Transverse Seismic Performance Index System of Urban Mass Transit Underground Structures

Zheng Fang Dong; Feng Li Li; Qing Mei Kong

doi:10.4028/www.scientific.net/AMM.744-746.924

Paper Titles

Seismic Performance of the Masonry Buildings with Frame at the Bottom Equipped with the New Hybrid Damper
p.905

Seismic Response Analysis of Liaocheng Guangyue Tower
p.911

Study on the Seismic Performance of the Tibetan Diaolou in Golog of Qinghai
p.915

The Dynamic Characteristics Analysis of Liaocheng Guangyue Tower
p.920

Transverse Seismic Performance Index System of Urban Mass Transit Underground Structures
p.924

Study on the Sluice Dynamic Characteristics under Concrete Cracking Condition
p.932

A Simplified Model for Stress Analysis of Tunnel Surrounding Rock with Confinement
p.939

Analysis of Pipe Settlement Based on Numerical Simulation
p.944

Comparative Analysis of Ground Settlement Caused by Two Kinds of Tunnel Excavation Method
p.948

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 744-746Transverse Seismic Performance Index System of...

Transverse Seismic Performance Index System of Urban Mass Transit Underground Structures

Abstract:

The transverse seismic performance index system of urban mass transit underground structures was presented, which included both intensity index of component and overall deformation index, in order to reasonably evaluate its damage degree under seismic excitations. Intensity index of component had two grades and limit values of two levels ware provided. Overall deformation index included story drift angle for rectangular underground structures and diameter deformation rate for shield tunnels. Performance index values of urban mass transit rectangular underground structure story drift angle ware put forward by reference to modified performance index values of ground structure story drift angle, which was based on a statistical analysis for experiment data of forty-six groups concrete-filled steel tubular frames and one hundred forty-five groups steel-reinforced concrete frames and took into account similarities and differences between surface structures and underground structures. Based on relation between tunnel diameter deformation and stress state of tunnel concrete and bolts, the diameter deformation rate was derived from the analytical solution using compatibility of deformation for a segment cross section. And the diameter deformation rate was also computed by means of incremental dynamic analysis method for different sites under various earthquakes. It is found in the study that based on two performance levels, limiting value of diameter deformation rate is obtained.

You might also be interested in these eBooks

Advances in Civil Engineering and Transportation IV

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 744-746)

Pages:

924-931

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.744-746.924

Citation:

Cite this paper

Online since:

March 2015

Authors:

Zheng Fang Dong, Feng Li Li, Qing Mei Kong*

Keywords:

Diameter Deformation Rate, Performance Index, Story Drift Angle, Urban Mass Transit Structure

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Lichu Fan and Weidong Zhuo. Seismic design for ductility of bridge (China Communications Press, China, 2001). (in Chinese).

Google Scholar

[2] Guobo Wang, Weiping Xie, Ming Sun and Weiguo Liu. Chinese Journal of Geotechnical Engineering, Vol. 33(4) (2011), p.593. (in Chinese).

Google Scholar

[3] Japan Railway Technical Research Institute. Design standard for railway structure-seismic design. (Maruzen Publishing co., LTD, Tokyo, Japan, 1999). (in Chinese).

Google Scholar

[4] T. R. Kuesel. Journal of the Structural Division, ASCE, Vol. 95(6) (1969), p.1213.

Google Scholar

[5] Shanghai Construction and Traffic Committee. Code for seismic design of subway structures. (Shanghai station of the building materials industry market management, China, 2009). (in Chinese).

Google Scholar

[6] Qunfeng Yao and Jun Sun. in: The third national conference on youth in geotechnical mechanics and engineering. (Hehai University Press, Nanjing, China, 1998). (in Chinese).

Google Scholar

[7] Lei Ai, Hongbing Liu and Jingwei Nie. Science Technology and Engineering, Vol. 12(1) (2012), p.76.

Google Scholar

[8] Zhengfang Dong. Study on tranverse seismic design methods and performance indices of underground structures of urban rail transit structures. (Tongji Universty, Shanghai, China, 2013). (in Chinese).

Google Scholar

[9] . Xiangqing Liu. Seismic analysis methods and experimental study of underground structures of urban rail transit structures. (Tsinghua Universty, Beijing, China, 2008). (in Chinese).

Google Scholar

[10] S. Nishiyama, K. Muroya, H. Haya, S. QR of RTRI, Vol. 40(3) (1999), p.158.

Google Scholar

[11] Lijiang Gu and Dongmei Zhang. in: Proceedings of the 8th National Civil Engineering Forum for Graduate Stuednts. (Hanzhou, China, 2010). (in Chinese).

Google Scholar

[12] Yongxiang Shi and Wusheng Zhao. Modern Tunnelling Technology, Vol. 50(1)(2013), p.115. (in Chinese).

Google Scholar

[13] Zhiliang Wang, Linfang Shen Guobin Liu and Ji Yao. Journal of the China Railway Society, Vol. 34(2)(2012), p.100.

Google Scholar