Detecting and evaluating water ingress in horizontally oriented aviation honeycomb panels by using automated thermal nondestructive testing

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Abstract

Results of applying active thermal nondestructive testing for the detection of water ingress in horizontally oriented aviation honeycomb panels and quantitative evaluation of water content are presented. Unlike ultrasonic inspection, thermal testing allows detecting water and evaluating its quantity in the presence of air gaps between water and inspected honeycomb skin. The proposed algorithm based on using an artificial neural network has enabled estimating water content with errors under 15 % in the cases where water contacts with a honeycomb skin, as well as in presence of air gaps between skin and water.

About the authors

A. O Chulkov

National Research Tomsk Polytechnic University

Email: chulkovao@tpu.ru
Tomsk, Russia

B. I Shagdyrov

National Research Tomsk Polytechnic University

Tomsk, Russia

V. P Vavilov

National Research Tomsk Polytechnic University

Tomsk, Russia

D. Yu Kladov

National Research Tomsk Polytechnic University

Tomsk, Russia

V. I Stasevskiy

National Research Tomsk Polytechnic University

Tomsk, Russia

References

  1. https://www.aviationunion.ru/media/news/25824
  2. Ibarra-Castanedo C., Brault L., Genest M., Farley V., Maldague X.P.V. Detection and characterization of water ingress in honeycomb structures by passive and active infrared thermography using a high resolution camera / Conference: 2012 Quantitative InfraRed Thermography. 2012. doi: 10.21611/qirt.2012.278
  3. Чулков А.О., Gaverina L., Pradere C. Batsale J.-C., Вавилов В.П. Обнаружение воды в сотовых композиционных конструкциях методом терагерцовой термографии // Дефектоскопия. 2015. № 8. С. 72-76.
  4. Вавилов В.П., Нестерук Д.А. Способ тепловизионного контроля воды в сотовых панелях эксплуатируемых самолетов / Патент РФ № 2284515. 2005.
  5. Нестерук Д.А. Тепловизионный контроль воды в авиационных сотовых панелях в процессе эксплуатации самолетов / Дисс.. канд. техн. наук. Томск: Томский политехнический университет, 2005.
  6. Пань Янян. Количественная оценка влагосодержания в композиционных сотовых панелях эксплуатируемых самолётов методом инфракрасной термографии / Дисс.. канд. техн. наук. Томск: Томский политехнический университет, 2018.
  7. https://www.interfax-russia.ru/siberia/news/uchenye-tomskogo-politeha-usovershenstvovali-defektoskop-dlya-aviacii
  8. Chulkov A.O., Vavilov V.P., Shagdyrov B.I., Kladov D.Yu. Automated detection and characterization of defects in composite-metal structures by using active infrared thermography // Journal of Nondestructive Evaluation. 2023. V. 42 (1). doi: 10.1007/s10921-023-00929-x
  9. Чулков А.О., Нестерук Д.А., Вавилов В.П. Свидетельство о государственной регистрации программы для ЭВМ "THERMO_NN" №2020619186. 2020.

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