Impact Force Identification using the Modal Transformation Method in Collocated and Non-Collocated Cases

Authors

  • Abdul Ghaffar Abdul Rahman Faculty of Mechanical Engineering, University of Malaysia Pahang 26600 Pekan, Pahang, Malaysia
  • Khoo Shin Yee Department of Mechanical Engineering, Faculty of Engineering University of Malaya, 50603 Kuala Lumpur, Malaysia
  • Zubaidah Ismail Department of Civil Engineering, Faculty of Engineering University of Malaya, 50603 Kuala Lumpur, Malaysia
  • Kong Keen Kuan Department of Mechanical Engineering, Faculty of Engineering University of Malaya, 50603 Kuala Lumpur, Malaysia
  • Ong Zhi Chao Advanced Shock and Vibration Research Group, Applied Vibration Laboratory, Block R, Faculty of Engineering University of Malaya, Malaysia
  • Chong Wen Tong Department of Mechanical Engineering, Faculty of Engineering University of Malaya, 50603 Kuala Lumpur, Malaysia
  • Siamak Noroozi School of Design, Engineering & Computing, Bournemouth University Poole, Dorset, BH12 5BB, UK

DOI:

https://doi.org/10.15282/jmes.6.2014.23.0093

Keywords:

Frequency response function; impact force identification; modal analysis; modal transformation method; operating deflection shape analysis.

Abstract

Previous impact force identification has focused on collocated cases because noncollocated cases tend to be ill-posed. Considering the impact location is inaccessible, impact force identification using remote responses away from the impact location must be developed. This study initiates an effort to examine impact force identification for non-collocated case. A methodology utilizing operating deflection shape analysis, modal analysis and the modal transformation method (MTM) is presented to identify the unknown dynamic force. The performance of this approach is examined via experimental verification. The objective of this study is to examine the effectiveness of impact force identification by using MTM for both collocated and non-collocated cases. By measuring the response and frequency response function of the test rig, the time history of the unknown force is recovered by the force identification method where the impact location is known. The proposed method is examined at Points 1 and 15, which have satisfactory and poor curve fitting results respectively. It is found that force accuracy improves when the curve fitting result is enhanced. Experimental results show that impact force identification via MTM is applicable in both collocated and noncollocated cases, only if the curve fitting results satisfactory.

References

Adekunle, A. S., Adebiyi, K. A., & Durowoju, M. O. (2013). Impact of quench severity and hardness on aisi 4137 using eco-friendly quenchants as industrial heat treatment. Journal of Mechanical Engineering and Sciences, 4, 409-417.

Chen, C., & Yuan, F.-G. (2010). Impact source identification in finite isotropic plates using a time-reversal method: Theoretical study. Smart Materials and Structures, 19(10), 105028.

Gaskell, P., Summers, J., Thompson, H., & Savage, M. (1996). Creeping flow analyses of free surface cavity flows. Theoretical and Computational Fluid Dynamics, 8(6), 415-433.

Halvorsen, W. G., & Brown, D. L. (1977). Impulse technique for structural frequency response testing. Sound and Vibration, 11(11), 8-21.

Hundhausen, R. J., Adams, D. E., & Derriso, M. (2007). Impact loads identification in standoff metallic thermal protection system panels. Journal of intelligent material systems and structures, 18(6), 531-541.

Jamil, N., Yusoff, A. R., & Mansor, M. H. (2012). Literature review of electromagnetic actuator force generation for dynamic modal testing applications. Journal of Mechanical Engineering and Sciences, 3, 311-319.

Khoo, S., Ismail, Z., Kong, K., Ong, Z., Noroozi, S., Chong, W., & Rahman, A. (2014). Impact force identification with pseudo-inverse method on a lightweight structure for under-determined, even-determined and over-determined cases. International Journal of Impact Engineering, 63, 52-62.

Liu, G.-R., & Han, X. (2004). Computational inverse techniques in nondestructive evaluation. Florida: CRC press.

Rahman, A., Ghaffar, A., Yee, K. S., Ismail, Z., Tong, C. W., & Noroozi, S. (2014). Impact force identification by using modal transformation method for automobile test rig. Applied Mechanics and Materials, 471, 102-106.

Richardson, M. H. (2000). Modal mass, stiffness and damping. Vibrant Technology, Inc., Jamestown, CA, 1-5.

Sani, M. S. M., Noor, M. M., Zainury, M. S. M., Rejab, M. R. M., Kadirgama, K., & Rahman, M. M. (2010). Investigation on modal transient response analysis of engine crankshaft structure WIT Transactions on the Built Environment (Vol. 112, pp. 419-428).

Sani, M. S. M., Rahman, M. M., Noor, M. M., Kadirgama, K., & Izham, M. H. N. (2011). Identification of dynamics modal parameter for car chassis IOP Conference Series: Materials Science and Engineering (Vol. 17, pp. 1-8).

Uhl, T. (2007). The inverse identification problem and its technical application. Archive of Applied Mechanics, 77(5), 325-337.

Vibrant Technology Inc. (2012). Fourier spectra, auto spectra, and psds; curve fitting; mode indicator methods; curve fitting methods; curve fitting guidelines; counting the modes in a band. Estimating frequency & damping; estimating residues; saving shapes. Product Help, ME'Scope V4.0.0.99.

Yoon, J.-Y., & Singh, R. (2011). Estimation of interfacial forces in a multi-degree of freedom isolation system using a dynamic load sensing mount and quasi-linear models. Journal of Sound and Vibration, 330(18), 4429-4446.

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Published

2014-06-30

How to Cite

[1]
Abdul Ghaffar Abdul Rahman, “Impact Force Identification using the Modal Transformation Method in Collocated and Non-Collocated Cases”, J. Mech. Eng. Sci., vol. 6, no. 1, pp. 968–974, Jun. 2014.

Issue

Vol. 6 (2014): June 2014

Section

Article

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This work is licensed under a Creative Commons Attribution 4.0 International License.