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Pieczonka Łukasz, dr hab. inż., prof. AGH

WIMiR-krm Katedra Robotyki i Mechatroniki

Wydział Inżynierii Mechanicznej i Robotyki

inżynieria mechaniczna
100
0
lpiecz@agh.edu.pl
Habilitacja
Nieklasyczne metody detekcji i obrazowania uszkodzeń w materiałach konstrukcyjnych
Wydział:
AGH Wydział Inżynierii Mechanicznej i Robotyki
Dziedzina:
nauki techniczne
Data uchwały Rady Wydziału:
14.12.2018
Stopień naukowy:
dr hab. nauk technicznych
Dyscyplina:
mechanika
Słowa kluczowe:
metody detekcji; metody obrazowania; uszkodzenia w materiałach konstrukcyjnych
Uwagi:
Rozprawę habilitacyjną stanowi cykl 19 publikacji: [1] Pieczonka Ł., [et al.] (2016). Nonlinear vibroacoustic wave modulations for structural damage detection: an overview. Optical Engineering vol. 55 iss. 1, s. 011005-1-011005-9 ; [2] Pieczonka, Ł., [et al.] (2014). Impact damage detection in light composite sandwich panels using piezo-based nonlinear vibro-acoustic modulations. Smart Materials and Structures vol. 23 iss. 10, s. 105021-1-105021-11 ; [3] Pieczonka Ł., [et al.] (2018). Damage imaging in composites using nonlinear vibro-acoustic wave modulations. Structural Control and Health Monitoring vol. 25 iss. 2 art. no. e2063, s. 1-13 ; [4] Pieczonka Ł., [et al.] (2015). Damage imaging in nonlinear vibro-acoustic modulation tests. W: Health monitoring of structural and biological systems, San Diego, California, United States, March 9-12, 2015. Ed. T. Kundu. Bellingham: SPIE, s. 94380E-1-94380E-7. Proceedings of SPIE, 9438 ; [5] Klepka A., [et al.] (2014). Impact damage detection in laminated composites by non-linear vibro-acoustic wave modulations. Composites. Part B, Engineering vol. 65 spec. iss., s. 99-108 ; [6] Pieczonka Ł., [et al.] (2013). Investigation of nonlinear vibro-acoustic wave modulation mechanisms in composite laminates. Key Engineering Materials vols. 569-570, s. 96-102 ; [7] Pieczonka Ł., [et al.] (2013). Analysis of vibro-acoustic modulations in nonlinear acoustics used for impact damage detection – numerical and experimental study. Key Engineering Materials vol. 558, s. 341-348 ; [8] Klepka, A., [et al.] (2013). Application of local defect resonance method to structural damage detection. W: Structural health monitoring 2013, a roadmap to intelligent structures, proceedings of the 9th international workshop on Structural Health Monitoring, Stanford, September 10-12, 2013, Vol. 1. Ed. F. Chang. Lancaster: DEStech Publications, s. 236-242 ; [9] Dziedziech K., [et al.] (2018). Efficient swept sine chirp excitation in the non-linear vibro-acoustic wave modulation technique used for damage detection. Structural Health Monitoring vol. 17 iss. 3, s. 565–576 ; [10] Klepka A., [et al.] (2016). Wideband excitation in nonlinear vibro-acoustic modulation for damage detection. W: Health monitoring of structural and biological systems, Las Vegas, United States, 20-24 March 2016. Ed. T. Kundu. Bellingham: SPIE, s. 980513-1-980513-7. Proceedings of SPIE, 9805 ; [11] Dao P. B., [et al.] (2017). Impact damage detection in smart composites using nonlinear acoustics-cointegration analysis for removal of undesired load effect. Smart Materials and Structures vol. 26 no. 3 art. no. 035012, s. 1-14 ; [12] Trojniar T., [et al.] (2014). Fatigue crack detection using nonlinear vibro-acoustic cross-modulations based on the Luxemburg-Gorky effect. W: Health monitoring of structural and biological systems, 10-13 March 2014, San Diego, California, USA. Ed. T. Kundu. Bellingham: SPIE, s. 90641F-1-90641F-10. Proceedings of SPIE, 9064 ; [13] Le Bas, P. Y., [et al.] (2015). Damage imaging in a laminated composite using an air-coupled time reversal mirror. Applied Physics Letters vol. 107 iss. 18 art. no. 184102, s. 184102-1-184102-4 ; [14] Anderson B. E., [et al.] (2015). Ultrasonic radiation from wedges of cubic profile: experimental results. Ultrasonics vol. 63, s. 141-146 ; [15] Anderson B. E., [et al.] (2017). Stress corrosion crack depth investigation using the time reversed elastic nonlinearity diagnostic. Journal of the Acoustical Society of America vol. 141 iss. 1, s. EL76-EL81 ; [16] Porcu M. C., [et al.] (2017). Assessing the scaling subtraction method for impact damage detection in composite plates. Journal of Nondestructive Evaluation vol. 36 iss. 2 art. no. 33, s. 1-16 ; [17] Frau A., [et al.] (2015). Analysis of elastic nonlinearity for impact damage detection in composite laminates. Journal of Physics : Condensed Matter vol. 628, s. 012103-1-012103-8 ; [18] Dziedziech K., [et al.] (2016). Enhanced nonlinear crack-wave interactions for structural damage detection based on guided ultrasonic waves. Structural Control and Health Monitoring vol. 23 iss. 8, s. 1108-1120 ; [19] Klepka A., [et al.] (2015). Triple correlation for detection of damage-related nonlinearities in composite structures. Nonlinear Dynamics vol. 81 iss. 1-2, s. 453-468.