Research on the classification of life-cycle safety monitoring levels of subsea tunnels

• Autorzy: Lu J. , Xue X.
• Języki publikacji: EN

Abstrakty

EN

As a traffic engineering project across straits or gulfs, subsea tunnel is one of the oceaneering with great construction difficulties, and the key to the success of subsea tunnel engineering lies in timely and accurate assessment of the structure safety of subsea tunnel engineering construction and life-cycle. Xiang’an Xiamen subsea tunnel is China’s first subsea tunnel which crosses complex formation conditions, engineering accidents such as collapse, sudden inflow of water or mud might occur during tunnel construction and operation. Therefore, the concept of subsea tunnel life-cycle monitoring is proposed aiming at the particularity of subsea tunnels. The variation forms of subsea tunnel mainly include large deformation, collapse, primary support cracking, water leakage, water pressure increase, steel arch corrosion, concrete corrosion, longitudinal differential settlement, etc., and classification of the life-cycle safety monitoring levels of the subsea tunnel is conducted based on risk assessment theory and risk level management benchmark to determine the possible variation forms in the monitoring level segments. The research results will provide reference for the subsea tunnel life-cycle monitoring, disaster warning as well as risk management under construction or to be built at home and abroad

• Wydawca: -
• Czasopismo: Polish Maritime Research
• Rocznik: 2017
• Tom: 24
• Numer: Special Issue S2
• Opis fizyczny: p.125-132,fig.,ref.

Twórcy

autor

Lu J.

• State Key Laboratory of Geohazard Prevention and Geoenvironment Protection, Chengdu University of Technology, Sichuan Chengdu, 610059, China

autor

Xue X.

• State Key Laboratory of Geohazard Prevention and Geoenvironment Protection, Chengdu University of Technology, Sichuan Chengdu, 610059, China

Bibliografia

• 1. American Institute of Architects.: Life Cycle Cost Analysis: A Guide for Architects. The USA: American Library Association, 1977.
• 2. Cheung, M. S., Naumoski, N.: The first smart long-span bridge in Canada-health monitoring of the Confederation Bridge. In: Mufti AA, editor.: Proceedings of the 1st international work-shop on structural health monitoring of innovative civil engineering structures. Winnipeg: ISIS Canada Corporation, pp. 31–44, 2002.
• 3. Frangopol, D. M.: Life-cycle cost analysis for bridge, Bridge Safety and Reliability. ASCE Reston: VA, pp. 210-236, 1999.
• 4. Flanagan, R.: Life Cycle Costing – the Issues Involved. Proceeding of Third International Symposium on Building Economics, Ottawa, Paper A 1, 1984.
• 5. A.S. Rakhra.: Buildings and Life-Cycle Costing. Canadian Building Digests-212, Originally published July, 1980.
• 6. Lee, Y. J., Chang, L. M.: Rehabilitation decision analysis and life-cycle costing of the infrastructure system.Construction Research, no. 82, pp. 1-6, 2003.
• 7. Andersen, E. Y., Pedersen, L.: Structural monitoring of the Great Belt East Bridge. In: Krokebogr J, editor. Strait crossings 94. Rotterdam: Balkema, pp. 189–95, 1994.
• 8. Fujino, Y., Abe, M. .: Structural health monitoring-current status and future. In: Boller C, Staszewski WJ, editors. Proceedings of the 2nd European workshop on structural health monitoring. Lancaster (PA): DEStech, pp. 3-10, 2004.
• 9. Myrvoll, F., Aarnes, K. A., Larssen, R. M.: Full scale measurements for design verification of bridges. In: Proceedings of the 18th international modal analytical conference. Bethel (CT): Society for Experimental Mechanics, pp. 827–35, 2000.
• 10. Wu, Z. S.: Structural health monitoring and intelligent infrastructures in Japan. In: Wu ZS, Abe M, editors.: Structural health monitoring and intelligent infrastructure. Lisse: Balkema, pp. 153–67, 2003.
• 11. Wang, M. L.: State-of-the-art applications in health monitoring. In: Invited presentation to workshop on basics of structural health monitoring and optical sensing technologies in civil engineering. Taiwan: National Central University, pp. 13-4, 2004.
• 12. Cheung, M. S., Tadros, G. S., Brown, T., Dilge, W. H., Ghali, A., Lau, D. T.: Field monitoring and research on performance of the Confederation Bridge. Canadian Journal of Civil Engineering, Vol. 24, no. 6, pp. 951-62, 1997.
• 13. Barrish Jr R. A, Grimmelsman K. A, Aktan A. E., Instrumented monitoring of the Commodore Barry Bridge. In: Aktan AE, Gosselin SR, editors. Nondestructive evaluation of highways, utilities, and pipelines IV. Bellingham (WA): The International Society for Optical Engineering, pp. 112–26, 2000.
• 14. Sumitro, S., Matsui, Y., Kono, M., Okamoto, T.: Long span bridge health monitoring system in Japan. In: Chase SB, Aktan AE, editors. Health monitoring and management of civil in frastructure systems. Bellingham (WA): The International Society for Optical Engineering, pp. 517-24, 2001. Kim, S., Chang, S. P., Lee, J.: Autonomous on-line health monitoring system for a cable-stayed bridge. In: Balageas DL, editor. Proceedings of the 1st European workshop on structural health monitoring. Lancaster (PA): DEStech, pp. 1254-61, 2002.
• 15. Lau, C. K., Mak, W. P. N, Wong, K. Y., Chan, W. Y. K., Man, K. L. D.: Structural health monitoring of three cablesupported bridges in Hong Kong. In: Chang FK, editor. Structural health monitoring. Lancaster (PA): Technomic, pp. 450–60, 1999.
• 16. He, X. H., Chen, Z. Q., Huang, F. L.: Preliminary studies on safety monitoring and state assessment for Nanjing Yangtse River Bridge. Journal of vibration and shock, Vol. 22, no. 1, pp.75-78, 2003.
• 17. Su, M. B, Du, Y. L., Sun, B.C., Chen, B. P.: Study on the long-term health monitoring and alarming system for the Wuhu Yangtze River Bridge. Journal of the China Railway Society, Vol. 29, no. 2, pp. 71-76, 2007.
• 18. A Code of Practice for Risk Management of Tunnel Works, Prepared by the International Tunnelling Insurance Group in Association with Munich Re Group, 2005

Identyfikatory

DOI

10.1515/pomr-2017-0074