Non-Destructive Testing and Structural Health Monitoring Methods for Additive Manufactured Polymers

Magdalena Mieloszyk is an associate professor at the Institute of Fluid-Flow Machinery of the Polish Academy of Sciences (IMP PAN), where she has been since 2006, earning her PhD in Mechanics in 2011 and DSc in 2019 from the same institute. She collaborates with various scientific institutions, including Kaunas University of Technology in Lithuania on additive manufacturing composites with embedded FBG sensors, Aarhus University in Denmark on thin metamaterials for lightweight structures, and Hohai University and Hong Kong Polytechnic University in China on 3D Laser Scanning Vibrometers. Additional collaborations include research on fibre optic sensors with the Institutul National de Fizica Laserilor, Plasmei si Radiatiilor in Romania, THz spectrometry with the University of Arizona, and structural analysis of sailing vessels and helicopters with Gdynia Maritime University and the Air Force Institute of Technology in Warsaw. Mieloszyk participates in 15 national and 8 international projects, leading one international and three national scientific projects as well as two educational projects. She is a co-author of a monograph, eight chapters in monographs, 35 international journal papers, and 42 international conference presentations, with an h-index of 17/15/15 in Google Scholar, WoS, and Scopus, respectively. Her research interests include structural health monitoring and non-destructive testing methods, applications of fibre optic sensors (particularly fibre Bragg grating sensors) for monitoring both metallic and composite structures, THz spectroscopy for damage detection, infrared thermography, signal processing algorithms for damage analysis, and additive manufacturing of polymers and fibre-reinforced composites. Michal K. Budzik is an associate professor in the Department of Mechanical and Production Engineering at Aarhus University, where he has been since 2012, after obtaining his PhD in Material Engineering from Gdańsk University of Technology in Poland in 2010. He has worked for the LEGO Group in Billund, Denmark, in Materials R&D during 2022-2023 and was a visiting professor at the University of Pennsylvania in 2021. Prior to his current role, he was employed at the Institute for Engineering and Materials, CNRS in Bordeaux, France, from 2010 to 2012. Budzik collaborates with various scientific institutions, including the Institute of Fluid-Flow Machinery of the Polish Academy of Sciences on thin metamaterials for lightweight structures, the University of Edinburgh on the failure of 3D-printed composites, the University of Pennsylvania on the influence of material architecture on fracture process zones, Vestas Aircoil in Denmark on hybrid woven composites with fiber-matrix debonding, Delft University of Technology on multi-material adhesive joints, and the University of Bordeaux on adhesion issues. He is involved in three European projects (CERTBOND, HISTRATE, Indestruct) and has published over 60 research articles, with an h-index of 20/17/17 in Google Scholar, WoS, and Scopus, respectively. His scientific interests primarily include mechanics of composites, architected materials, adhesion, and fracture mechanics.

1. Additive manufacturing methods for polymers and fiber reinforcement polymers
2. Non-destructive testing and Structural Health Monitoring methods for polymers
3. Natural fibers reinforcement in Additive Manufacturing of Polymers
4. Modified fused deposition of Polymers
5. Selective laser sintering of Polymers
6. Additive Manufactured Structural metamaterials
7. Piezoelectric Sensors for additive manufactured polymers
8. Mechanical behavior of additive manufactured biopolymers and fiber reinforced polymers
9. THz spectroscopy – non-destructive testing method for additive manufactured polymers
10. Micro Computer Tomography for AM structures
11. Fiber optic techniques – structural health monitoring method for additive manufactured polymers
12. Vibration based methods - non-contact measurements using laser Doppler vibrometer for additive manufactured polymers
13. Guided wave propagation-based methods for and electromechanical impedance of additive manufactured polymers
14. Fracture mechanism of AM structures