Thermal Effects on Curved Steel Box Girder Bridges and Their Countermeasures
Publication: Journal of Performance of Constructed Facilities
Volume 31, Issue 2
Abstract
Owing to its light self-weight, low heat capacity and large thermal expansion coefficient, the application of the curved steel box girder bridge with small and medium spans has gained popularity for the construction of urban infrastructure. However, sun exposure could easily increase the maximum temperature difference at the bottom of steel box beam by 25°C. With the effect of nonuniform temperature field and overloaded vehicles, the edge inside the curved steel box girder bridge may be separated from the remaining structure, resulting in overturning. Thus, more attention needs to be paid in order to prevent the separation. In this paper, an overturning resistance analysis of a three-span curved steel box girder bridge located in Hangzhou, China was performed. A model was proposed based on the measurement of temperature field to the steel box girder. The separating displacement due to temperature variations was predicted and verified by the measurement results. As a result, changes in supporting reactions due to the effect of the nonlinear temperature field and self-weight and offset vehicle load were determined, and the overturning stability of the bridge was analyzed via the trial and error method. The balance weight method was employed to diminish the risk of overturning of bridges. Finally, the method proposed in this paper was applied to a bridge under construction, which results in an increase in stability safety factor from 0.63 to 2.58.
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Acknowledgments
The financial support from the National Natural Science Foundation with Grant No. 51578496 and the Zhejiang Provincial Natural Science Foundation with Grant No. LZ16E080001 and LQ15E080010 of the People’s Republic of China is greatly acknowledged.
References
Chavel, B. W., and Yadlosky, J. M. (2011). “Framework for improving resilience of bridge design.”, Federal Highway Administration, Washington, DC.
De Backer, H., Outtier, A., and Van Bogaert, P. (2009). “Numerical and experimental assessment of thermal stresses in steel box girders.” Proc., 11th Nordic Steel Construction Conf., Luleå Univ. of Technology, Luleå, Sweden, 65–72.
Elbadry, M. M., and Ghali, A. (1983). “Temperature variations in concrete bridges.” J. Struct. Eng., 2355–2374.
Kang, W. J. (2000). “Analysis of solar temperature effect on reinforced concrete box girder.” Ph.D. dissertation, Hunan Univ., Changsha, China.
Kim, S. H., et al. (2009). “A study on thermal behaviour of curved steel box girder bridges considering solar radiation.” Arch. Civ. Mech. Eng., 9(3), 59–76.
Liao, M., et al. (2010). “Nonlinear finite-element analysis of critical gusset plates in the I-35W Bridge in Minnesota.” J. Struct. Eng., 59–68.
McClure, R. M., West, H. H., and Hoffman, P. C. (1984). “Observations from tests on a segmental bridge.” Transp. Res. Rec., 950, 60–67.
Mirambell, E., and Aguado, A. (1990). “Temperature and stress distributions in concrete box girder bridges.” J. Struct. Eng., 2388–2409.
Moorty, S., and Roeder, C. W. (1992). “Temperature-dependent bridge movements.” J. Struct. Eng., 1090–1105.
MRPRC (Ministry of Railways of the People’s Republic of China). (2005). “Code for design on reinforced and prestressed concrete structure of railway bridge and culvert.” Beijing.
NTSB (National Transportation Safety Board). (2007). “Highway accident report: Collapse of I-35W highway bridge Minneapolis.”, Washington, DC.
Oh, B. H., Choi, S. C., and Cha, S. W. (2006). “Temperature and relative humidity analysis in early-age concrete decks of composite bridges.” Proc., Measuring, Monitoring and Modeling Concrete Properties, Springer, Netherlands, 305–316.
Roe, A. G. (2001). “Fatigue, brittle fracture likely caused Milwaukee span failure.” Demolition, 246(2), 1–17.
Tong, M., et al. (2001). “Numerical modelling for temperature distribution in steel bridges.” Comput. Struct., 79(6), 583–593.
Tong, M., Tham, L. G., and Au, F. T. K. (2002). “Extreme thermal loading on steel bridges in tropical region.” J. Bridge Eng., 357–366.
Wang, J. F., Lin, J. P., and Fan, X. L. (2015). “Evaluation of long multi-span steel U-shaped girder during incremental launching construction.” J. Test. Eval., 43(2), 425–433.
Zhou, G. D., and Yi, T. H. (2013). “Thermal load in large-scale bridges: A state-of-the-art review.” Int. J. Distributed Sens. Networks, 1–17.
Zuk, W. (1961). “Thermal and shrinkage stresses in composite bridges.” J. Am. Concr. Inst., 58(3), 327–340.
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© 2016 American Society of Civil Engineers.
History
Received: Jan 28, 2016
Accepted: Jun 20, 2016
Published online: Jul 29, 2016
Discussion open until: Dec 29, 2016
Published in print: Apr 1, 2017
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