Engineering
Wind Turbine
100%
Leading Edge
39%
Delamination
18%
Composite Material
16%
Mixed Mode
16%
Defects
15%
Crack Growth
13%
Tunnel Construction
13%
Fatigue Damage
12%
Bridging
11%
Impact Toughness
11%
Structural Health Monitoring
11%
Cohesive Law
10%
Damage Mechanism
10%
Computational Analysis
9%
MXene
9%
Rotor Blade
8%
Epoxy Composite
8%
Wind Power
7%
Fatigue Life
7%
Fatigue Testing
7%
Graphene
7%
Composite Structure
7%
Acoustic Emission
7%
J-Integral
7%
System Protection
6%
Blade Surface
6%
Mode Mixity
6%
Micromechanical Model
6%
Composite Fiber
6%
S-N Curve
6%
Finite Element Modeling
6%
Thermal Residual Stress
6%
R-Curves
5%
Full Scale
5%
Finite Element Method
5%
Crack Tip
5%
Crack Front
5%
Energy Release Rate
5%
Stress Concentration
5%
Damage Initiation
5%
Damage Growth
5%
Fiber-Reinforced Polymer
5%
Material Science
Delamination
25%
Composite Material
18%
Glass Fiber
17%
Crack Growth
16%
Fatigue Damage
15%
Mechanical Strength
14%
Finite Element Methods
14%
Polyurethane
13%
Crack Tip
10%
Graphene
10%
Polymer Composite
9%
Fracture Toughness
9%
Reinforced Plastic
9%
Finite Element Modeling
9%
Fatigue of Materials
9%
Protective Coating
8%
Scanning Electron Microscopy
8%
Stress Concentration
8%
Carbon Fiber
8%
Thermoplastics
7%
Residual Stress
7%
MXene
6%
Crack Initiation
6%
Volume Fraction
6%
Damage Mechanics
6%
R-Curves
6%
Tomography
5%
X-Ray Computed Tomography
5%
Keyphrases
Wind Turbine Blade
23%
Fiber Bridging
7%
Leading Edge Protection
6%
Cohesive Law
6%
Composite Materials
6%
Micromechanical Modeling
6%
Mode Mixing
6%
Delamination
5%
Delamination Crack
5%