Publications and Presentations

Project presentation: Slides are here

Publications: 

2024-2025

• A. Tempelis, L. Mishnaevsky Jr., Coating material loss and surface roughening due to leading edge erosion of wind turbine blades: Probabilistic analysis, Wear, 566–567, 2025, 205755
• L. Mishnaevsky, Jr., A. Tempelis, Y. Belahurau, N.F.-J. Johansen, Microplastic emission from eroding wind turbine blades: Preliminary estimations of volume, Energies 2024, 17(24)
• A.  Varshney , D. Paul, P. Mahajan, L. Mishnaevsky Jr., Cure-induced residual stresses and viscoelastic effects in repaired wind turbine blades: Analytical-numerical investigation Composites Part C, Vol. 15, 2024, 100521
• Y. Chen, J. Beauson, A.B. Abrahamsen, L.  Mishnaevsky Jr., Multifield computational model of chemical recycling of polymer composites: Temperature effects on solvolysis efficiency and energy consumption, J Cleaner Production, 2025, 145313
• Y. Sun, L. Mishnaevsky Jr. Healable polymer blends for structural applications: Computational analysis of damage and healing mechanisms, International Journal of Mechanical Sciences, Vol. 287, 2025, 109938

2023

• Y. Chen and L. Mishnaevsky Jr. Modeling the solvolysis of composite materials of wind turbine blades, Advanced Engineering Materials, https://doi.org/10.1002/adem.202302150
• Q. M. Ansari, F. Sánchez, L.Mishnaevsky Jr., T.r M. Young, Evaluation of offshore wind turbine blades coating thickness effect on leading edge protection system subject to rain erosion, Renewable Energy, https://doi.org/10.1016/j.renene.2024.120378
• N. Kuthe, L. Mishnaevsky Jr., P.  Mahajan, & Ahmad, S., Potential of development of anti-erosion graphene-reinforced coatings for wind turbine blades, 2024, Dynamic Behavior of Soft and Hard Materials: Proceedings of 13th International Symposium on Plasticity and Impact Mechanics 2022. Velmurugan, R., Balaganesan, G., Kakur, N. & Kanny, K. (eds.). Springer, Vol. 3. p. 109-114 6 p.
• L. Mishnaevsky Jr., M. Jafarpour, J. Krüger, S.N. Gorb, A new concept of sustainable wind turbine blades: Bio-inspired design with engineered adhesives, Biomimetics 2023, 8(6), 448
• L. Mishnaevsky Jr., How to repair the next generation of wind turbine blades, Energies 2023, 16(23), 7694
• L. Mishnaevsky Jr.,Recycling of wind turbine blades: Recent developments, Current Opinion in Green and Sustainable Chemistry, Vol. 39, 2023, 100746
• L. Mishnaevsky Jr. et al, Recent developments in the protection of wind turbine blades against leading edge erosion: Materials solutions and predictive modelling, Renewable Energy, 2023
• A. Tempelis, L. Mishnaevsky Jr, Surface roughness evolution of wind turbine blade subject to rain erosion, Materials and Design, 231, 2023, 112011
• S.M. Pathak et al,  Development of cellulose-reinforced polyurethane coatings: A novel eco-friendly approach for wind turbine blade protection, Energies 2023, 16(4), 1730

2022

• L. Mishnaevsky Jr., Root causes and mechanisms of failure of wind turbine blades: Overview, Materials, 2022, 15(9), 2959
• L.Mishnaevsky Jr., B.Bendixen, P.Mahajan, S.Fæster, N.F. Johansen, D.Paul and A. Fraisse, Repair of wind turbine blades: Costs and quality, 2022 J. Phys.: Conf. Ser. 2265 032032
• D. Paul, A. Varshney, P.Mahajan, L. Mishnaevsky Jr., Post-repair residual stresses and microstructural defects in wind turbine blades: Computational modelling,  Int J Adhesion and Adhesives, 2023, Vol. 123, 103356
• L. Mishnaevsky Jr. Repair of wind turbine blades: Technologies, modelling, costs, WindTech International, 05 May 2022
• S.M. Pathak et al, Solid particle erosion performances of ceramic nanoparticles reinforced water-based polyurethane coatings for wind turbine application, Ceramics International ,Vol.48, No 23, Part B,  2022, pp.  35788-35798
• N. Kuthe et al, Engineered anti-erosion coating for wind turbine blade protection: Computational analysis, Materials Today Communications, Vol.31, 2022, 103362

2020-2021

• L. Mishnaevsky Jr., Sustainable end-of-life management of wind turbine blades. Materials 2021, 14, 1124
• L. Mishnaevsky Jr., Current challenges of wind energy development: Materials science aspects, Physical Mesomechanics, 2021, Vol. 24, No. 5, pp. 533–540 

• L. Mischnaewski III, L. Mishnaevsky Jr., Structural repair of wind turbine blades:  Computational model Wind Energy, DOI: 10.1002/we.2575 

• M. McGugan and L. Mishnaevsky Jr. Damage mechanism based approach to the structural health monitoring of wind turbine blades, Coatings 2020, 10(12), 1223

• L. Mishnaevsky Jr., K. Thomsen, Costs of repair of wind turbine blades: Influence of technology aspects, Wind Energy, 2020, 23 (12) 2247-2255

• L. Mishnaevsky Jr., Wind turbine blade waste problem and possible solutions, New Materials, October 2020, DOI: 10.13140/RG.2.2.29576.65286

Video: Repair of Wind Turbine Blades, Experiences and Approaches. Collection of video materials 

1. Basics of Composite Repair, https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=f63f9d60-9e1a-4da7-a6aa-b1ee0055d7c4

2. Wind turine blades: Design, manufacturing and typical damage mechanisms, https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=eec6a74c-7abb-42ff-871b-b1ee006151f2

3. Wind turbine blade repair and life extension. Presentatation at DTU Wind, 2022, https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=9261bb75-f6c4-44a6-82d0-b1ee0057a6e1

4. Wind Blade Waste Problem and Recycling, https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=a5dae8aa-e075-4cc4-9b64-b1ee00667ac9

5. Presentations at the 4^th International  Symposia on Leading Edge Erosion of Wind Turbine Blades, 7-9.2.2023, Roskilde, DK

• Day 1: https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=523cbd21-6d57-4664-bcfe-afa20154347d
• Day 2 morning: https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=d4b27705-eb83-4288-b116-afa4007b8926
• Day 2 afternoon: https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=6e40e387-f40f-47fe-a95a-afa500b67be1&start=0 (last part was not recorded)
• Day 3: https://panopto.dtu.dk/Panopto/Pages/Viewer.aspx?id=a99b2eda-c89a-41e8-90a2-afa4016de942

• Some other youtube video:here.