Numerical Evaluation of Earthquake Effect on Cisumdawu Tunnel Stability

https://doi.org/10.22146/jag.53207

I Gde Budi Indrawan(1*), Jutika Aditya Nugraha Nugraha(2), Dwikorita Karnawati(3)

(1) Geological Engineering Departement, Universitas Gadjah Mada
(2) Geological Engineering Departement, Universitas Gadjah Mada
(3) Geological Engineering Departement, Universitas Gadjah Mada
(*) Corresponding Author

Abstract


Cisumdawu Tunnel is located approximately 3.95 km southeast of the activeLembang Fault. Earthquakes induced by movement of the the active the strike-slip fault may influence stability of the twin tunnel. This paper presents results of numerical analyses carried out to demonstrate effect of a worst-case scenario of earthquake load potentially induced by the Lembang Fault on the stability of the Cisumdawu Tunnel. Static and pseudo-static tunnel stability analyses were carried out at 11 observation stations of tunnel face mapping using RS2 finite element package (Rocscience, Inc.). In the pseudo-static analyses, a 0.48 horizontal seismic load coefficient, which was obtained from a deterministic seismic hazard analysis (DSHA) based on a 6.8 maximum magnitude of estimated earthquake sourced from the Lembang Fault using Campbell-Bozorgnia (2014) attenuation relationship, was applied to the finite element models. The numerical analysis results showed that strength factors of the rock masses around the twin tunnel were greater than unity, both under the static and earthquake loads. The forepolling zones, however, appeared to be under an overstressed condition. Reduction of rock strength factor around the tunnel roof due to application of the earthquake load occurred at all observation stations. Total displacement contours of rock masses around the twin tunnel indicated an increased rock mass displacement due to the earthquake load, as compared to that due to the static load. Under the static load, the largest displacement occurred at the tunnel inverts. The predicted roof displacements obtained from this study were in a reasonably good agreement with those obtained from the field measurements. Number of yielded elements and extend of shear and tension failure zones in the rock masses around the twin tunnel also appeared to increase due to the earthquake load. Despite slight tunnel displacement as predicted in the numerical analyses, the worst-case scenario of earthquake load potentially induced by the Lembang Fault may only cause failures of the rock masses around the Cisumdawu Tunnel. To prevent the twin tunnel displacement caused by such relatively severe earthquake loads, however, stabilizing surrounding the relatively poor ground condition may be necessary.


Keywords


Cisumdawu Tunnel - Displacement - Earthquake load – Pseudo - static analysis - Strength factor

Full Text:

PDF


References

Campbell, K.W. and Bozorgnia, Y. (2014) NGAWest2 Ground Motion Model for the Average Horizontal Components of PGA, PGV, and 5% Damped Linear Acceleration Response Spectra. Earthquake Spectra: August 2014, Vol. 30, No. 3, p. 1087-1115. Daryono, M. R. (2016) Paleoseismology Tropis Indonesia: Dengan Studi Kasus di Sesar Sumatra, Sesar Palukoro-Matano, dan Sesar Lembang. Unpublished Dissertation. Institut Teknologi Bandung. Gupta, I.D. (2002) The State of the Art in Seismic Hazard Analysis. ISET Journal of Earthquake Technology 428 (39) No. 4, p. 311-346. Halomoan, R. P. (2018) Analisis Metode Penggalian dan Kestabilan Terowongan Jalan Tol Cisumdawu (Cileunyi – Sumedang – Dawuan), Provinsi Jawa Barat. Unpublished Thesis. Universitas Gadjah Mada, Yogyakarta. Hashash, Y.M.A., Hook, J.J., Schmidt, B., and Yao, J. I-C. (2001) Seismic Design and Analysis of Under Underground Structures. Tunnelling and Underground Space Technology 16, p. 247-293. Hoek, E. (2000) Numerical Modelling for Shallow Tunnels in Weak Rock. Presented during the 5th GRC Lecture, NTU, Singapore. Hung, C.J., Monsees, J., Munfah, N., and Wisniewski, J. (2009) Technical Manual for Design and Construction of Road Tunnels. FHWA-NHI- 10-034. National Highway Institute, U.S. Department of Transportation. Jaky, J. (1944) The Coefficient of Earth Pressure at Rest. Journal of the Society of Hungarian Architects and Engineers, vol. 7, p. 355-358. Kramer, S.L. (1996) Geotechnical Earthquake Engineering. Prentice-Hall, Inc. KSO PT. Hi Way Indotek, & JO. PT. Wahana Mitra Amerta (2014) Perencanaan Teknik Terowongan Cisumdawu (Final Design). National Earthquake Research Center (2017) Peta Sumber dan Bahaya Gempa Indonesia Tahun 2017. Bandung: Puslitbang Kementerian PUPR. Nugraha, J. A. (2019) Analisis dan Mitigasi Risiko Deformasi Terowongan Sisi "L" di STA 12+684 hingga STA 12+658, Jalan Tol Cisumdawu-Jawa Barat. Unpublished Thesis. Universitas Gadjah Mada, Yogyakarta. Ruggeri, G. (2001) Sliding Safety of Existing Gravity Dams – Final Report. BSN. 2013. SNI Standar Nasional Indonesia 0068:2013. Pipa Baja untuk Konstruksi Umum. Jakarta. Umbara, R., Indrawan, I.G.B., Aldiamar, F. (2019) Numerical Evaluation of Cisumdawu Tunnel Excavation Method. Jurnal Jalan-Jembatan 36 (1), p. 54-66.



DOI: https://doi.org/10.22146/jag.53207

Article Metrics

Abstract views : 2261 | views : 2148

Refbacks

  • There are currently no refbacks.


Copyright (c) 2020 I Gde Budi Indrawan, Jutika Aditya Nugraha Nugraha, Dwikorita Karnawati

Creative Commons License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Journal of Applied Geology Indexed by:

 

Creative Commons License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.