Altair Hyperwork - Modelling - Meshing - Run Solver File

learn with us HyperWorks is an analysis and Optimization Solution

What you'll learn

FEM Theory

Meshing of 1d 2d 3d

Create and set-up Finite element models for analysis

Improve knowledge of meshing

Topology, size, Shape Optimization

learner HyperWork tutorial

learner Hyperwork CFD

Requirements

Basic CAD And 3d modelling

Install latest or old version Altair HyperWork software student Version and licence version

Description

Hyperworks is a complete CAE software made by Altair engineering. It consists all the modules of CAE i.e. modelling, meshing, solver. It is a complete package of finite element procedure. Pre-processing, Solving and Post-processing can be done using Hyperworks.Altair HyperWorks provides the most comprehensive, open-architecture CAE solution in the industry including best-in-class modeling, analysis and optimizatio.HyperWorks line of software, including:OptiStruct - Structural Analysis Solver (linear and non-linear); solution for structural design and optimizationRADIOSS - Structural Analysis Solver (highly non-linear problems under dynamic loadings); an industry standard for automotive crash and impact analysisMotionView - Solver-neutral Multi-body Pre-processorMotionSolve - Multi-body Solver; an integrated solution to analyze and optimize multi-body system performanceHyperXtrude - Metal & Polymer Extrusion Solver; an advanced solver for manufacturing process simulations and validationsHyperForm - Metal Forming SolverHyperMesh, HyperCrash, Simlab, HyperView, HyperGraph - CAE Pre & Post Processing[1]HyperStudy - Design of Experiments and Multi-disciplinary Design OptimizationHyperMath - Mathematical Analysis EnvironmentAcuSolve - General-purpose Finite Element Based CFD SolverFEKO - 3D Electromagnetic Solver

Overview

Section 1: Theory of FEA and CAE

Lecture 1 Introduction

Lecture 2 How to decide element type

Lecture 3 Can we solve same problem using 1-D, 2-D and 3D element

Lecture 4 How to do meshing in critical area

Lecture 5 3d Element

Lecture 6 Minimum element length using in time and crease calculation analysis

Lecture 7 Material and property Information

Section 2: 1D Meshing

Lecture 8 1D Meshing Introduction

Lecture 9 Create Hyper-beam

Lecture 10 Create HyperBeam I Solving the problem usinng 10 rod element

Lecture 11 Create bar element

Lecture 12 Concept of C-D-E-F point

Lecture 13 Bar element analysis

Lecture 14 Create bar element using rectangular cross section

Lecture 15 Different of dof (Degree of freedom)

Lecture 16 Roll cage Analysis

Section 3: 2D Meshing

Lecture 17 2D Meshing topic cover in session

Lecture 18 how to open and save file In HyperMesh

Lecture 19 Working with panel

Lecture 20 Organizing a model

Lecture 21 Importing and repairing CAD

Lecture 22 Create a Mid-surface

Lecture 23 Simplifying Geometry

Lecture 24 Refining topology to achieve a quality mesh

Lecture 25 Auto Meshing panel

Lecture 26 Meshing without surfaces

Lecture 27 Create a Meshing in Curved surfaces

Lecture 28 Checking and editing Mesh

Section 4: 3D Meshing

Lecture 29 Create and Edit solid geometry

Lecture 30 Perform Tetra Meshing

Lecture 31 Creating a hex-penta mesh using surfaces part 1

Lecture 32 Creating a hex-penta mesh using surfaces part 2

Lecture 33 Creating a hexahedral mesh using the solid map function

Lecture 34 Using the tetramesh process manager

Section 5: Analysis and Post Processing

Lecture 35 Linear static analysis of a plate with a hole Part 1

Lecture 36 Linear static analysis of a plate with a hole part 2

Lecture 37 Thermal stress analysis of a coffee pot lid

Lecture 38 Normal modes analysis of a splash shield

Lecture 39 3D Inertia relief analysis using RADIOSS

Lecture 40 3D Buckling analysis using RADIOSS

Lecture 41 Connection of dissimilar meshes using CWELD element

Lecture 42 Analysis of a composite aircraft structure using PCOMPG

Lecture 43 Direct frequency response analysis of a flat plate

Lecture 44 Model frequency response analysis of a flat plate

Lecture 45 Acoustic analysis of a half car model

Lecture 46 Random response analysis of a flat plate

Lecture 47 Nonlinear gap analysis of an airplane wing rib

Lecture 48 Direct transient dynamic analysis of a bracket

Section 6: Topology Optimization

Lecture 49 Design concept for a structural C-clip

Lecture 50 Design concept for a structural C-clip with minimum member size control

Lecture 51 Topology optimization for an automotive control arm

Lecture 52 Increasing natural frequencies of an automotive splash shield with ribs

Lecture 53 Control arm topology optimization with draw direction constraints

Lecture 54 Sport weld reduction using CWELD and 1-D Topology optimization

Section 7: Use 3D Models in practice

Lecture 55 Practice models

Computer aided design & engineering,learn practical application of FEA and CAE,Aerospace Engineering,Mechanical and Industrial Engineer,Learn Meshing and Analysis of Mechanical System,Automobile Engineers