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Structural design of high-strength austenitic stainless steel
Leroy Gardner
*
, Asko Talja
, N.R. Baddoo
*
Corresponding author for this work
VTT Technical Research Centre of Finland
The Steel Construction Institute (SIC)
Imperial College London
VTT (former employee or external)
Research output
:
Contribution to journal
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Article
›
Scientific
›
peer-review
134
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Keyphrases
High Strength
100%
Structural Design
100%
Austenitic Stainless Steel
100%
Stainless Steel
100%
Material Cost
66%
Standard Strength
66%
Cold Working
33%
Annealing
33%
Chemical Composition
33%
Tensile Test
33%
Numerical Results
33%
Numerical Modeling
33%
Steel Grade
33%
Strength Grading
33%
Material Selection
33%
Strain Hardening
33%
Eurocode 3
33%
Incomplete Knowledge
33%
Reliability Level
33%
Availability Performance
33%
Material Use
33%
Lower Limb Strength
33%
Economic Structure
33%
Strength Enhancement
33%
Sensitivity Study
33%
Significant Disadvantage
33%
Steel Members
33%
Deformation Capacity
33%
Structural Behavior
33%
Strength of Materials
33%
Design Guidance
33%
Product Range
33%
Structural Configuration
33%
Structural Carbon Steel
33%
High-strength Materials
33%
Sustainable Structures
33%
High-strength Stainless Steel
33%
Capacity Design
33%
Engineering
Structural Design
100%
Austenitic Stainless Steel
100%
Design Method
100%
Stainless Steel
80%
Material Cost
40%
Strain Hardening
40%
Steel Grade
20%
Parametric Study
20%
Eurocodes
20%
Sensitivity Study
20%
Cold Working
20%
Design Guidance
20%
Structural Configuration
20%
Strength Enhancement
20%
Carbon Steel
20%
Structural Behavior
20%
Materials Mechanics
20%
Numerical Modeling
20%
Tensile Test
20%
INIS
design
100%
austenitic steels
100%
stainless steels
57%
comparative evaluations
28%
cost
28%
range
28%
modifications
14%
performance
14%
efficiency
14%
levels
14%
deformation
14%
bending
14%
modeling
14%
annealing
14%
chemical composition
14%
capacity
14%
configuration
14%
availability
14%
reliability
14%
carbon steels
14%
compression
14%
parametric analysis
14%
strain hardening
14%
sensitivity analysis
14%
cold working
14%
Material Science
Austenitic Stainless Steel
100%
Stainless Steel
100%
Work Hardening
50%
Material Selection
25%
Structural Behavior
25%
Carbon Steel
25%