Engineering
Delamination
100%
Crack Growth Rate
48%
Delamination Growth
39%
Numerical Study
31%
Block Level
31%
Rate Model
28%
Toughening
28%
Constant Amplitude
26%
Bridging
25%
Transients
22%
Fatigue Loading
18%
Fibre-Reinforced Polymer Composite
18%
Crack Propagation
18%
Failure Mechanism
17%
Cohesive Zone
15%
Finite Element Method
15%
Load Block
15%
R-Curves
14%
Cohesive Law
14%
Experimental Result
14%
Intralaminar Crack
14%
History Effect
14%
Thermal Stress
14%
Mixed Mode
14%
Loading History
14%
Damage Development
14%
Damage Model
14%
Crack Density
14%
Intralaminar Damage
14%
Step Change
14%
Bending Stiffness
14%
Bending Tests
14%
Automatic Calculation
14%
Crack Initiation
14%
Fatigue Crack Growth
14%
Finite Element Modeling
14%
Crack Growth
11%
Constitutive Model
10%
Crack Front
9%
High Cycle Fatigue
9%
Damage Evolution
9%
Tasks
9%
Loading Condition
9%
Deflection Curve
9%
Cyclic Loading
9%
Fatigue Life
9%
Fibre Reinforced Polymer
9%
Fatigue Damage
9%
Epoxy Glass
9%
Interaction Effect
8%
Material Science
Delamination
70%
Glass-Fiber Reinforced Plastic
42%
Crack Growth
18%
Crack Propagation
17%
Composite Laminate
14%
Finite Element Modeling
14%
Crack Initiation
14%
Density
14%
Laminated Composite
10%
Finite Element Methods
8%
Fatigue Crack Growth
8%
Mechanical Fracture
7%
Cohesive Zone Model
7%
Reinforced Plastic
5%
Keyphrases
Cohesive Law
14%
Intralaminar Cracks
14%
Inverse Parameter Identification
14%
Parametric Finite Element Modeling
14%
Cohesive Zone Law
14%
Delamination Toughening
14%
Interface Finite Element
14%
Cantilever Bending Test
14%
Glass Fiber Reinforced Polymer Composites
14%
Block Loads
11%
Load Interaction Effect
10%
Crack Growth Rate Model
9%
Deflection Curve
9%
Interface Toughening
8%
Preoperational
7%
Delamination Initiation
7%
Residual Effect
7%
Deformation Response
7%
Component Effect
7%
Thermomechanical Studies
7%