UH-Contribution Ravi Mullapudi Parnak Charkhchi Ashraf Ayoub

1. NEES - Jan 23, 2008 UH-Contribution Ravi Mullapudi Parnak Charkhchi Ashraf Ayoub

2. OUTLINE • Combined Bending/Shear • Modified Compression Field Theory (MCFT) • Rotating Angle Softened Truss Model (RA-STM) • Fixed Angle Softened Truss Model (FA-STM) • Soften Membrane Model (SMM) • Comparison between Models • Seismic Analysis – Numerical Results • Combined Torsion/Bending/Shear • Discretization of Section in 2D/3D Regions • 3D Constitutive Models • Section Analysis • Numerical Results • On-Going Work • Beam Element under Combined Torsion/Bending/Shear • Seismic Analysis • OpenSees

3. Modified Compression Field Model Rotating Angle- Softened Truss Model

4. SOFTEN TRUSS MODEL -Principle Concrete Element • Shear stress along crack ≠ 0  Vc • Biaxial Stress & Strain • Smeared Approach SOFTEN Membrane MODEL • Hsu/Zhu Poisson Ratio

5. NUMERICAL RESULTS – USC Shear-Critical Column = 86 MPa Xiao and Martirossyan Longitudinal yield stress = 510 MPa Transverse yield stress = 449 MPa

6. NUMERICAL RESULTS Effect of Different Models Monotonic Analysis with different Elements HC4-8L16-T6-0.1P Column

7. NUMERICAL RESULTS Hoop Strain Distributions HC4-8L16-T6-0.1P Column

8. NUMERICAL RESULTS – Cyclic Load Displacement Axial Load = 1068 kN USC Column Flexure Element • Flexure element is unable to predict the correct behavior

9. NUMERICAL RESULTS – Cyclic Load Displacement Axial Load = 1068 kN USC Column Shear Element HC4-8L16-T6-0.2P Column • Shear element is able to predict the correct behavior

10. NUMERICAL RESULTS Shear Element Load Displacement Dynamic Shear Analysis HC4-8L16-T6-0.1P Column

11. – Earthquake Analysis – Load vs. Deformation NUMERICAL RESULTS HC4-8L16-T6-0.1P Column El Centro Record

12. = 22 MPa NUMERICAL RESULTS – Shear-Critical Column Aboutaha et al. Longitudinal yield stress = 434 MPa Transverse yield stress = 400 MPa

13. NUMERICAL RESULTS – Shear Element Load Displacement 48” Column Syracuse Column Axial Load = 0 kN • Due to weak axis loading, Pinching is high

14. NUMERICAL RESULTS – Shear and Flexure Element 48” Column Syracuse Column Axial Load = 0 kN • Flexure element is unable to predict the correct behavior

15. NUMERICAL RESULTS – Earthquake Analysis – Time History 48” Column Syracuse Column Shear Analysis Assumed Axial Load = 0.1 fc Ag = 205.5 kN 2 * EL Centro (1940) record

16. – Earthquake Analysis – Load vs. Deformation NUMERICAL RESULTS SC3 Column Shear Dynamic 2*El-Centro

17. NUMERICAL RESULTS – Earthquake Analysis – Time History Syracuse Column Flexure and Shear Analysis Assumed Axial Load = 0.1 fc Ag = 205.5 kN 2 * EL Centro (1940) record

18. Shell Region Core Region Transverse Reinforcement 1% Longitudinal Reinforcement 2% 406.4 mm Dia. NUMERICAL RESULTS – UNR Column Axial Load = 355 kN Vu Phan et al. 36.3 N – S2/mm 1829 mm EL Centro NS

19. NUMERICAL RESULTS – Earthquake Analysis EL Centro (1940) record UNR Column- 9F1 Experiment

20. NUMERICAL RESULTS – Earthquake Analysis EL Centro (1940) record UNR Column

21. Shear Element Load Displacement NUMERICAL RESULTS UNR Column 9S1 Deflection for 2.0*El Centro

22. Torsion Basic Equations Equilibrium Compatibility

23. Torsional Section Discretization 2D/3D Regions

24. 3D Constitutive Model – Vecchio and Selby Approach (1991) • No Complete 3D- Model available • Assuming the same relation ship for intermediate stress calculation • Implemented the 3D procedure to SMM

25. Torsional Section Fiber Section Analysis

26. Numerical Results Pure Torsion Box Section

27. Numerical Results

28. Numerical Results - Combined Torsion/Bending 5, #9 bars #4 hoops @ 5” 24” 12”

29. Schedule of On-Going Work