Engineering
Fatigue Strength
84%
High Strength Steel
60%
Mechanical Impact
55%
Joints (Structural Components)
51%
Welds
50%
High Frequency
48%
Strength Assessment
39%
Steel
36%
Residual Stress
34%
Application
28%
Models
26%
Mechanical Fatigue Test
26%
Test Result
25%
Substrates
25%
Surface
20%
Prediction
19%
Base Material
18%
Additive Manufacturing Process
18%
Additive Manufacturing
17%
Stress State
17%
Fatigue Design
17%
Design
17%
Fatigue Assessment
16%
Computer Simulation
15%
Fatigue Behavior
15%
Mild Steel
15%
Estimation
14%
Ti-6al-4v
14%
Butt Joint
14%
Material Model
13%
Welded Structure
13%
Numerical Computation
12%
Railway
12%
Notch Fatigue
12%
Axial Misalignment
12%
Process Simulation
12%
Crack Propagation
12%
Compressive Residual Stress
11%
Welding
10%
Temperature
10%
Experimental Investigation
10%
Numerical Model
10%
Mechanical Properties
10%
Rolling Process
10%
High Cycle Fatigue
10%
Nominal Stress
9%
Manufacturing Process
9%
Constant Amplitude
9%
Deformation
9%
Low Cycle Fatigue
9%
Material Science
Mechanical Strength
100%
Materials
69%
Spring Steel
49%
Fatigue of Materials
38%
Temperature
36%
Laser
32%
Microstructure
28%
Cast
26%
Materials Property
25%
Aluminum
23%
Crack Propagation
23%
Residual Stress
22%
Fatigue Behavior
21%
Cast Aluminum Alloy
20%
Ti-6Al-4V
20%
High Strength Steels
19%
Fatigue Crack Growth
19%
Finite Element Method
18%
Tomography
17%
Gas
16%
Welding
15%
Carbon Steel
14%
Metal
13%
Aluminum Alloys
13%
Gas Metal Arc Welding
12%
Grain Growth
12%
Numerical Computational Method
12%
Rubber
12%
Mechanical Impact
12%
Stainless Steel
12%
Crack Initiation
10%
Surface Roughness
9%
Filler
9%
Die Casting
9%
Microscopy
9%
Low-Cycle Fatigue
9%
Bending
9%
Hot Isostatic Pressing
8%
Porosity
8%
High-Cycle Fatigue
8%
Scanning Electron Microscopy
8%
Pore Size
8%
Crack Growth
7%
Viscoplastic Material
7%
Wear Resistance
6%
Creep
6%
Sand Casting
6%
Stress Intensity
6%
Characterization
6%
Energy Density
6%