EC3-Compatible Methods for Analysis and Design of Steel Framed Structures
Abstract
:1. Introduction
1.1. Nonlinear Behaviour of Steel Structures
1.2. Imperfections
1.3. Modelling–Analysis–Verification
1.4. Advantages and Disadvantages of Different Methods
1.5. Literature Review
1.6. Objectives and Outline
2. Examined Analysis and Design Methods
- GMNIA: Geometrically and Materially Nonlinear Analysis with Imperfections
- GNIA-SD: Geometrically Nonlinear Analysis with Imperfections—Section Design
- GM: General Method
- GNA-SMD: Geometrically Nonlinear Analysis—Section and Member Design
- LA-SMD: Linear Analysis—Section and Member Design
2.1. GMNIA
2.2. GNIA-SD
2.3. General Method
2.4. GNA-SMD
2.5. LA-SMD
3. Examined Frames
3.1. Geometry and Material
3.2. Loads
3.3. Imperfections
3.4. Modelling
4. Results
4.1. Influence of Nonlinearities
4.2. Influence of the Imperfection Pattern
4.3. Collapse Mechanism
4.4. Ultimate Load Factors
- All methods are on the safe side for the most rigid frame LS, where αcr > 10.
- All methods except for General Method are unsafe for the slenderest frame, where αcr < 3.
- Only the General Method is on the safe side for all frames.
- The commonly used in practice GNIA-SD method is safe only for the LS frame.
- The least conservative method is the GNIA-SD, while the most conservative is the ASOA-SMD, except for the VHS frame where the General Method is the most conservative.
- All methods become less conservative as the slenderness of the structure increases.
- Although for frames that αcr < 10, sway buckling lengths should be considered when a 1st order analysis is executed, results show that by taking them equal to the system lengths (method LA-SMDns) leads to safe results for the MS frame (αcr = 6.66) and slightly (less than 5%) unsafe results for the HS frame (αcr = 4.05).
- The differences between the exact GNA-SMD and the approximate ASOA-SMD method are very small. The approximate method is slightly more conservative for the three more rigid frames, while for the slenderest one, where its application is not permitted, the two methods lead to an identical ultimate load factor.
5. Discussion
5.1. Interaction of Nonlinearities
5.2. Magnitude of Imperfections
5.3. GNA-SMD
5.4. General Method
5.5. Effective Buckling Length
6. Conclusions
- The out-of-plane buckling dominates the behaviour of the examined frames. Their collapse mechanism involves inelastic flexural torsional buckling of their columns.
- For the three more rigid frames (αcr > 3), all the EC3-permitted design methods, except for the GNIA-SD, are on the safe side.
- The examined methods become less conservative as the slenderness of the structure increases. Hence, although they are all safe for the rigid frame, for the slenderest one (αcr < 3) all of them except for the General method are unsafe.
- In slender structures (αcr < 10) the consideration of each type of nonlinearity separately but neglecting their interaction, i.e., the geometric nonlinearity in the analysis and the material nonlinearity through plastic cross-sectional verification, results in unsafe design.
- The imperfections incorporated in the buckling curves are much lower than those proposed in Table 5.1 of EN 1993-1-1. If the imperfections extracted from the buckling curves are considered in GMNI Analyses, then all the methods that involve buckling verification are more conservative than GMNIA for all frames.
- When the system buckling approach is adopted for the determination of the buckling lengths, the calculations should be based on the critical buckling mode for the storey that each column belongs to, namely the first buckling mode where this storey displays large drift.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
EC3 | Eurocode 3 |
GMNIA | Geometrically and Materially Nonlinear Imperfection Analysis |
GMNIA (Lbc) | Geometrically and Materially Nonlinear Imperfection Analysis (Local imperfections from buckling curves) |
GNIA-SD | Geometrically Nonlinear Imperfection Analysis–Section Design |
GNA-SMD | Geometrically Nonlinear Analysis–Section and Member Design |
ASOA-SMD | Approximate Second Order Analysis–Section and Member Design |
LA-SMDs | Linear Analysis-Section and Member Design (sway buckling length) |
LA-SMDns | Linear Analysis-Section and Member Design (non-sway buckling length) |
FB | Flexural Buckling |
FTB | Flexural Torsional Buckling |
LB | Local Buckling |
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Method | Modelling—d.o.f. of Beam Elements | Analysis | Modelled Imperfections | Section Design | Member Design | In Plane Buckling Length |
---|---|---|---|---|---|---|
GMNIA | 7 | GMNIA | Global & Local | No | No | - |
GNIA-SD | 7 | GNIA | Global & Local | Yes | No | - |
GM | 6 | GNIA/LBA | Global & in-plane local | Yes | General Method | - |
GNA-SMD | 6 | GNA | Global | Yes | Yes | Non-sway |
LA-SMD | 6 | LA | Global | Yes | Yes | Sway |
Frame | Slenderness | αcr | Vertical Loads | Horizontal Loads | |||
---|---|---|---|---|---|---|---|
Distributed | Concentrated | ||||||
Internal Column | External Column | 1st Floor | 2nd Floor | ||||
q [kN/m] | Pint [kN] | Pext [kN] | H1 [kN] | H2 [kN] | |||
LS | Low | 10.04 | 70 | 0 | 0 | 256.5 | 436 |
MS | Medium | 6.66 | 70 | 576 | 288 | 89.5 | 456 |
HS | High | 4.05 | 70 | 1727 | 863.5 | 15 | 289 |
VHS | Very High | 2.86 | 70 | 2878 | 1439 | 0 | 0 |
Method | Ultimate Load Factor λcollapse | |||
---|---|---|---|---|
LS (αcr = 10.04) | MS (αcr = 6.66) | HS (αcr = 4.05) | VHS (αcr = 2.86) | |
GMNIA | 1.000 | 1.000 | 1.000 | 1.000 |
GNIA-SD | 0.963 | 1.010 | 1.088 | 1.167 |
GNA-SMD | 0.820 | 0.853 | 0.896 | 1.009 |
ASOA-SMD | 0.804 | 0.834 | 0.878 | 1.009 |
LA-SMDs | 0.874 | 0.904 | 0.957 | 1.054 |
LA-SMDns | 0.877 | 0.939 | 1.011 | 1.082 |
General Method | 0.869 | 0.905 | 0.922 | 0.960 |
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Antonodimitraki, S.; Thanopoulos, P.; Vayas, I. EC3-Compatible Methods for Analysis and Design of Steel Framed Structures. Modelling 2021, 2, 567-590. https://doi.org/10.3390/modelling2040030
Antonodimitraki S, Thanopoulos P, Vayas I. EC3-Compatible Methods for Analysis and Design of Steel Framed Structures. Modelling. 2021; 2(4):567-590. https://doi.org/10.3390/modelling2040030
Chicago/Turabian StyleAntonodimitraki, Sofia, Pavlos Thanopoulos, and Ioannis Vayas. 2021. "EC3-Compatible Methods for Analysis and Design of Steel Framed Structures" Modelling 2, no. 4: 567-590. https://doi.org/10.3390/modelling2040030
APA StyleAntonodimitraki, S., Thanopoulos, P., & Vayas, I. (2021). EC3-Compatible Methods for Analysis and Design of Steel Framed Structures. Modelling, 2(4), 567-590. https://doi.org/10.3390/modelling2040030