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Updated in [October 16th, 2023]
What does this course tell?
(Please note that the following overview content is from the original platform)
In this course you will learn ETABS software, a worldwide structural design software, starting from the basic modelling techniques in ETABS to exploring many available advanced options, techniques, tools and guides for reinforced concrete structural design with hands on parallel exercise on a 20-storey building for clearer concepts and understanding like no other.The course is prepared with extreme care considering the best sequence of steps and topics for easy and proper learning . Although the course is focused on ETABS, but the structural design concepts and steps are using ACI design code and ASCE loading code for references of parameters. The course focuses on the design practice and knowledge utilized on professional level worldwide . Here is a brief syllabus for the courseETABS user Interface, viewing options, definitions of keywords, shortcuts, tools and tipsDifference between shell thin, thick and membrane, Rigid and Semi-rigid diaphragms, Import grids from Autocad/Revit, Concept of envelope (Exercise on moment, shear and axial force envelope)Defining rectangular, cylindrical grids, material properties, Frame sections, Define Slab and wall sectionsModelling framing in ETABS (Draw beams, columns, slabs, walls and replicate on stories, using viewing tools, hide/unhide elements with exercise file, Automatic and manual meshing of slab and wall, Model reviewing, Creating selection groups, Merge multiple ETABS models)Applying Loading (Defining and assigning load patterns, load cases, load combinations, seismic loads (ASCE 7-10), mass source, Diaphragm, wind loads (ASCE 7-10), P-Delta options )General Analysis and Design (Assign and draw slab strips (DDM), assign pier to walls, set code preferences, Analysis results (Forces, Deformation and stresses), Modal Analysis )Analysis and Design Results interpretationAnalysis and design of reinforced concrete columnsAnalysis and design of reinforced concrete beamsAnalysis and design of reinforced concrete shear walls modelling and designAnalysis and design of Flat plate slab, Flat slab with drop panels and Two-way slab on beamsAnalysis results and interpretation for forces, modelling errors and their solutions and displacementsServiceability and Irregularities (Seismic drift check, Wind drift check, Torsional irregularity check & Amplification, Stiffness irregularity check, Mass/Weight irregularity check and limits, orthogonal directional combinations)Linear Dynamic Analysis (What is LDP, concepts of dynamic analysis)Response Spectrum (Response spectrum analysis procedure, scaling of dynamic base shear and analysis results)Linear Time History analysis (Procedure, Importing seismograms toEtabs, Time history matching to site Response Spectrum, scaling of dynamic base shear, analysis results and why & when to use dynamic analysis)
We considered the value of this course from many aspects, and finally summarized it for you from two aspects: skills and knowledge, and the people who benefit from it:
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What skills and knowledge will you acquire during this course?
During this course, the learner will acquire the following skills and knowledge:
1. Familiarity with the ETABS software, a widely used structural design software.
2. Understanding of basic modelling techniques in ETABS.
3. Exploration of advanced options, techniques, tools, and guides for reinforced concrete structural design.
4. Hands-on experience in designing a 20-story building using ETABS.
5. Clear understanding of structural design concepts and steps using ACI design code and ASCE loading code as references.
6. Knowledge of ETABS user interface, viewing options, definitions of keywords, shortcuts, tools, and tips.
7. Differentiation between shell thin, thick, and membrane elements, as well as rigid and semi-rigid diaphragms.
8. Ability to import grids from Autocad/Revit and understand the concept of envelope (moment, shear, and axial force envelope).
9. Proficiency in defining rectangular and cylindrical grids, material properties, frame sections, and slab and wall sections.
10. Expertise in modelling framing elements such as beams, columns, slabs, and walls, and replicating them on multiple stories.
11. Understanding of viewing tools, hiding/unhiding elements, automatic and manual meshing of slabs and walls, model reviewing, and creating selection groups.
12. Knowledge of applying loading, including load patterns, load cases, load combinations, seismic loads (ASCE 7-10), wind loads (ASCE 7-10), and P-Delta options.
13. Ability to perform general analysis and design tasks, such as assigning and drawing slab strips, assigning piers to walls, setting code preferences, and interpreting analysis results.
14. Proficiency in analyzing and designing reinforced concrete columns, beams, shear walls, flat plate slabs, flat slabs with drop panels, and two-way slabs on beams.
15. Interpretation of analysis results for forces, modeling errors, and their solutions, as well as displacements.
16. Understanding of serviceability and irregularities checks, including seismic drift, wind drift, torsional irregularity, stiffness irregularity, and mass/weight irregularity.
17. Knowledge of linear dynamic analysis concepts, including linear time history analysis and response spectrum analysis.
18. Ability to import seismograms to ETABS, match them to site response spectrum, scale dynamic base shear, and interpret analysis results.
19. Understanding of when and why to use dynamic analysis in structural design.
Who will benefit from this course?
This course will benefit individuals who are interested in or working in the field of structural design and engineering. Specifically, it will be beneficial for:
1. Structural Engineers: The course provides a comprehensive understanding of ETABS software, which is widely used in the structural design industry. It covers various advanced options, techniques, and tools for reinforced concrete structural design, allowing structural engineers to enhance their skills and knowledge in this area.
2. Architects: Architects who are involved in the design of high-rise buildings can benefit from this course as it focuses on the design practice and knowledge utilized on a professional level worldwide. It provides insights into the structural design concepts and steps using ACI design code and ASCE loading code as references.
3. Civil Engineers: Civil engineers who are involved in the design and analysis of buildings can benefit from this course as it covers topics such as modeling framing, applying loading, analysis and design of reinforced concrete columns, beams, shear walls, and slabs. It also includes analysis and interpretation of results, as well as considerations for serviceability and irregularities.
4. Construction Professionals: Construction professionals, such as project managers or site engineers, can benefit from this course as it provides a thorough understanding of the design process and considerations for high-rise buildings. This knowledge can help them in coordinating with structural engineers and ensuring the successful implementation of the design.
5. Students and Researchers: Students pursuing a degree in civil engineering or related fields can benefit from this course as it provides a practical understanding of structural design using ETABS software. Researchers in the field of structural engineering can also benefit from the advanced topics covered in the course, which can enhance their knowledge and skills in this area.
Course Syllabus
Introduction
ETABS Basics
Defining Structural Properties
Modelling Tools
Additional Modelling tools
Applying Gravitational Loading
Structural Analysis and Design
Reinforced Concrete Columns
Reinforced Concrete Beams
Reinforced Concrete slabs
Reinforced Concrete Shear walls systems
Serviceability and Irregularities
Linear Dynamic Analysis