1. Evaluation of the Sandwich Plate System in Bridge Decks Using a Plate Approach� Devin Harris – Michigan Tech
Chris Carroll – Virginia Tech
2. Project Overview
3. SPS for Civil Structures
4. Introduction to SPS Developed by Intelligent Engineering
Maritime industry
Bridge Application (deck)
5. Prefabricated Decks/Bridges Fabricated panel – limited girder configuration
Wide girder spacing
Larger cantilevers
Fast erection Structured Panel Deck
8. Sequence of SPS Construction
9. Sequence of SPS Construction
10. Prefabricated Decks/Bridges Simple plate – many girder configuration
Small girder spacing
Short cantilevers
Girders attached to deck in factory
Very fast erection Simple Plate Deck
12. Fabrication Process
13. Current Bridge Projects �New Bridge IBRC – Cedar Creek – Texas – June ‘08
14. Research Objective To develop a simple design procedure for SPS decks for bridge applications
15. SPS Deck Design Approach AASHTO Deck Design
Design Methods
Linear Elastic (Equivalent Strip)
Inelastic (Yield-Line)
Empirical (R/C only)
Orthotropic Plate
Limit States
Serviceability
Strength
Fatigue
SPS Approach (Layered Plate)
Variable loads and B.C.s
Assume deflection controls
16. SPS Plate Representation
17. Analysis Options Classical Plate Approach
Navier
Levy
Energy (Ritz)
Finite Element Approach
Shell
Solid
Grid (line elements) Note: Focus here will be on the FE approach, but the classical plate approach will be used primarily as a validation mechanismNote: Focus here will be on the FE approach, but the classical plate approach will be used primarily as a validation mechanism
18. FE Model Approach Shell Model
Advantages
Ideal for thin elements
Computationally efficient
Membrane/bending effects
Single thru thickness element
Solid Model
Advantages
Realistic geometry representation
Element connectivity
Disadvantages
Element compatibility
Element connectivity
Stacking limitations*
Disadvantages
Can be overly stiff
User error (more likely)
Complicated mesh refinement
19. Material Properties
20. Element Validation (Generic) Givens:
Boundary Conditions: Fully Restrained
Material Properties: E=29,000 ksi; n=0.25
Dimensions: thickness=6” (constant); a=b=L [L/t … 1-200]
Load: q = 0.01 ksi (uniform)
ANSYS
Shell 63 (4-node)
Shell 91/93 (8-node)
Solid 45 (8-node)
Solid 95, Solid 191 (20-node)
GT STRUDL
BPR (4-node plate)
SBHQ6 (4-node shell)
IPLS (8-node solid)
IPQS (20-node solid)
22. GT STRUDL Models
23. GT STRUDL Models
24. GT STRUDL Models
25. GT STRUDL Models
26. GT STRUDL Models
27. GT STRUDL Models
28. GT STRUDL Models
29. GT STRUDL Models
30. GT STRUDL Models
31. GT STRUDL Models
32. SPS Models Case I
Simple Support on all edges
Cold-formed angles – assume minimal rotational restraint
33. SPS Models Case II
Simple supports perpendicular to girders
Fixed supports along girders
Rotation restrained by girders & cold-formed angles
34. SPS Models Case III
Full restraint on all edges
Rotation restrained by girders & cold-formed angles
35. GT STRUDL Models
36. GT STRUDL Models Simple – Simple
Simple – Fixed
Fixed – Fixed
2” Thick Plate
1” Thick Plate
Symmetry
37. GT STRUDL Models
38. GT STRUDL Models
39. GT STRUDL Models Stiffness Analysis
GTSES
GTHCS
41. Summary of Element Validity ANSYS Solids
Converged with single thru thickness element
ANSYS Shells
Minimal mesh refinement required for convergence
STRUDL Plate/Shells
Converged but no multiple layer capabilities
STRUDL Solids
Converged with sufficient thru thickness refinement
42. Suggested Improvements Layered element for composite materials
Redraw Issues in GT Menu
Contour plots without mesh
Undo Button in GT Menu
43. Model Validation – SPS Panel
44. Model Validation – SPS Panel SPS Plate (0.25” plates; 1.5” core)
Support by W27 x 84 beams
Loaded to 77.8 k with concrete filled tires (assumed 10” x 20”)
45. Experimental vs. Shell Model Predictions�ANSYS
46. Experimental vs. Shell Model Predictions�ANSYS
47. Experimental vs. Solid Model Predictions�ANSYS
48. Experimental vs. Solid Model Predictions�GT STRUDL
49. Experimental vs. Solid Model Predictions�GT STRUDL
50. Model Validation – SPS Bridge
51. Model Validation – SPS Bridge SPS Plate (0.125” plates; 0.75” core)
Support by Built-up Girders (depth ~ 23”)
Loaded ~ 24 k with bearing pad (9” x 14”)
52. Experimental vs. Shell Model Predictions�ANSYS
53. Experimental vs. Shell Model Predictions�ANSYS
54. Experimental vs. Solid Model Predictions�ANSYS
55. Experimental vs. Solid Model Predictions�GT STRUDL
56. Experimental vs. Solid Model Predictions�GT STRUDL
57. Comparison of ANSYS and GT STRUDL Models
58. Conclusions SPS deck behavior can be modeled as plate with variable boundary conditions
Solid and shell elements are applicable
Attention to mesh refinement critical to solid elements
Higher order elements significantly increase # DOFs
Layered elements ideal for efficiency
GT STRUDL and ANSYS yield similar results, but not identical
Future investigation of differences in solid/shell boundary conditions
59. Acknowledgements Virginia Department of Transportation
Intelligent Engineering (www.ie-sps.com)
GT STRUDL Users’ Group
Virginia Tech
