Numerical Simulation of the Impact ofIce Accumulation on a Composite Wind Turbine Blades located in a Cold Climate

O. Lagdani; M. Tarfaoui; M. Nachtane; M. Trihi; H. Laaouidi

doi:10.1051/e3sconf/202122901052

All issues

Volume 229 (2021)

E3S Web Conf., 229 (2021) 01052

References

Open Access

Issue		E3S Web Conf. Volume 229, 2021 The 3^rd International Conference of Computer Science and Renewable Energies (ICCSRE’2020)


Article Number		01052
Number of page(s)		5
DOI		https://doi.org/10.1051/e3sconf/202122901052
Published online		25 January 2021

Tarfaoui, M., Rahaman Shah, Owaisur, & Nachtane, M. 2019. Design and optimization of composite offshore wind turbine blades. Journal of Energy Resources Technology. [PubMed] [Google Scholar]
Yirtici, O., & Tuncer, I. H. 2020. Aerodynamic Shape Optimization of Wind Turbine Blades to Reduce Power Losses due to Icing. [Google Scholar]
Wang, Q., Xiao, J., Zhang, T., Yang, J., & Shi, Y. 2020. A new wind turbine icing computational model based on Free Wake Lifting Line Model and Finite Area Method. [Google Scholar]
O’Leary, K., Pakrashi, V., & Kelliher, D. 2019. Optimization of composite material tower for offshore wind turbine structures. Renewable Energy. [PubMed] [Google Scholar]
M. Tarfaoui, J.Y. Pradillon, O.R. Shah. 2015. Numerical investigation of a large composite wind turbine with different spar profiles using finite-element method. La Houille Blanche, n° 5, p. 29-35 [CrossRef] [EDP Sciences] [Google Scholar]
M. Nachtane, M. Tarfaoui, D. Saifaoui, A. El Moumen. Finite element analysis of composite wind turbine blade under the critical loads. Eleven International Conference on Thermal Engineering: Theory and Applications February 25-28, 2018, Doha, Qatar. [Google Scholar]
R. Abouchoukri. 2018. Design, Fabrication, and Operation of a Small homemade Wind Turbine Blades. [Google Scholar]
Tarfaoui, M., Nachtane, M., Khadimallah, H., & Saifaoui, D. 2017. Simulation of Mechanical Behavior and Damage of a Large Composite Wind Turbine Blade under Critical Loads. Applied Composite Materials, 25(2), 237–254. [CrossRef] [Google Scholar]
M. Nachtane, M. Tarfaoui, M. Ait Mohammed, D. Saifaoui, A. El Moumen. Effects of environmental exposure on the mechanical properties of composite tidal current turbine. Renewable Energy 2020, 156, 1132-1145. [CrossRef] [Google Scholar]
Nachtane, M., Tarfaoui, M., Goda, I., & Rouway, M. 2020. A review on the technologies, design considerations and numerical models of tidal current turbines. Renewable Energy. [Google Scholar]
M. Nachtane, M. Tarfaoui, D. Saifaoui, A. El Moumen, O.H. Hassoon, H. Benyahia. 2018. Evaluation of durability of composite materials applied to renewable marine energy: Case of ducted tidal turbine. Energy Reports, Volume 4, Pages 31-40. [CrossRef] [Google Scholar]
Gemi, L. 2018. Investigation of the effect of stacking sequence on low velocity impact response and damage formation in hybrid composite pipes under internal pressure. A comparative study. Composites Part B: Engineering, 153, 217–232. [CrossRef] [Google Scholar]
Gu, J., & Chen, P. 2017. Some modifications of Hashin’s failure criteria for unidirectional composite materials. Composite Structures, 182, 143–152. [CrossRef] [Google Scholar]
K. Kodagali., 2017. Thesis, Progressive Failure Analysis of composite Materials using the Puck Failure Criteria. [Google Scholar]
Kim Martineli Souza Gonçalves. 2015. Hashin’s Failure Criteria In-Plane Stress Numerical Model Correlated to Tensile Tests. International Journal of Engineering Research and Science & Technology. [Google Scholar]
H. Boudounit, M. Tarfaoui, D. Saifaoui. 2019. Structural Design and Analysis of a 5MW Offshore Wind Turbine Blades Under Critical Aerodynamic Loads. 14th Congress of Mechanics April 16-19, 2019 (Rabat, MOROCCO). [Google Scholar]
Söker, H. 2013. Loads on wind turbine blades. Advances in Wind Turbine Blade Design and Materials, 29–58. [CrossRef] [Google Scholar]

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[1] Tarfaoui, M., Rahaman Shah, Owaisur, & Nachtane, M. 2019. Design and optimization of composite offshore wind turbine blades. Journal of Energy Resources Technology. [PubMed] [Google Scholar]

[2] Yirtici, O., & Tuncer, I. H. 2020. Aerodynamic Shape Optimization of Wind Turbine Blades to Reduce Power Losses due to Icing. [Google Scholar]

[3] Wang, Q., Xiao, J., Zhang, T., Yang, J., & Shi, Y. 2020. A new wind turbine icing computational model based on Free Wake Lifting Line Model and Finite Area Method. [Google Scholar]

[4] O’Leary, K., Pakrashi, V., & Kelliher, D. 2019. Optimization of composite material tower for offshore wind turbine structures. Renewable Energy. [PubMed] [Google Scholar]

[5] M. Tarfaoui, J.Y. Pradillon, O.R. Shah. 2015. Numerical investigation of a large composite wind turbine with different spar profiles using finite-element method. La Houille Blanche, n° 5, p. 29-35 [CrossRef] [EDP Sciences] [Google Scholar]

[6] M. Nachtane, M. Tarfaoui, D. Saifaoui, A. El Moumen. Finite element analysis of composite wind turbine blade under the critical loads. Eleven International Conference on Thermal Engineering: Theory and Applications February 25-28, 2018, Doha, Qatar. [Google Scholar]

[7] R. Abouchoukri. 2018. Design, Fabrication, and Operation of a Small homemade Wind Turbine Blades. [Google Scholar]

[8] Tarfaoui, M., Nachtane, M., Khadimallah, H., & Saifaoui, D. 2017. Simulation of Mechanical Behavior and Damage of a Large Composite Wind Turbine Blade under Critical Loads. Applied Composite Materials, 25(2), 237–254. [CrossRef] [Google Scholar]

[9] M. Nachtane, M. Tarfaoui, M. Ait Mohammed, D. Saifaoui, A. El Moumen. Effects of environmental exposure on the mechanical properties of composite tidal current turbine. Renewable Energy 2020, 156, 1132-1145. [CrossRef] [Google Scholar]

[10] Nachtane, M., Tarfaoui, M., Goda, I., & Rouway, M. 2020. A review on the technologies, design considerations and numerical models of tidal current turbines. Renewable Energy. [Google Scholar]

[11] M. Nachtane, M. Tarfaoui, D. Saifaoui, A. El Moumen, O.H. Hassoon, H. Benyahia. 2018. Evaluation of durability of composite materials applied to renewable marine energy: Case of ducted tidal turbine. Energy Reports, Volume 4, Pages 31-40. [CrossRef] [Google Scholar]

[12] Gemi, L. 2018. Investigation of the effect of stacking sequence on low velocity impact response and damage formation in hybrid composite pipes under internal pressure. A comparative study. Composites Part B: Engineering, 153, 217–232. [CrossRef] [Google Scholar]

[13] Gu, J., & Chen, P. 2017. Some modifications of Hashin’s failure criteria for unidirectional composite materials. Composite Structures, 182, 143–152. [CrossRef] [Google Scholar]

[14] K. Kodagali., 2017. Thesis, Progressive Failure Analysis of composite Materials using the Puck Failure Criteria. [Google Scholar]

[15] Kim Martineli Souza Gonçalves. 2015. Hashin’s Failure Criteria In-Plane Stress Numerical Model Correlated to Tensile Tests. International Journal of Engineering Research and Science & Technology. [Google Scholar]

[16] H. Boudounit, M. Tarfaoui, D. Saifaoui. 2019. Structural Design and Analysis of a 5MW Offshore Wind Turbine Blades Under Critical Aerodynamic Loads. 14th Congress of Mechanics April 16-19, 2019 (Rabat, MOROCCO). [Google Scholar]

[17] Söker, H. 2013. Loads on wind turbine blades. Advances in Wind Turbine Blade Design and Materials, 29–58. [CrossRef] [Google Scholar]