Dynamic Responses of Crack Welded Pipe Based on Frequency Response Function (FRF) for Fault Detection

Authors

  • Abdul Mutalib F.F. School of Mechanical Engineering, Faculty of Engineering, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Johor
  • Lim M.H. Department of Mechanical Precision Engineering Malaysia–Japan International Institute of Technology Universiti Teknologi Malaysia Jalan Sultan Yahya Petra 54100 Kuala Lumpur

Keywords:

Weldedjoints, crack welded pipe, experimental modal analysis (EMA), frequency response function, finite element analysis (FEA)

Abstract

Welding technique is one of the most important and often used methods for joining metals in industry. Welded joints are used in almost every industry depending on various applications and where the permanent joints with high strength are deemed necessary. Some of the applications are used in structural supports, automotive joints, piping industries, pressure vessels etc. Welded joints, particularly in the welded pipe structure have a complex non-linear behavior which may be due to the material’s geometry or the contacts itself at the joints. However, cracksin a structure can happen either at the interfacial contacts or in the material of the components. The cracks may change the dynamic properties of the structure such as natural frequency, mode shapes and structural performance that may lead to premature failure to the structure. Therefore, this paper presents a crack detection method using a vibration-based damage detection techniqueusing the frequency response function (FRF) data. A combination of the numerical model and physical welded pipe structure with and without cracks in pipe structure will be investigated using the experimental modal analysis (EMA). A finite element analysis (FEA) utilizing HyperMesh Version 13.0 software has been utilized to model the scheme. A validation procedure is also employed to detect the presence of cracks in the welded pipe structure based on the FRF data from the parameter values used in both the benchmarked and cracks models. The comparison of the with/without cracks welded pipe structure has revealed that the effect of the FRF between with/without cracks welded pipe structure is clearly influenced by the stiffness reduction in the crack structure.

References

Ewins D.J., 2000. Modal Testing: Theory and Practice, Research Studies Press Ltd, Lecthworth.

Zhang L., Brincker R. and Andersen P., 2010. An Overview of Operational Modal Analysis: Major Development and Issues, Mechanical Systems and Signal Processing, 24 (5), 1274-1290.

LePage W.R., 1980. Complex Variables and the Laplace Transform for Engineers, Dover Publications Inc., New York.

Schwarz B.J. and Richardson M.H., 1999. Experimental Modal Analysis, CSI Reliab. Week, Orlando, 35(1): 1–12.

Sampaio R.P.C., Maia N.M., Silva J.M.M., 1999. Damage Detection Using the Frequency Response Function Curvature Method, J. Sound Vib., 226(5): 1029–1042.

Yoon M.K., Heider D., Gillespie Jr. J.W., Ratcliffe C.P. and Crane R.M., 2009. Local Damage Detection Using a Global Fitting Method on Mode Shape Datain Notched Beams,Journal of Nondestructive Evaluation, 28: 63-74.

Bandara R.P., Chan T.H.T. and Thambiratnam D.P., 2014. Frequency Response Function Based Damage Identification Using Principal Component Analysis and Pattern Recognition Technique, Eng. Struct., 66: 116–128.

Rizos P.F., Aspragathos N. and Dimarogonas A.D., 1990. Identification of Crack Location and Magnitude in a Cantilever Beam from the Vibration Modes, Journal of Sound and Vibration, 138(3): 381-388.

Xiang J.W. and Liang M., 2011. Multiple Crack Identification Using Frequency Measurement, World Academy of Science, Engineering and Technology, 76: 311-316.

Zhang L., Brincker R.and Andersen P., 2005. An Overview of Operational Modal Analysis: Major Development and Issues, Proceedings of the 1stInternational Operational Modal Analysis Conference, IOMAC 2005.

Au S-K, Zhang F-Land Ni Y.C., 2013. Bayesian Operational Modal Analysis: Theory, Computation, Practice, Computers and Structures,126: 3-14.

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Published

2020-10-11

How to Cite

F.F., A. M., & M.H., L. (2020). Dynamic Responses of Crack Welded Pipe Based on Frequency Response Function (FRF) for Fault Detection. Jurnal Mekanikal, (43). Retrieved from https://jurnalmekanikal.utm.my/index.php/jurnalmekanikal/article/view/398

Issue

Section

Mechanical

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