200 users
STAAD.Pro is extensively used to automate, accelerate, and improve accuracy in the process of designing a variety of structures. Professionals use this tool in the industry to design and model structures according to design codes. On top of this, users can also perform structural analysis and mimic loading conditions that structures will experience in the real-world. Knowing how to work with STAAD.Pro when it comes to the design of buildings and other structures is a vital software skill for civil engineers and other professionals working in the industry.
9/10 of our learners achieve their learning objectives after successful course completion*
STAAD.Pro is extensively used to automate, accelerate, and improve accuracy in the process of designing a variety of structures. Professionals use this tool in the industry to design and model structures according to design codes. On top of this, users can also perform structural analysis and mimic loading conditions that structures will experience in the real-world. Knowing how to work with STAAD.Pro when it comes to the design of buildings and other structures is a vital software skill for civil engineers and other professionals working in the industry.
To provide a comprehensive understanding of the ins and outs of STAAD.Pro from a professional and industrial perspective, Skill-Lync offers this course on the Analysis and Design of Buildings using STAAD.Pro. By taking this course, learners will… Understand how to work with the STAAD.Pro GUI. Design and model RCC and steel structures according to IS Codes using STAAD.Pro. Calculate different loads (dead load, live load, seismic load, wind loads) acting on a structure according to IS Codes. Understand the parameters that go into the design of a building, and be able to interpret the output. Be able to use STAAD Advanced Concrete Design for design calculations and documentation.
Introduction to Basics
User interface (UI) of the software
Types of structures
Material specifications
Support conditions
Design parameters
Analysis and post processing options available in STAAD.Pro
Modeling of RC Building
Steps involved in modelling, designing, and analysing RC structures
Structure’s framework
Structural elements
Input Generation
Material specifications
Assigning supports and constants
Design parameters of the model under study.
Analysis of buildings according to requirements
Load Generation
Load cases and load combinations
Load calculations
Dead load
Live load
Wind load
Applying calculated load to software models
Analysis of the Model
Complete analysis of the structure
Post-processing results
Interpretation of results
Extracting shear force diagram (SFD), bending moment diagram (BMD), reactions, and displacements for design purposes
Output Interpretation
Design of structural elements (slab, beam, column, and foundation) using STAAD.Pro
Verifying results with manual calculation sheets
Introduction to Steel Structures
Types of steel structures
Components in a steel building
Rafters
Purlins
Side wall and end wall girts
Column
Bay spacing
Cladding
Modelling of Steel Building
Study of a steel structure
Modelling the structure using the coordinate method
Input Generation
Input parameters according to specifications and standards.
Calculation of loads in a steel building using Microsoft Excel
Applying the calculated load on a model
Analysis of the Model
Input parameters
Design specifications
Analysis of structures
Result Interpretation
Interpretation of the output file generated
Extraction of results for each element in the building
BMD
SFD
Serviceability check
Documentation & Verification of the Output
Representing analysis in the form of documents and drawings
Factors to be considered when representing the design (Detailing drawing with cross section (C/S) and longitudinal section (L/S))
Cross-checking extracted results from software with manual calculations
© 2024. All rights reserved.
Automated page speed optimizations for fast site performance