A Compensation Method for Environmental Influences on Passive Lamb Wave Based Impact Evaluation for CFRP

Konstantin Jonas Schubert; Axel Siegfried Herrmann

doi:10.4028/www.scientific.net/KEM.569-570.1265

Paper Titles

Assessment of Historic Structures Based on GPR, Ultrasound, and Impact-Echo Data Fusion
p.1210

Structural Health Monitoring under Varying Environmental Conditions Using Wavelets
p.1218

Damage Assessment in a Cracked Fiber-Reinforced Cantilever Beam Using Wavelet-Kurtosis Techniques
p.1226

Modelling of Piezo-Bond Structure System for Structural Health Monitoring Using EMI Technique
p.1234

Damage Detection of Shear Connectors Based on Power Spectral Density Transmissibility
p.1241

Multi-Technique Approach for the Assessment of Historical Masonry Constructions
p.1249

Application of Multiple Objective Particle Swarm Optimisation in the Design of Damaged Offshore Mooring Systems
p.1257

A Compensation Method for Environmental Influences on Passive Lamb Wave Based Impact Evaluation for CFRP
p.1265

Detection and Localisation of Structural Damage Based on the Polynomial Annihilation Edge Detection: An Experimental Verification
p.1273

HomeKey Engineering MaterialsKey Engineering Materials Vols. 569-570A Compensation Method for Environmental Influences...

A Compensation Method for Environmental Influences on Passive Lamb Wave Based Impact Evaluation for CFRP

Abstract:

One of the largest issues remaining on the way to in situ Structural Health Monitoring of composite structures using Lamb waves is the impact that non-damaging factors like temperature changes and humidity absorption have on most measurement strategies. While some of these tasks have been successfully conquered, others, especially related to slowly developing influences like humidity absorption or mechanical ageing, remain challenging. In this paper, a method to approach this problem for a Lamb-wave based passive impact detection system is presented. Passive approaches use the waves generated by the impact event itself to both localize said event and evaluate whether it was large enough to damage the structure. For this, the impacts energy has to be estimated from sensors detecting the Lamb waves. The problem provided by changing conditions within the material is that the locally measurable wave amplitude due to an impact event of a certain energy is altered if the material properties change. This might happen due to temperature changes, mechanical loads, humidity absorption, fluid loads and other factors. The main idea of the presented approach is to mix a passive and an active system. Piezoelectric elements are used to generate Lamb waves to obtain the attenuation coefficients of the material before and after hot/wet-conditioning. These coefficients are then used to estimate the impact energy from passive sensor responses. Both the approach and experimental validation performed with low velocity impacts from an impact hammer are presented to show the ability to correctly calculate impact forces after conditioning.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volumes 569-570)

Pages:

1265-1272

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.569-570.1265

Citation:

Cite this paper

Online since:

July 2013

Authors:

Konstantin Jonas Schubert, Axel Siegfried Herrmann

Keywords:

Environmental Influence, Humidity Absorption, Impact, Lamb Wave, Passive SHM

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] W. Staszewski, C. Boller, G. Tomlinson, Health Monitoring of Aerospace Structures - Smart Sensor Technologies and Signal Processing, John Wiley & Sons, Chichester, (2004).

DOI: 10.1002/0470092866

Google Scholar

[2] Z. Su, L. Ye, Identification of Damage Using Lamb Waves - From Fundamentals to Applications, Springer, Berlin, (2009).

Google Scholar

[3] V. Giurgiutiu, Structural Health Monitoring With Piezoelectric Wafer Active Sensors, Academic Press, Burlington, (2008).

Google Scholar

[4] A.J. Croxford, P.D. Wilcox, G. Konstantinidis, B. Drinkwater, Strategies for overcoming the effect of temperature on guided wave structural health monitoring, Proc. of SPIE 2007, 65321T.

DOI: 10.1117/12.719435

Google Scholar

[5] J.E. Michaels, T.E. Michaels, Detection of Structural Damage from the Local Temporal Coherence of Diffuse Ultrasonic Signals, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control 52, No. 10 (2005) 1769-1782.

DOI: 10.1109/tuffc.2005.1561631

Google Scholar

[6] T. Clarke, F. Simonetti, P. Cawley, Guided wave health monitoring of complex structures by sparse array systems: Influence of temperature changes on performance, Journal of Sound and Vibration 329 (2010) 2306-2322.

DOI: 10.1016/j.jsv.2009.01.052

Google Scholar

[7] M. Tracy, F. -K. Chang, Identifying Impacts in Composite Plates with piezoelectric Strain Sensors, Part I: Theory, Journal of Int. Mat. Sys. and Structures 9 (1998) 920-928.

DOI: 10.1177/1045389x9800901108

Google Scholar

[8] M. Calomfirescu, Lamb Waves for Structural Health Monitoring in Viscoelastic Composite Materials, Logos Verlag, Berlin, (2008).

Google Scholar

[9] M. Tracy, F. -K. Chang, Identifying Impacts in Composite Plates with piezoelectric Strain Sensors, Part II: Experiment, Journal of Int. Mat. Sys. and Structures 9 (1998) 929-937.

DOI: 10.1177/1045389x9800901109

Google Scholar

[10] D.E. Chimenti, Guided waves in plates and their use in materials characterization, Applied Mechanics Reviews 50, (1997) 247-284.

DOI: 10.1115/1.3101707

Google Scholar

[11] G. Bottai, V. Giurgiutiu, Simulation of the Lamb wave interaction between piezoelectric wafer active sensors and host structure, Proc. of SPIE's 12th International Symposium on Smart Structures and Materials (2005) paper #5765-29.

DOI: 10.1117/12.597747

Google Scholar