
Master practical StaadPro modeling and analysis for a G+9 building and a steel warehouse with a five-ton crane, including installation, loading, analysis, design, and reporting outputs.
Learn to set up and run Staad.Pro Connect edition for a g+9 residential building, including downloading, installing, licensing, and configuring design codes, axis orientation, and opening existing models.
Learn to model a G+9 residential building in Staad.Pro connect edition and address installation and licensing challenges, including antivirus interference and setup troubleshooting.
Learn to set up Staad Pro for a g+9 residential building, selecting analytical modeling, creating nodes, beams and plates, and performing post-processing for design.
Learn to model a g+9 residential building in staad.pro by constructing a centerline diagram from architectural and geotechnical inputs, then create joints with translational repeats for accurate geometry.
Learn to model a g+9 residential building in staad pro by creating joints, giants (columns), foundations and plinth beams, and duplicating levels for a nine-story design, with plan and 3d views.
Explore staircase design for a G+9 building by modeling flight slabs, landing slabs, and landing beams, deciding lift placement and headroom for accessibility.
Model a G+9 residential building in STAAD.Pro by adding headroom, equipment room, and water tank, then define geometry, plates, slabs, and concrete properties before applying wall and wind loads.
Define m20, m25, and m30 concrete materials in StaadPro, assign them to beams, columns, slabs, and shear walls, and validate the g+9 residential model through 3d views.
Model a g+9 residential building in staad.pro, defining m20 and m25 materials with centimeter-based dimensions. Set beams, slabs, columns, plates; manage units; apply releases and fixed supports for analysis.
Learn to model a G+9 residential building in StaadPro using grid-based joints, beams, columns, shear walls, and roof slabs, with material properties, releases, and seismic and wind loads.
Apply StaadPro to model a g+9 building, convert dead and live loads to seismic weights, define seismic and wind loads, set load cases and analyze reactions.
Learn to define and apply seismic and wind loads in STAAD.Pro, using external pressure coefficients, load ranges, and surface directions for g+9 buildings and warehouses.
Learn to model decorative yet structural elements in StaadPro, calculate wall loads from brick weight, and apply live, water tank, equipment, and lift loads to beams and joints.
Learn practical loading, analysis, and design in StaadPro, including metric configuration, moving and wind and seismic loads, shear walls, and creating load envelopes and combinations for collapse and serviceability.
Learn to view and isolate structural elements, apply floor-specific loads, and generate wind and seismic load combinations in StaadPro, including 1.5 and 0.9 multipliers, for analysis and design.
Set up collapse and serviceability load combinations in staad pro, copy one-time dead, live, wind, and seismic loads, then run static analysis and review the output.
Navigate Staad.pro loading, analysis and design, define envelopes and collapse cases, interpret bending moment and shear in post-processing, and review warnings, results, and foundation reactions.
Describes post processing envelopes in StaadPro and guides the concrete design workflow: select parameters, define inputs, and run concrete and steel design with material options and checks.
Explore loading, analysis, and design in Staad Pro for concrete beams and columns, including reinforcement ratio and tied or spiral column types.
Learn StaadPro loading, analysis, and design with a focus on RCC vs steel design, how to identify pass/fail members, and extract material takeoff and reinforcement details from reports.
Learn practical steel warehouse design using Staad.pro, analyzing a g+9 building, balancing concrete and steel elements with advanced design for connections, bracketing, and crane provisions.
Explore modeling a steel warehouse in StaadPro Connect g+9 building, including defining Indian steel sections, applying top and bottom cover plates, modeling purlins and roof sheets, and assigning materials.
Explore StaadPro steel warehouse design part-3 by applying wind and seismic loads, defining releases, and configuring supports, with plan and 3d view modeling and wind pressure considerations.
Use StaadPro to analyze a steel warehouse design, fix warnings, assign joint weights, and apply seismic, wind, dead, live, temperature, crane, and exhaust-fan loads to obtain reactions.
Analyze crane and live loads, temperature effects, wind and seismic loads, and the required load combinations per code to ensure strength and serviceability in a steel warehouse design.
Master StaadPro to advance steel warehouse design by finalizing analysis, fixing errors in loading and user tables, and setting design parameters for limit state design and deflection checks.
Explore steel structure warehouse design using staad pro, including code selection, deflection limits, and material strengths, with fixity, gusset plates, and lateral torsional buckling considerations.
Explains steel warehouse design with STAAD Pro Connect, distinguishing hot-rolled and welded sections, applying design parameters, check code, and optimized section selection for least weight.
Address instability in StaadPro steel warehouse design by splitting beams and using built up taper sections to pass critical columns; note welded vs rolled sections and basic connection design.
Verify all joint members pass before design, split joints when needed, avoid prismatic sections, and select beam-column flange or web connections, using 3d view, bolts, and welds.
learn to perform response spectrum analysis for a high-rise building using Staad Pro, define seismic loading per 1893 2016, and derive natural periods, accelerations, and modal results.
StructuralGuru-GURURAYAR ASSOCIATES
(ENGINEERING CONSULTANCY & TRAINING'S)
ISO 9001-2015 CERTIFIES COMPANY
We are GURURAYAR ASSOCIATES MSME registered and ISO 9001-2015 certified single ownership company established in 2016 with 25 years of Industrial, commercial and residential design/consultancy experience in the field, we decided to alter direction. Now, we share our passion by helping others.
OUR MISSION:
To build an independent professional structural design engineers/consultants in all over India and abroad as well. We train people with our practical design methodology which is being currently practiced in engineering consultancy. We are committed to excel the quality and economic structural design services to our clients as well. Our ramp up process is designed to empower your team. Business mentors are key—that’s why when it comes to client selection, we’re choosy. We want to give each of you the right time and guidance you deserve.
OUR VISION :
"To give real service, you must add something which cannot be bought or measured by MONEY"
- Sir M.Vishveshwarayya.
OUR MOTTO: HELP EACH OTHER! GROW TOGETHER!!
TRANSFORMING MILLIONS OF CIVIL ENGINEERS FROM ALL OVER THE GLOBE IN TO DESIGNING AND CONSULTANTS FIELD!.
COURSE DESCRIPTION:
Following topics covered as Syllabus For Static G+9 Residential Building Modelling, Analysis & Design:-
1. Introduction Structure
2. Types of structures
3. Basic definitions Idealization of structures
4. About Staadpro Features hardware requirements
5. Staadpro screen organization GUI overview
6. Unit systems Structure geometry
7. Coordinate systems (Global and Local)
8. The Structural Model
9. Units
10. Objects and Elements
11. Groups
12. Coordinate
13. Systems and Grids
14. Properties
15. Load Cases
16. Functions
17. Analysis Cases
18. Combinations
19. Design settings
20. Output and Display Definitions
21. The Graphical User Interface
22. The Staadpro Screen Main Window
23. Menu Bar
24. Toolbars
25. Display Windows
26. Status Line
27. Using the Mouse
28. Viewing Options 2-D and 3-D Views
29. Perspective Pan, Zoom, and 3-D Rotate Limits
30. Element View Options
31. Other Options
32. Refreshing the Display Window
33. Basic Operations
34. File Operations
35. Defining Named Entities Drawing
36. Objects
37. Snap Tools
38. Drawing Controls
39. Selecting Graphically
40. Selecting by Feature
41. Editing Assigning Undo arid Redo
42. Analysing Displaying
43. Graphical Displays
44. Model Definition
45. Analysis Results
46. Function Plots
47. Tabular Displays
48. Designing
49. Locking and Unlocking
50. Entering Numerical Data
51. Setting Options
52. Define Grid System
53. Selecting template
54. Entering Grid System Data
55. Adding Grid Lines In X, Y and Z Directions
56. Define Material Properties
57. Specify Design Parameters
58. Material Property Data
59. Define Section Properties
60. Add Frame Section Property
61. Specify Frame Section Properties for Beam
62. Add New Frame Section Properties for Column
63. Specify Area Section Properties for Slab
64. Draw Drawing beams with different methods
65. Drawing Column as with different orientation
66. Drawing slabs
67. Assigning Properties
68. Assigning Properties to Frame Elements
69. Assigning Properties to Area Elements
70. Assign Restraints Assigning Fixed, Pinned, Roller Support at Joints
71. Define and Assign Load Cases
72. Adding and Assigning Dead Load Case
73. Adding and Assigning Live Load Case
74. Add rig and Assigning Wind Load Case
75. Adding and Assigning Seismic Load Case
76. Defining Load Combinations
77. Adding different Load Combinations for dead Load, Live Load, Wind Load and Seismic Load
78. View Analysis Results in Tabular Form
79. View Analysis Result Diagrams of Frame Elements
80. View Analysis Result Contour in Slab Panels
81. Concrete Design
82. Concrete Frame Design and View Design Results
83. Steel Design Steel
84. Frame Design and View
85. Design Results
86. View Design Parameters
87. View Load Combination for Concrete Frame Design
88. View Reinforcement for Frame Design
89. View Percentage Steel for Frame Design
90. Steel Frame Design and View Design Results
91. View Load Combination for Steel Frame Design.
Following are detailed Syllabus covered in Response Spectrum Analysis & Design of G+9 Residential Building:-
1. Defining RSA functions.
2. Manual calculation of sa/g acceleration values
3. Creating Dynamic loads.
4. Creating Dynamic modal cases.
5. Perform RSA Analysis & Scale factor correction of static & Dynamic base reactions.
6. Correcting story deflections, drifts, and story torsional effects in modal by shear wall or bracings insertion.
7. Performing structural design