Damage Evaluation for Concrete Bridge Deck by Means of Stress Wave Techniques
Publication: Journal of Bridge Engineering
Volume 17, Issue 6
Abstract
Different from postfailure maintenance in many perspectives, preventive maintenance of civil engineering structures is another highly crucial measure, not only for achieving efficient distribution of limited budget over existent aging infrastructures but also for maximizing their service lifespans. In the context of road bridges, their functional failure often causes serious impact on safety and logistics, which could turn out to be detrimental to the social economy. To appropriately maintain a huge number of aging infrastructures, a strategic maintenance program, facilitating both the global- and local-diagnosis approaches, that is effective in assessing early damage is of high demand. In this study, fatigue damage of concrete bridge decks, which is a common form of deterioration among bridges, was examined by sensitive nondestructive testing methods utilizing propagation of stress waves. Specifically, the fatigue damage process of concrete decks due to repeated traffic loads is visualized by means of active and passive elastic wave techniques, namely the elastic wave tomography and acoustic emission techniques. In the experiment, a full-scale concrete deck was subjected to repeatedly moving wheel load, to induce fatigue damage to the concrete. At three stages of after initial loading, after 10,000 passage and after 20,000 passages of 150-kN wheel loading, the fatigue test was suspended temporarily, and elastic waves were transmitted into the concrete to inspect interior structure with elastic waves' velocity. Applying static load with gradual increment in magnitude, acoustic emission testing was then conducted to extract characteristic acoustic emission (AE) parameters with regard to the intrinsic damage. Promising elastic wave parameters for quantifying the damage, which have been identified through experimental studies, were later verified using in situ deck specimens hewed out from an actual bridge. These experiments showed that by using sparsely arrayed AE sensors for measurement, followed by extracting AE frequency features, global investigation of the integrity of bridge decks could be carried out. Once the area of interest was identified through analysis of AE data, detailed information such as cross-sectional damage could be visualized by employing ultrasonic testing and tomographic reconstruction procedure.
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References
Aggelis, D. G., Shiotani, T., Momoki, S., and Hirama, A. (2009). “ Acoustic emission and ultrasound for damage characterization of concrete elements.” ACI Mater. J., 106(6), 509–514.
Aggelis, D. G., Tsinopoulos, S. V., and Polyzos, D. (2004). “An iterative effective medium approximation (IEMA) for wave dispersion and attenuation predictions in particulate composites, suspensions and emulsions.” J. Acoust. Soc. Am., 116(6), 3443–3452.
Grosse, C., and Ohtsu, M., eds. (2008). Acoustic emission testing: Basics for research–applications in civil engineering, Springer, Berlin.
Kobayashi, Y., Shiotani, T., Aggelis, D. G., and Shiojiri, H. (2007). “Three-dimensional seismic tomography for existing concrete structures.” Proc., 2nd Int. Operational Modal Analysis Conf., Vol. 2, Structural Vibration Solutions, Aalborg East, Denmark, 595–600.
Luo, X., Haya, H., Inaba, T., and Shiotani, T. (2006). “Seismic diagnosis of railway substructures by using secondary acoustic emission.” Soil. Dyn. Earthquake Eng., 26(12), 1101–1110.
Luo, X., Haya, H., Inaba, T., Shiotani, T., and Nakanishi, Y. (2004). “Damage evaluation of railway structures by using train-induced AE.” Construct. Build. Mater., 18(3), 215–223.
Matsui, S. (2007). Dourokyou Shouban (Deck slab on road bridge). Morikita Publishing Corp., Tokyo. (in Japanese).
Nassif, H. H., Gindy, M., and Davis, J. (2005). “Comparison of laser Doppler vibrometer with contact sensors for monitoring bridge deflection and vibration.” NDT&E Int., Vol. 38(3), 213–218.
Oh, H., Sim, J., and Meyer, C. (2003) “Experimental assessment of bridge deck panels strengthened with carbon fiber sheets.” Composites B. Eng., 34(6), 527–538.
Saadatmanesh, H., Wei, A., and Ebsnni, M. R. (1991). “RC beams strengthened with GFRP plate I: Experimental study.” J. Struct. Eng., 117(11), 3417–3433.
Satoh, T., Mitamura, H., Adachi, Y., Nishi, H., Ishikawa, H., and Matsui, S. (2007). “Fatigue durability of a reinforced concrete deck slab in a cold snowy region.” Rep. No. 4089, Civil Engineering Research Institute, 123–130.
Schläfli, M., and Bruhwiler, E. (1998). “Fatigue of existing reinforced concrete bridge deck slabs.” Eng. Struct., 20(11), 991–998.
Shigeishi, M., Colombo, S., Broughton, K. J., Rutledge, H., Batchelor, A. J., and Forde, M. C. (2001). “Acoustic emission to assess and monitor the integrity of bridges.” Construct. Build. Mater., 15(1), 35–49.
Shiotani, T., and Aggelis, D. G. (2006). “Damage quantification of aging concrete structures by means of NDT.” Proc., Structural Faults and Repair 2006 (CD-ROM), Engineering Technics Press, Edinburgh, U.K.
Shiotani, T., and Aggelis, D. G. (2008). “Evaluation of repair effect for deteriorated concrete piers of intake dam using AE activity.” J. Acoust. Emiss., 25, 69–79.
Shiotani, T., and Aggelis, D. G. (2009). “Wave propagation in cementitious material containing artificial distributed damage.” Mater. Struct., 42(3), 377–384.
Shiotani, T., Aggelis, D. G., and Makishima, O. (2009a). “Global monitoring of large concrete structures using acoustic emission and ultrasonic techniques: Case study.” J. Bridge Eng., 14(3), 188–192.
Shiotani, T., Aggelis, D. G., and Momoki, S. (2009b). “Elastic wave validation of large concrete structures repaired by means of cement grouting.” Construct. Build. Mater., 23(7), 2647–2652.
Sim, J., Sim, J. W., Oh, H. S., and Lee, K. M. (2001). “Fatigue loading effect on the strengthening concrete bridge deck specimen with carbon fiber sheet.” Proc., EASEC-8, Nanyang Technological Univ., Singapore.
Sonoda, K., and Horikawa, T. (1982). “Fatigue strength of reinforced concrete slab under moving loads.” Rep. 37, International Association for Bridge and Structural Engineering, 455–462.
Swamy, R. N., Jones, R., and Charif, A. (1989). “The effect of external plate reinforcement on the strengthening of structurally damaged RC beams.” The Struct. Engr., 67(3), 45–56.
Washer, G. A. (1998). “Developments for the non-destructive evaluation of highway bridges in the USA.” NDT Int., 31(4), 245–249.
Whitehurst, E. A. (1967). Evaluation of concrete properties from sonic tests. American Concrete Institute, Farmington Hills, MI.
Yuyama, S., Yokoyama, K., Niitani, K., Ohtsu, M., and Uomoto, T. (2007). “Detection and evaluation of failures in high-strength tendon of prestressed concrete bridges by acoustic emission.” Construct. Build. Mater., 21(3), 491–500.
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Published In
Journal of Bridge Engineering
Volume 17 • Issue 6 • November 2012
Pages: 847 - 856
Copyright
© 2012 American Society of Civil Engineers.
History
Received: May 10, 2011
Accepted: Jan 18, 2012
Published online: Jan 20, 2012
Published in print: Nov 1, 2012
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