Analysis of the Effect of Fiber Orientation on Mechanical and Elastic Characteristics at Axial Stresses of GFRP Used in Wind Turbine Blades

Due to its physical and mechanical properties, glass-fiber-reinforced polymer (GFRP) is utilized in wind turbine blades. The loads given to the blades of wind turbines, particularly those operating offshore, are relatively significant. In addition to the typical static stresses, there are also large...

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Veröffentlicht in:	Polymers 2023-02, Vol.15 (4), p.861
Hauptverfasser:	Morăraș, Ciprian Ionuț, Goanță, Viorel, Husaru, Dorin, Istrate, Bogdan, Bârsănescu, Paul Doru, Munteanu, Corneliu
Format:	Artikel
Sprache:	eng
Schlagworte:	Axial stress Climate change Composite materials Energy consumption Failure Fiber orientation Fiber reinforced polymers Finite element analysis Finite element method Glass fiber reinforced plastics Mechanical properties Orientation effects Parameter identification Physical properties Polymerization Shear tests Strain gauges Stress-strain curves Tensile strength Tensile stress Tensile tests Turbine blades Turbines Wind turbines
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description	Due to its physical and mechanical properties, glass-fiber-reinforced polymer (GFRP) is utilized in wind turbine blades. The loads given to the blades of wind turbines, particularly those operating offshore, are relatively significant. In addition to the typical static stresses, there are also large dynamic stresses, which are mostly induced by wind-direction changes. When the maximum stresses resulting from fatigue loading change direction, the reinforcing directions of the material used to manufacture the wind turbine blades must also be considered. In this study, sandwich-reinforced GFRP materials were subjected to tensile testing in three directions. The parameters of the stress-strain curve were identified and identified based on the three orientations in which samples were cut from the original plate. Strain gauge sensors were utilized to establish the three-dimensional elasticity of a material. After a fracture was created by tensile stress, SEM images were taken to highlight the fracture's characteristics. Using finite element analyses, the stress-strain directions were determined. In accordance to the three orientations and the various reinforcements used, it was established that the wind turbine blades are operational.
doi_str_mv	10.3390/polym15040861
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The loads given to the blades of wind turbines, particularly those operating offshore, are relatively significant. In addition to the typical static stresses, there are also large dynamic stresses, which are mostly induced by wind-direction changes. When the maximum stresses resulting from fatigue loading change direction, the reinforcing directions of the material used to manufacture the wind turbine blades must also be considered. In this study, sandwich-reinforced GFRP materials were subjected to tensile testing in three directions. The parameters of the stress-strain curve were identified and identified based on the three orientations in which samples were cut from the original plate. Strain gauge sensors were utilized to establish the three-dimensional elasticity of a material. After a fracture was created by tensile stress, SEM images were taken to highlight the fracture's characteristics. Using finite element analyses, the stress-strain directions were determined. 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subjects	Axial stress Climate change Composite materials Energy consumption Failure Fiber orientation Fiber reinforced polymers Finite element analysis Finite element method Glass fiber reinforced plastics Mechanical properties Orientation effects Parameter identification Physical properties Polymerization Shear tests Strain gauges Stress-strain curves Tensile strength Tensile stress Tensile tests Turbine blades Turbines Wind turbines
title	Analysis of the Effect of Fiber Orientation on Mechanical and Elastic Characteristics at Axial Stresses of GFRP Used in Wind Turbine Blades
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