Determination of Crack Growth in St52 Structural Steel via Acoustic Emission Technique and Its Application in Steel Structures

Document Type : Research Article

Authors

1 PhD student/IUST

2 mechanical engineering of master of science student, iran university of science and technology

Abstract

Acoustic emission is one of the most important techniques in none-destructive test, that is able to evaluate crack growth in steel element of structure and is efficient in order to condition monitoring for deployment on in-service bridge component and these data can be used for schedule planning for maintenance of bridge structure. In the line of experiments and empirical research, samples of structural steel (St52) were used as a compact tension specimen in axial tensile fatigue test in order to study the crack growth. In this study, application of acoustic emission technique for health monitoring and determination of crack length in components of steel structure which are under axial fatigue load are investigated by using experimental test result, for this purpose correlation between acoustic emission parameters such an energy rate, count rate, and crack length and fatigue life has been studied. Finally, by using the extracted data from acoustic emission and fatigue test result, and least mean square regression analysis, the value of the constant for the relation between crack length and acoustic emission parameters have been determined.

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Main Subjects

References

[1] Ansari, F., Sensing issues in civil structural health monitoring. Vol. 10, Springer, 2005.
[2] Wenzel, H., Health monitoring of bridges, John Wiley & Sons, 2008.
[3] Rolfe, Theodore, S. and Barsom, J.M., Fracture and fatigue control in structures: Applications of fracture mechanics, ASTM International, 1977.
[4] Miller, Ronnie K., and Paul McIntire. Nondestructive Testing Handbook. Vol. 5: Acoustic Emission Testing, American Society for Nondestructive Testing, Ohio, USA, 1987.
[5] Mozahid, H., Acoustic Emission Source Characterization of Fatigue Crack Extension in Steel Bridge Material, MS Thises, Department of Civil and Environmental Engineering, University of South Carolina, Columbia, 2013.
[6] Harris, D. O., and Dunegan, H. L., Continuous monitoring of fatigue-crack growth by acoustic-emission techniques, Journal of Experimental mechanics, Vol. 14(2), pp: 71- 81, 1974.
[7]  Zachary, K., Walter, H., Steck, J., Crack Propagation Analysis Using Acoustic Emission Sensors for Structural Health Monitoring Systems, Journal of The Scientific World, Vol. 213, pp:13-17, 2013.
[8]  Masmoudi, S., Mahi, A. E., Turki, S., Fatigue behaviour and structural health monitoring by acoustic emission  of E-glass/epoxy laminates with piezoelectric implant, Journal of composite material, Vol. 108, pp: 50-58, 2016.
[9] Behnia, A., Chai, H. K., Shiotani, T., Advanced structural health monitoring of concrete structures with the aid of acoustic emission, Journal of Construction and Building Materials,Vol. 65, pp: 282-302, 2014.
[10]   Strantza, M., Hemelrijck, D. V., and et all, Acoustic emission monitoring of crack propagation in additively manufactured and conventional titanium components, Journal of Mechanics Research Communications, Vol. 84, pp:8-13, 2017.
[11]  Michalcová, L., Růžek, R., Fatigue test of an integrally stiffened panel: Prediction and crack growth monitoring using acoustic emission, Journal of Procedia Structural Integrity, Vol. 2, 2016.
[12]  Dykas, B., Harris, J., Acoustic emission characteristics of a single cylinder diesel generator at various loads and with a failing injector, Journal of Mechanical Systems and Signal Processing, Vol. 93, pp: 397-414, 2017.
[13]  Gagar, D., Foote, P., Irving, P. E., Effects of loading and sample geometry on acoustic emission generation during fatigue crack growth: Implications for structural health monitoring, Journal of Fatigue, Vol. 81, pp: 117-127, 2015.
[14]  Baram, J., and M. Rosen, Fatigue life prediction by distribution analysis of acoustic emission signals, Journal of Materials Science and Engineering, Vol. 41(1), pp: 25-30, 1979.
[15] Lindley, T. C., Palmer, I. G. and Richards, C. E., Acoustic emission monitoring of fatigue crack growth, Journal of Materials Science and Engineering, Vol. 32(1), pp: 1-15, 1978.
[16]  Choi, J., Jyi-Jiin, L., and Daniel, I. M., Analysis of acoustic emission waveforms from propagating fatigue crack, Proceedings of AIP Conference, Vol. 509(1), 2000.
[17] Yu, J., et al., Prediction of fatigue crack growth in steel bridge components using acoustic emission, Journal of Constructional Steel Research, Vol. 67(8), pp: 1254- 1260, 2011.
[18]  Roberts, T. M., and Talebzadeh, M., Fatigue life prediction based on crack propagation and acoustic emission count rates, Journal of Constructional Steel Research, Vol. 59(6), pp: 679-694, 2003.
[19] ASTM. Annual Book of ASTM Standard: section three- metals test methods and analytical procedures. ASTM International; 2006.
[20] ASTM E647 Standard Test Method for Measurement of Fatigue Crack Growth Rates, 2006.
Amirkabir Journal of Mechanical Engineering
Volume 51, Issue 5
November and December 2019
Pages 993-1004

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