Evaluation of Impact Damages in Composites Based on Fusion of Ultrasonic and Optical Images with Optimized Parameters

Katunin, A.; Przystałka, P.; Wronkowicz, A.

Artykuł - szczegóły

Tytuł artykułu

Evaluation of Impact Damages in Composites Based on Fusion of Ultrasonic and Optical Images with Optimized Parameters

Autorzy

Katunin A. , Przystałka P. , Wronkowicz A.

Wybrane pełne teksty z tego czasopisma

http://www.simr.pw.edu.pl/ipbm/Instytut-Podstaw-Budowy-Maszyn/Nauka/Machine-Dynamics-Research

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Warianty tytułu

Języki publikacji

Abstrakty

Character of initiation and propagation of impact damages in polymer constructional composites does not allow for unambiguous evaluation of a structure condition basing on observation of its surface only. The developed method is based on wavelet fusion of ultrasonic and optical images with optimization of wavelet parameters, which allows for obtaining of single image with distinguishable internal and external damages. The method was tested experimentally on the composite plates after impact loading with various impact energy and different types of impactors.

Słowa kluczowe

damage assessment impact damage composites wavelet-based fusion optimization

Wydawca

Oficyna Wydawnicza Politechniki Warszawskiej

Czasopismo

Machine Dynamics Research

Rocznik

2014

Tom

Vol. 38, No. 3

Strony

33--41

Opis fizyczny

Bibliogr. 19 poz., il., tab.

Twórcy

autor

Katunin A.

andrzej.katunin@polsl.pl

Institute of Fundamentals of Machinery Design, Silesian University of Technology

autor

Przystałka P.

Institute of Fundamentals of Machinery Design, Silesian University of Technology

autor

Wronkowicz A.

Institute of Fundamentals of Machinery Design, Silesian University of Technology

Bibliografia

1. Bełzowski A., Rechul Z., Stasieńko J., 2002: Uszkodzenia udarowe w laminacie wzmocnionym tkaniną szklaną, Kompozyty, 2002, 2, 394-398.
2. Usamentiaga R., Venegas P., Guerediaga J., Vega L., López I., 2013: Feature extraction and analysis for automatic characterization of impact damage of carbon fiber composites using active thermography, NDT&E International, 2013, 123-132.
3. He Y., Tian G., Pan M., Chen D., 2014: Impact evaluation of carbon fiber reinforced plastic (CFRP) laminated using eddy current pulsed thermography, Composite Structures, 2014, 109, 1-7.
4. Meola C., Carlomagno G. M., 2014: Infrared thermography to evaluate impact damage in glass/epoxy with manufacturing defects, International Journal of Impact Engineering, 2014, 67,1-11.
5. Grammatikos S. A., Kordatos E. Z., Matikas T. E., David C., Paipetis A. S., 2014: Current injection phase thermography for low-velocity impact damage identification in composite laminates, Materials and Design, 2014, 55,429-441.
6. Katunin A., 2015: Stone impact damage identification in composite plates using modal data and quincunx wavelet analysis, Archives of Civil and Mechanical Engineering, 2015, 15, 251-261.
7. Santos M. J., Santos J. B., Amaro A. M., Neto M. A., 2013: Low velocity impact damage evaluation in fiber glass composite plates using PZT sensors, Composites: Part B, 2013, 55, 269-276.
8. Frieden J., Cugnoni J., Botsis J., Gmiir T., 2012: Low energy impact damage monitoring of composites using dynamic strain signals from FBG sensors - Part I: Impact detection and localization”, Composite Structures, 2012, 94, 438-445.
9. Tan K. T., Watanabe N., Iwahori Y., 2011: X-ray radiography and micro-computed tomography examination of damage characteristics in stitched composites subjected to impact loading, Composites: Part B, 2011, 42, 874-884.
10. Bull D. J., Spearing S. M., Sinclair I., Helfen L., 2013: Three-dimensional assessment of low-velocity impact damage in particle toughened composite laminates using microfocus X-ray computed tomography and synchrotron radiation laminography, Composites: Part A, 2013, 52, 62-69.
11. Potel C., Chotard T., de Belleval J.-F., Benzeggagh M., 1998: Characterization of composite materials by ultrasonic methods: modelization and application to impact damage, Composites: Part B, 1998, 29B, 159-169.
12. Hosur M. V., Murthy C. R. L., Ram am urthy T. S., Shet A., 1998: Estimation of impact-induced damage in CFRP laminates through ultrasonic imaging, NDT&E International, 1998, 31, 359-374.
13. Aymerich F., Meili S., 2000: Ultrasonic evaluation of matrix damage in impacted composite laminates, Composites: Part B, 2000, 31, 1-6.
14. Gros X. E., Bousigue J., Takachashi K., 1999: NDT data fusion at pixel level, NDT&E International, 1999, 32, 283-292.
15. Katunin A., Przystalka P., 2014: Structural diagnostics of composite beams using optimally selected fractional B-spline wavelets, Intelligent Systems in Technical and Medical Diagnostics, Korbicz J., Kowal M., Eds., Advances in Intelligent Systems and Computing, 2014,230, 475-486.
16. Katunin A., Przystalka P., 2014: Damage assessment in composite plates using fractional wavelet transform of modal shapes with optimized selection of spatial wavelets, Engineering Applications of Artificial Intelligence, 2014, 30, 73-85.
17. Katunin A., Sznura M., 2013: Stanowisko badawcze do kontrolowanych testów udarowych płyt kompozytowych, Aparatura Badawcza i Dydaktyczna, 2013, 18, 297-302.
18. Bochud N., Fahim A. A., Gómez A. M., Rus G., 2011: Impact damage characterization in composites using signal processing techniques, Procedia Engineering, 2011,14,169-176.
19. Piella G., 2004: New quality measure for image fusion, The 7th International Conference on Information Fusion, Stockholm 2004.

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Bibliografia

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