Ansys - Finite Element Analysis And Industrial Applications
Last updated 10/2021
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 14.01 GB | Duration: 24h 3m
Last updated 10/2021
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 14.01 GB | Duration: 24h 3m
Linear Static Analysis with Finite Element Method
What you'll learn
Fundamentals of Ansys Workbench
Defining Materials
Creating and Importing Geometry
Creating Parameters and Discussing the Effects of Parameters to Analysis.
Optimization Based On Parameters
Topology Optimization and Reducing Weight
Meshing in Details
Boundary Conditions (Loads and Supports)
Contact and Joint Types
Static Structural Section in Details
Structural Analysis
Hydrostatic Analysis
Connection Equipment Analysis
Static Linear Analysis
SpaceClaim
Simplifying the Geometry in SpaceClaim
Preparing the Geometry for Meshing and Contact Surfaces in SpaceClaim
Meshing in Advanced Level
Mesh Tips and Tricks in Advanced Level
Contacts in Advanced Level
Creating Submodel
Industrial Applications
Requirements
Having an Ansys Workbench
Being a student in Mechanical, Mechatronics, Manufacturing, or Civil Engineering.
Being curious about FEA or Ansys
Description
–- Check My Website (importfea) –-We are going to make a detailed examination of linear static analysis in the tutorial. After learning the necessary fundamentals, we will focus on the static structural section. In the static structural section, we'll see all of the loads, supports, contacts, joints, and mesh types with applications.Versions 19.2, 19.3, and 2020R2 were used in the tutorial. For more detailed information and surprises, don't forget to visit my Instagram page (@ansysegitim) :)We can gather the tutorial under 2 topics as introductory and advanced tutorials. We will be learning the topics below for the introductory course. Before reviewing these topics, I need to make it clear to you. First of all, let's talk about what the tutorial does not include :)I did not include the non-linear analysis at this stage, since the topic is advanced. You are not going to see crashed trucks, plate-piercing bullets, flying aircraft, rockets, tanks or rifles, etc in the tutorial. All of these need separate courses. For this reason, learning them as a beginner in 10 minutes, 30 minutes, or 1-hour courses only teaches you to make colorful animations of that truck or plane :) The topics require mastery separately.Now, let's examine what awaits us in the course. In the introduction part, my aim is to teach to use the Ansys. Each of the lessons is created with the aim of learning one specific topic within Ansys and is focused on that purpose. For example, if we are trying to learn the topic of boundary conditions, then we don't struggle to get fine mesh quality or structures or we don't need to prepare the model for meshing while we are learning the topic of contacts. You will get a better understanding of the applications after the theoretical lessons.In the tutorial, we will not only go to the analysis results with a few mouse clicks, we will reach the results by explaining which option we used and why we used it. Thus, after a while, you will be able to make many applications yourself.I have also covered in detail topology optimization (weight reduction) which is indispensable for design.I have also covered the topic of optimization. You will learn how to keep stresses below your desired value while improving the design by creating parameters.I have included in detail truss systems and structural analysis which are indispensable for static analysis.You will learn how to analyze fasteners especially bolted connections. I also added many more topics and applications related to static analysis to the first section of the tutorial In the second section, the advanced sections, we will be examining the following topics.Firstly, I wanted to make a reminder by going back to the fundamentals of engineering concepts from the very beginning. The fundamentals are topics that we must know and even develop. Under the title of fundamentals of engineering, you will see the topics of Stress, Strain, Young's modulus, Poisson's Ratio, and some important Material Properties. I explained all the commands separately that we will use frequently while preparing the geometries on SpaceClaim. We will discuss how to prepare a geometry/model, what should we pay attention to while preparing a geometry, what we should simplify, what should we keep in the geometry, and how to prepare geometry for meshing. I tried to explain the topic of advanced mesh in great detail from the scratch in advanced level mesh lessons. I started by teaching the mesh element types, the element orders, the effect of element types on the results, how to find the optimized element size, and how to make a mesh convergence study. I also gave you the tips that FEA Experts frequently use to obtain fine mesh structures. I suggest you definitely don't miss this part. Under the title of advanced contact, we discussed the questions of what we should pay attention to while creating contact regions, which contact type is decent for which structures and what sub-settings come out while creating contact regions, how does it affect the results, when to use it and when to ignore it.We examined the topic of submodeling which is indispensable for an analysis. You will learn how to create a submodel and what you should pay attention to while creating them. And the final and great topic is the Industrial Applications. You should definitely not miss it. You will see some real-world engineering problems that I have run the analysis as a structural analysis engineer. We examined these projects in detail and examined how we solved them from the very beginning to the very end of the analysis (The dimensions of the projects were changed and some changes were made to ensure that they were not exactly the same but you will get the main idea).Goodbye for now…
Overview
Section 1: Finite Element Method
Lecture 1 Finite Element Method
Section 2: Ansys Workbench
Lecture 2 Interface of the Workbench
Lecture 3 Defining Materials
Lecture 4 Creating and Imporing Geometry.
Lecture 5 Basic Example
Section 3: Topology Optimization and Design Parameters
Lecture 6 Paramter and Optimization
Lecture 7 Example for Parameters in 2D Geometry
Lecture 8 Topology Optimization - 1
Lecture 9 Topology Optimization - 2
Lecture 10 Symmetry Feature - 1
Lecture 11 Symmetry Feature - 2
Lecture 12 2D Wrench
Section 4: Interface of the Mechanical
Lecture 13 Interface of the Mechanical
Lecture 14 Pre-Processing Steps
Lecture 15 Object Generator
Lecture 16 Frame Example - Share Topology Feature
Lecture 17 Truss Systems Example
Lecture 18 Vase Example - Hydrostatic Pressure
Section 5: Introduction to Mesh
Lecture 19 Global Mesh
Lecture 20 Local Mesh - 1
Lecture 21 Local Mesh - 2
Lecture 22 Torsion Example
Lecture 23 Bike Crank Example
Lecture 24 Creating Sensitive Mesh Structures
Section 6: Boundary Conditions
Lecture 25 Support Types
Lecture 26 Load Types
Lecture 27 Structural Analysis Example
Lecture 28 Garden Fountains Example - Hydrostatic Pressure
Section 7: Contact Types
Lecture 29 Contact Types
Lecture 30 Stand Example
Lecture 31 Plate-Bar Example
Lecture 32 Clevis Example
Section 8: Joint Types
Lecture 33 Joint Types
Lecture 34 Pendulum Example
Lecture 35 Piston Example
Section 9: Examples
Lecture 36 Practice 1 - Bended Plate
Lecture 37 Practice 2 - Bearing Load
Lecture 38 Practice 3 - Bridge
Lecture 39 Practice 4 - Connection Bracket
Lecture 40 Practice 5 - Supporting Bracket
Lecture 41 Practice 6 - Rotor
Lecture 42 Practice 7 - Arm Shaft
Lecture 43 Practice 8 - Flange Connection
Lecture 44 Practice 9 - Connection Plates
Lecture 45 Practice 10 - Bolt Pretension
Lecture 46 Practice 11 - F1 Motors Nozzle
Section 10: Advanced 1 - Fundamentals of Engineering
Lecture 47 Stress and Strain
Lecture 48 Young's Modulus and Poisson's Ratio
Lecture 49 Material Properties
Section 11: Advanced 2 - SpaceClaim and Preparing/Simplifying Geometry
Lecture 50 SpaceClaim
Lecture 51 Preparing and Simplifying Geometry
Section 12: Advanced 3 - Mesh in Details
Lecture 52 Element Types and Orders
Lecture 53 Differences in Dimensions (3D, 2D, and 1D)
Lecture 54 Optimized Element Number
Lecture 55 Comparison of TET and HEX Elements
Lecture 56 Mesh Convergence
Lecture 57 Mesh Tips - 1
Lecture 58 Mesh Tips - 2
Lecture 59 Mesh Tips - 3
Lecture 60 Mesh Tips - 4
Lecture 61 Mesh Tips - 5
Section 13: Advanced 4 - Contact Regions
Lecture 62 Advanced Contact Regions
Section 14: Advanced 5 - Submodelling
Lecture 63 Submodeling
Section 15: Advanced - 6 Industrial Applications 1 - Beam-Column Connections
Lecture 64 Model Preparation
Lecture 65 Boundary Conditions
Lecture 66 Contact
Lecture 67 Mesh
Lecture 68 Post Processing
Lecture 69 Creating Submodel
Lecture 70 Preparing Submodel
Lecture 71 Submodel - Boundary Conditions
Lecture 72 Submodel - Mesh 1
Lecture 73 Submodel - Mesh 2
Lecture 74 Submodel - Mesh 3
Lecture 75 Submodel - Mesh 4
Lecture 76 Submodel - Contact
Lecture 77 Submodel - Post Processing
Section 16: Advanced 7 - Industrial Applications 2 - Industrial Stair
Lecture 78 Model Preparation
Lecture 79 Material Properties
Lecture 80 Boundary Conditions
Lecture 81 Mesh - 1
Lecture 82 Mesh - 2
Lecture 83 Mesh - 3
Lecture 84 Contact
Lecture 85 Contact Status Checking with Modal Analysis
Lecture 86 Post Processing
Section 17: Bonus Content - What's Next?
Lecture 87 Buckling in Ansys
Studens in Engineering,Everyone who wants to learn FEA or Ansys