wall , moment of pile body and soil pressure of retaining plate increases with increase of the seismic acceleration. （2）When the seismic intensity is equal to or more than 8 degrees, for the moment of pile body and soil pressure of retaining plate, the test value are more than design value calculated by quasi-static method. This means when the earthquake intensity is less than or equal to 7 degrees, the structure can be designed according to the traditional quasi-static method and when the intensity is equal to or more than 8 degrees, the structure′s safety factor should be appropriately increased.
(3) The results have been successfully applied to the embankment retaining reinforcement engineering of many new double-track railways in high-intensity seismic area.


Key words： Key words: earthquake embankment pile-plank wall high intensity vibrating table

作者简介: 蒋楚生，1964年出生，男，教授级高级工程师。

引用本文:

蒋楚生1 李庆海1 曹新文2. 高烈度地震区高路堤桩板墙的动力响应研究[J]. 铁道工程学报, 2015, 32(3): 21-.
JIANG Chu-sheng1，LI Qing-hai1，CAO Xin-wen2.

Research on the Dynamic Response of Pile-plank Wall for High Embankmentin High Intensity Seismic Area

. 铁道工程学报, 2015, 32(3): 21-.

链接本文:

http://tdgcxb.crec.cn/CN/ 或 http://tdgcxb.crec.cn/CN/Y2015/V32/I3/21

［1］李海光. 新型支挡结构设计与工程实例［M］. 北京：人民交通出版社, 2004.
Li Haiguang. Design and Project Case of New Retaining Structure［M］. Beijing:China Communications Press, 2004.
［2］蒋忠信, 蒋良潍. 南昆铁路支挡结构主动土压力分布图式［J］. 岩石力学与工程学报, 2005(6):1035-1040.
Jiang Zhongxin, Jiang Liangwei. Distribution Map Forms of Active Earth Pressue on Retaining Structures in Nanning-Kunming Railway［J］. Chinese Journal of Rock Mechanics and Engineering, 2005(6):1035-1040.
［3］蒋楚生. 路肩(堤)式预应力锚索桩板墙柔性支挡结构的土压力分布新探索［J］. 铁道工程学报,2007（4）:24-28.

Jiang Chusheng. A New Exploration on the Earth Pressure Distribution on a Flexible Retaining Structure of Cable-anchors Tied Pile-slab Wall on Embankment′s Shoulder or Slope［J］. Journal of Railway Engineering Society, 2007（4）:24-28.
［4］TB 10025—2006，铁路路基支挡结构设计规范［S］.
TB 10025—2006，Code for Design on Retaining Structures of Railway Subgrade［S］.
［5］刘国楠，胡荣华，潘效鸿,等. 衡重式桩板挡墙上墙土压力模型试验研究［J］. 岩土力学, 2011(S2):94-98.
Liu Guonan, Hu Ronghua, Pan Xiaohong, etc. Model Tests on Earth Pressure of Upper Part Wall of Sheet Pile Wall with Relieving Platform［J］. Rock and Soil Mechanics, 2011(S2):94-98.
［6］GB 50111—2006，铁路工程抗震设计规范（2009年版）［S］. 
GB 50111—2006，Code for Seismic Design of Railway Engineering［S］.
［7］王燕华，程文瀼，陆飞，等. 地震模拟振动台的发展［J］. 工程抗震与加固改造, 2007(5):53-56.
Wang Yanhua, Cheng Wenrang, Lu Fei, etc. Development of the Shaking Table［J］. Earthquake Resistant Engineering and Retrofitting，2007(5):53-56.