FEA and ANSYS Chapter 2. Training Manual October 30, 2001 Inventory #001569 2-2 Chapter 2 - FEA and ANSYS What is FEA? Finite Element Analysis is a way.

Slides:



Advertisements
Similar presentations
Finite element method Among the up-to-date methods of stress state analysis, the finite element method (abbreviated as FEM below, or often as FEA for analyses.
Advertisements

Electronics Cooling MPE 635 Mechanical Power Engineering Dept.
ENE 428 Microwave Engineering
(Industrial Electronics) Engr. M. Laiq Ur Rahman
Breakdown in Solid Dielectrics
Abhyankar Consultancies CAE and Design Consultants.
Lecture 2 – Finite Element Method
SolidWorks Simulation. Dassault Systemes 3 – D and PLM software PLM - Product Lifecycle Management Building models on Computer Engineering Analysis and.
Lecture 101 Introduction to Energy Storage Elements: The Capacitor.
Chapter 1: Introduction and Basic Concepts
Storey: Electrical & Electronic Systems © Pearson Education Limited 2004 OHT 13.1 Capacitance and Electric Fields  Introduction  Capacitors and Capacitance.
Computer Aided Engineering Presented by Jasmin Duljkovic Boise State University.
FEA and ANSYS Module 2. Training Manual January 30, 2001 Inventory # FEA and ANSYS Overview In this chapter, we will define Finite Element Analysis.
Lecture B Electrical circuits, power supplies and passive circuit elements.
Chapter 5 Vibration Analysis
Design & Technology Center Vedam DAY - 1: Introduction to Structural Analysis and FEM DAY - 2: Introduction to ANSYS structure classic GUI: DAY - 3: Pre-processing.
The Finite Element Method
Electrical Fundamentals
Unit 27 Transformers. Objectives –After completing this chapter, the student should be able to: Describe how a transformer operates. Explain how transformers.
© 2008 Snap-on Incorporated; All Rights Reserved.
Lecture 2 Most basic facts from Electricity needed for understanding telecommunications Local transmission lines in the telephone system Decibels Signals.
PY212 Electricity and Magnetism I. Electrostatics.
SRAC 2001 Presented by: Kiko (Application Engineer) Intelligent CAD/CAM Technology LTD. Cosmos World.
12 Transmission Lines.
Chapter Five Vibration Analysis.
Applied mechanics of solids A.F. Bower.
APPLIED MECHANICS Lecture 13 Slovak University of Technology
ANSYS for MEMS by Manjula1 FEM of MEMS on ANSYS MEMS Summer 2007 Why FEM for MEMS? Features in ANSYS Basic Procedures Examples.
By: Narendra Babu N M110247ME THERMAL ANALYSIS OF MICROPROCESSOR.
Lecture 2.0: Introduction to Process Control Systems and Modeling Eng R. L. Nkumbwa Copperbelt University /16/ Eng R. L. Nkumbwa 2010.
Image courtesy of National Optical Astronomy Observatory, operated by the Association of Universities for Research in Astronomy, under cooperative agreement.
HEAT TRANSFER FINITE ELEMENT FORMULATION
(Biomedical Applications)
Lecture 5.
HCMUT 2004 Faculty of Applied Sciences Hochiminh City University of Technology The Finite Element Method PhD. TRUONG Tich Thien Department of Engineering.
Lecture 9: Modeling Electromechanical Systems 1.Finish purely electrical systems Modeling in the Laplace domain Loading of cascaded elements 2.Modeling.
Discretization Methods Chapter 2. Training Manual May 15, 2001 Inventory # Discretization Methods Topics Equations and The Goal Brief overview.
ADINA (Biomedical Applications). CAE ENGINEERING TOTAL SOLUTION 2 ADINA CONTENTS FSI 2 Application 3 4 Introduction 1 Module.
Chapter 6 Overview. Maxwell’s Equations In this chapter, we will examine Faraday’s and Ampère’s laws.
Introduction Chapter 1. Training Manual March 15, 2001 Inventory # Prerequisites Prerequisites for the Heat Transfer Seminar include: –Successful.
6. Maxwell’s Equations In Time-Varying Fields
General Analysis Procedure Chapter 4. Training Manual October 30, 2001 Inventory # Chapter 4 - General Analysis Procedure Overview The objective.
COUPLED ANALYSES Chapter 7. Training Manual May 15, 2001 Inventory # Fluid-Structure Analysis “One Way” Analysis –Structural deformation effect.
Craig T. Riesen Energy Workshop II 1 Electricity & Generation Basics of Electricity and Electrical Transmission Transmission Generation electrons.
Chapter 1. Essential Concepts
FEASIBILITY ANALYS OF AN MHD INDUCTIVE GENERATOR COUPLED WITH A THERMO - ACOUSTIC ENERGY CONVERSION SYSTEM S. Carcangiu 1, R. Forcinetti 1, A. Montisci.
Systems Dynamics Dr. Mohammad Kilani Class 1 Introduction.
ANSYS. Overview of ANSYS It is an engineering simulation software developed in 1970 by Dr. John A. Swanson It was developed to use finite element analysis.
CFD Simulation & Consulting Services Hi-Tech CFD | Voice: Optimizing Designs of Industrial Pipes, Ducts and.
Introduction Chapter One. Training Manual Introduction February 2, 2004 Inventory # Welcome! Welcome to the ANSYS Workbench introductory training.
A Field Construction Technique to Efficiently Model the Dynamic Vector Forces within Induction Machines Dezheng Wu, Steve Pekarek School of Electrical.
RF and Microwave Network Theory and Analysis
The rate of change of velocity.
Electrical circuits, power supplies and passive circuit elements
TRANSDUCERS PRESENTATION BY: Dr.Mohammed Abdulrazzaq
ANSYS Basic Concepts for ANSYS Structural Analysis
Transient Analysis of Heat Transfer and Fluid Flow in a Polymer-based Micro Flat Heat Pipe with Hybrid Wicks Mehdi Famouria, Gerardo Carbajalb, Chen Lia.
Chapter Electromechanical Systems 6. Chapter Electromechanical Systems 6.
Finite Element Application
Electrical circuits, power supplies and passive circuit elements
ELEC 401 MICROWAVE ELECTRONICS Lecture 3
FEA Introduction.
ELEC 401 MICROWAVE ELECTRONICS Lecture 3
Structured Modeling of Mechatronic Systems in which you meet the modest but talented multiport component.
ECE699 – 004 Sensor Device Technology
Beam Analysis with ANSYS
Chapter 2 Rudiment of Structural Analysis and FEM
PY212 Electricity and Magnetism
Realistic multiphysics analysis
Presentation transcript:

FEA and ANSYS Chapter 2

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS What is FEA? Finite Element Analysis is a way to simulate loading conditions on a design and determine the design’s response to those conditions. The design is modeled using discrete building blocks called elements. –Each element has exact equations that describe how it responds to a certain load. –The “sum” of the response of all elements in the model gives the total response of the design. –The elements have a finite number of unknowns, hence the name finite elements. Historical Note The finite element method of structural analysis was created by academic and industrial researchers during the 1950s and 1960s. The underlying theory is over 100 years old, and was the basis for pen-and-paper calculations in the evaluation of suspension bridges and steam boilers.

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS...What is FEA? The finite element model, which has a finite number of unknowns, can only approximate the response of the physical system, which has infinite unknowns. –So the question arises: How good is the approximation? Physical SystemF.E. Model –Unfortunately, there is no easy answer to this question. It depends entirely on what you are simulating and the tools you use for the simulation. We will, however, attempt to give you guidelines throughout this training course.

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS...What is FEA? Why is FEA needed? To reduce the amount of prototype testing –Computer simulation allows multiple “what-if” scenarios to be tested quickly and effectively. To simulate designs that are not suitable for prototype testing –Example: Surgical implants, such as an artificial knee The bottom line: –Cost savings –Time savings… reduce time to market! –Create more reliable, better-quality designs

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS About ANSYS ANSYS is a complete FEA software package used by engineers worldwide in virtually all fields of engineering: –Structural –Thermal –Fluid, including CFD (Computational Fluid Dynamics) –Electrical / Electrostatics –Electromagnetics A partial list of industries in which ANSYS is used: –Aerospace –Automotive –Biomedical –Bridges & Buildings –Electronics & Appliances –Heavy Equipment & Machinery –MEMS - Micro Electromechanical Systems –Sporting Goods

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS ANSYS/Multiphysics is the flagship ANSYS product which includes all capabilities in all engineering disciplines. There are three main component products derived from ANSYS/Multiphysics: –ANSYS/Mechanical - structural & thermal capabilities –ANSYS/Emag - electromagnetics –ANSYS/FLOTRAN - CFD capabilities Other product lines: –ANSYS/LS-DYNA - for highly nonlinear structural problems –DesignSpace - an easy-to-use design and analysis tool meant for quick analysis within the CAD environment –ANSYS/ProFEA - for ANSYS analysis & design optimization within Pro/ENGINEER

Training Manual October 30, 2001 Inventory # ANSYS/Structural ANSYS/Professional ANSYS/ProFEA DesignSpace Chapter 2 - FEA and ANSYS …About ANSYS ANSYS/ED ANSYS/University ANSYS/PrepPost ANSYS/ Multiphysics ANSYS/ FLOTRAN ANSYS/Emag ANSYS/LS-DYNA ANSYS/Mechanical

Training Manual October 30, 2001 Inventory # Compression of a Hyperelastic Seal Chapter 2 - FEA and ANSYS …About ANSYS Structural analysis is used to determine deformations, strains, stresses, and reaction forces. Static analysis –Used for static loading conditions. –Nonlinear behavior such as large deflections, large strain, contact, plasticity, hyperelasticity, and creep can be simulated.

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Dynamic analysis –Includes mass and damping effects. –Modal analysis calculates natural frequencies and mode shapes. –Harmonic analysis determines a structure’s response to sinusoidal loads of known amplitude and frequency. –Transient Dynamic analysis determines a structure’s response to time-varying loads and can include nonlinear behavior. Other structural capabilities –Spectrum analysis –Random vibrations –Eigenvalue buckling –Substructuring, submodeling Mode Shape Animation

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Explicit Dynamics with ANSYS/LS-DYNA –Intended for very large deformation simulations where inertia forces are dominant. –Used to simulate impact, crushing, rapid forming, etc. Impact Analysis of a Vehicle Crash Test

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Thermal analysis is used to determine the temperature distribution in an object. Other quantities of interest include amount of heat lost or gained, thermal gradients, and thermal flux. All three primary heat transfer modes can be simulated: conduction, convection, radiation. Steady-State –Time-dependent effects are ignored. Transient –To determine temperatures, etc. as a function of time. –Allows phase change (melting or freezing) to be simulated. Transient Temperature of a Warming Clothes Iron

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Electromagnetic analysis is used to calculate magnetic fields in electromagnetic devices. Static and low-frequency electromagnetics –To simulate devices operating with DC power sources, low-frequency AC, or low-frequency transient signals. –Example: solenoid actuators, motors, transformers –Quantities of interest include magnetic flux density, field intensity, magnetic forces and torques, impedance, inductance, eddy currents, power loss, and flux leakage.

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS High-frequency electromagnetics –To simulate devices with propagating electromagnetic waves. –Example: microwave and RF passive components, waveguides, coaxial connectors –Quantities of interest include S-parameters, Q-factor, Return loss, dielectric and conducting losses, and electric and magnetic fields. Electric field (EFSUM) in a coaxial cable

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Electrostatics –To calculate the electric field from voltage or charge excitation. –Example: High voltage devices, micro-electromechanical systems (MEMS), transmission lines –Typical quantities of interest are electric field strength and capacitance. Current Conduction –To calculate current in a conductor from an applied voltage Circuit Coupling –To couple electric circuits with electromagnetic devices

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Types of electromagnetic analysis: –Static analysis calculates magnetic fields due to direct current (DC) or permanent magnets. –Harmonic analysis calculates magnetic fields due to alternating current (AC). –Transient analysis is used for time-varying magnetic fields.

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Computational Fluid Dynamics (CFD) –To determine the flow distributions and temperatures in a fluid. –ANSYS/FLOTRAN can simulate laminar and turbulent flow, compressible and incompressible flow, and multiple species. –Applications: aerospace, electronic packaging, automotive design –Typical quantities of interest are velocities, pressures, temperatures, and film coefficients. Velocity of Fluid in a Duct Pressure Distribution on a Football

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About ANSYS Acoustics –To simulate the interaction between a fluid medium and the surrounding solid. –Example: speakers, automobile interiors, sonars –Typical quantities of interest are pressure distribution, displacements, and natural frequencies. Contained-Fluid Analysis –To simulate the effects of a contained, non-flowing fluid and calculate hydrostatic pressures due to sloshing. –Example: oil tankers, other liquid containers Heat and Mass Transport –A one-dimensional element is used to calculate the heat generated by mass transport between two points, such as in a pipe.

Training Manual October 30, 2001 Inventory # Deflection of a bi-metal bar due to heating Chapter 2 - FEA and ANSYS …About ANSYS Coupled-Field Analysis considers the mutual interaction between two or more fields. The fact that each field depends upon another makes it impossible to solve each separately, therefore you need a program that can solve both physics problems by combining them. Examples: –Thermal-stress analysis –Piezoelectrics (electric & structural ) –Acoustics (fluid & structural) –Thermal-electric analysis –Induction heating (magnetic and thermal) –Electrostatic-structural analysis

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS About the Company ANSYS, Inc. Developer of ANSYS family of products Headquartered in Canonsburg, PA - USA (south of Pittsburgh)

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About the Company ANSYS Support Distributors (ASDs) Sales and support network for ANSYS Over 75 offices worldwide Local expertise for ANSYS consulting and training

Training Manual October 30, 2001 Inventory # Chapter 2 - FEA and ANSYS …About the Company ANSYS Support Coordinator (ASC) Contact for ANSYS at your company site Focal point for ANSYS correspondence; software updates, error notices, newsletter and other mailings, etc. For more information about ANSYS and the company: On-line documentation Training manuals from other ANSYS courses