1. GTSTRUDL�Pushover Analysis�How Do You Do It?�What Do You Get? GTSTRUDL Users Group
June 18-21, 2003
Clearwater Beach, FL
2. Topics Basic Nonlinear Analysis Procedure
Member Material Nonlinearity
Nonlinear Member End Connections
Plastic Hinge
Basic Incremental Nonlinear Analysis Example
Basic Pushover Analysis Procedure
Pushover Analysis Features and Mechanics
Pushover Analysis Examples
Steel Frame with Nonlinear Member End Connections
Steel Frame with Plastic Hinges
RC Frame with Plastic Hinges by Force Control
RC Frame with Plastic Hinges by Displacement Control
3. Basic Nonlinear Analysis Procedure
4. Nonlinear Effects Menu
5. Nonlinear Effects Menu
6. Nonlinear Spring Element Menus
7. Nonlinear Spring Element Menus
8. Nonlinear Spring Element Menus
9. Nonlinear Spring Connections�Properties
10. Nonlinear Spring Connections�Data Description
11. Plastic Hinge Effects�Basic Geometry
12. Plastic Hinge Effects�Basic Geometry
13. Plastic Hinge Effects�Properties The implication of this hinge configuration is that the three degrees of freedom are coupled, producing the classical axial force bending moment interaction which is not present in the NLS connection model.The implication of this hinge configuration is that the three degrees of freedom are coupled, producing the classical axial force bending moment interaction which is not present in the NLS connection model.
14. Plastic Hinge Effects�Properties
15. Plastic Hinge Effects�Properties
16. Plastic Hinge Effects� Properties -- Material Property Defaults
17. Plastic Hinge Effects�Properties Material Stress-Strain Examples
18. Plastic Hinge Effects�Properties Material Stress-Strain Examples
19. Plastic Hinge Effects�Properties RC Plastic Hinge Behavior
20. Plastic Hinge Effects�Summary of Characteristics Compact behavior; e.g. no local buckling, etc.
Neutral axis shift automatically taken
into account by equilibrium corrections.
Failure is based on combined normal stress only (axial plus bending).
21. Plastic Hinge Effects�Summary of Characteristics Elastic loading/unloading behavior only. No hysteretic effects.
May be mixed with any other member nonlinearity including NLS connections (DOFs may not overlap).
All member modeling features supported: member loads, member releases, member eccentricities, etc.
22. Plastic Hinge Effects�Data Description Example WF Section
23. Plastic Hinge Effects�Data Description Example Rectangular RC Section
24. Nonlinear Analysis Procedure
25. Basic Nonlinear Analysis Example STRUDL 'NL1' 'BASIC NONLINEAR FRAME ANALYSIS'
UNITS INCHES KIPS
JOINT COORDS
1 0.0 180.0 S
2 120.0 180.0
3 120.0 135.0
4 120.0 90.0
5 120.0 45.0
6 120.0 0.0 S
JOINT RELEASES
1 6 MOMENT Z
TYPE PLANE FRAME
MEMBER INC
1 1 2; 2 6 5
3 5 4; 4 4 3;
5 3 2
26. Basic Nonlinear Analysis Example CONSTANTS
E 10000.0
MEMBER PROPERTIES
1 AX 10000.0 IZ 100.0
2 TO 5 AX 10000.0 IZ 200.0
$
$ Perform nonlinear analysis in 4
$ load increments.
$
UNITS KIPS FEET
LOAD 1
MEMBER LOADS
1 FORCE Y GLO UNI FR W 25.0 NONLINEAR EFFECTS
GEOMETRY MEMBERS 2 TO 5
MAXIMUM NUMBER OF CYCLES 50
CONVERGENCE TOLERANCE -
DISPLACEMENT 0.001
NONLINEAR ANALYSIS
CREATE LOAD COMBINATION Inc1 -
SPECS 1 1.0
27. Basic Nonlinear Analysis Example $
$ Load increment 2
$ Continue nonlinear analysis
$
CHANGES
LOAD 1
ADDITIONS
MEMBER LOADS
1 FORCE Y GLO UNI W 25.0
PRINT APPLIED MEMBER LOADS
LOAD LIST 1
NONLINEAR ANALYSIS CONTINUE
CREATE LOAD COMBINATION Inc2 -
SPECS 1 1.0 UNITS INCHES
LIST DISPLACEMENTS FORCES
UNITS FEET
$
$ Load increment 3
$ Continue nonlinear analysis
$
CHANGES
LOAD 1
ADDITIONS
MEMBER LOADS
1 FORCE Y GLO UNI W 25.0
PRINT APPLIED MEMBER LOADS
28. Basic Nonlinear Analysis Example LOAD LIST 1
NONLINEAR ANALYSIS CONTINUE
CREATE LOAD COMBINATION Inc3 -
SPECS 1 1.0
UNITS INCHES
LIST DISPLACEMENTS FORCES
UNITS FEET
$
$ Loading increment 4
$ Continue nonlinear analysis
$
CHANGES
LOAD 1
ADDITIONS MEMBER LOADS
1 FORCE Y GLO UNI FR W 25.0
PRINT APPLIED MEMBER LOADS
LOAD LIST 1
NONLINEAR ANALYSIS CONTINUE
CREATE LOAD COMBINATION Inc4 -
SPECS 1 1.0
UNITS INCHES
LIST DISPLACEMENTS FORCES
FINISH
29. Basic Pushover Analysis Procedure
30. Basic Pushover Analysis Procedure
31. Pushover Analysis�Basic Features Nonlinear static analysis
Automatic creation of load increments
Automatic storage of load increment results
Creation of intermediate load step conditions
Intermediate load step conditions contain both results and applied loadings.
Intermediate load steps stored in load group IncrLds
32. Pushover Analysis�Basic Features Automated search for collapse load factor
All nonlinear effects supported
33. Pushover Analysis�Mechanics
34. Pushover Analysis�Mechanics
35. Pushover Analysis�Mechanics
36. Pushover Analysis�Mechanics
37. Pushover Analysis�Menu and Command Syntax
38. Pushover Analysis�Menu and Command Syntax
39. Pushover Analysis�Menu and Command Syntax
40. Pushover Analysis�Steel Frame Example with NLS Connections
41. Pushover Analysis�Steel Frame Example with NLS Connections
42. Pushover Analysis�Steel Frame Example with NLS Connections
43. Pushover Analysis�Steel Frame Example with NLS Connections
44. Pushover Analysis�Steel Frame Example with NLS Connections
45. Pushover Analysis�Steel Frame Example with NLS Connections
46. Pushover Analysis�Steel Frame Example with NLS Connections
47. Pushover Analysis�Steel Frame Example with NLS Connections
48. Pushover Analysis�Steel Frame Example with NLS Connections
49. Pushover Analysis�Steel Frame Example with Plastic Hinges
50. Pushover Analysis�Steel Frame Example with Plastic Hinges
51. Pushover Analysis�Steel Frame Example with Plastic Hinges
52. Pushover Analysis�Steel Frame Example with Plastic Hinges
53. Pushover Analysis�Steel Frame Example with Plastic Hinges
54. Plastic Hinge Effects� Steel Frame Example with Plastic Hinges
55. Pushover Analysis�Steel Frame Example with Plastic Hinges
56. Pushover Analysis�Steel Frame Example with Plastic Hinges
57. Pushover Analysis�Steel Frame Example with Plastic Hinges
58. Pushover Analysis �Steel Frame Example with Plastic Hinges
59. Pushover Analysis�Steel Frame Example with Plastic Hinges
60. Pushover Analysis�Steel Frame Example with Plastic Hinges
61. Pushover Analysis�Strategies Do a conventional nonlinear analysis first.
Use FORM LOAD to create a version of your incremental load scaled to size of first increment.
Use a larger collapse load convergence tolerance (~0.01) for the first pushover analysis attempt.
Keep the loading rate on the smaller side. Its better to have two to four load increments that are basically linear.
62. Pushover Analysis�Strategies Larger convergence rate values -- 0.6 to 0.8 -- seem to perform better, i.e. result in a more economical number of load increments.
~50 appears to be the most economical maximum number of nonlinear analysis cycles, particularly with NLS elements, NLS connections, and plastic hinges.
63. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control
64. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control
65. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control
66. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control PUSHOVER ANALYSIS DATA
CONSTANT LOAD 'DL'
INCREMENTAL LOAD 'PUSH'
MAXIMUM NUMBER OF LOAD INCREMENTS 40
MAXIMUM NUMBER OF TRIALS 11
LOADING RATE 1.0
CONVERGENCE RATE 0.6
CONVERGENCE TOLERANCE COLLAPSE 0.0005
CONVERGENCE TOLERANCE EQUIL 0.0001
MAXIMUM NUMBER OF CYCLES 100
END
PERFORM PUSHOVER ANALYSIS
67. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control
68. Pushover Analysis�RC Frame Example with Plastic Hinges, Force Control
69. Pushover Analysis�RC Frame Example with Plastic Hinges, Displacement Control
70. Pushover Analysis�RC Frame Example with Plastic Hinges, Displacement Control
71. Pushover Analysis�RC Frame Example with Plastic Hinges, Displacement Control
