Thermo-mechanics J. Cugnoni, LMAF / EPFL 2009.

Slides:



Advertisements
Similar presentations
© 2011 Autodesk Freely licensed for use by educational institutions. Reuse and changes require a note indicating that content has been modified from the.
Advertisements

Computer Aided Thermal Fluid Analysis Lecture 10
Example: Microrobot leg 3D. Introduction This model shows the movement of a silicon micro-robot leg due to thermal expansion as a function of time. The.
AE4131 ABAQUS Lecture Part V
Finite Element Primer for Engineers: Part 2
1 Deformation and damage of lead free materials and joints J. Cugnoni*, A. Mellal*, Th. J. J. Botsis* * LMAF / EPFL EMPA Switzerland.
MECh300H Introduction to Finite Element Methods
Identified Company (CompositeX) to manufacture Custom Composite Pressure Vessel ● Working pressure 1000psi ● Holds 8 kg Nitrous Oxide ● 700 cubic inch.
Thermal analysis There is a resemblance between the thermal problem and the stress analysis. The same element types, even the same FE mesh, can be used.
Al 2 O 3 Post Combustion Chamber Post Combustion Chamber ANSYS Thermal Model (Embedded Fuel Grain Concept) Outer radius: 1.25” ( m) Inner radius:
1 Deformation and damage of lead free materials and joints J. Cugnoni*, A. Mellal*, Th. J. J. Botsis* * LMAF / EPFL EMPA Switzerland.
FE Modeling Strategy Decide on details from design Find smallest dimension of interest Pick element types – 1D Beams – 2D Plate or.
Mechanical characterization of lead- free solder joints J. Cugnoni*, A. Mellal*, Th. J. Pr. J. Botsis* * LMAF / EPFL EMPA Switzerland.
CHAP 5 FINITE ELEMENTS FOR HEAT TRANSFER PROBLEMS
Feasibility Analysis h T1 T2 T3 T4 T5 One Dimensional Transient Analysis One Dimensional Finite Difference Steady State Analysis T1 and T5 will be known.
PAX DETECTOR THERMAL SIMULATION 1Vittore Carassiti - INFN FEFz-Juelich, 27/10/2008.
Thermodynamics Part II. Remaining Topics Mechanisms of Heat Transfer Thermodynamic Systems and Their Surrounding Thermal Processes Laws of Thermodynamics.
RF-Accelerating Structure: Cooling Circuit Modeling Riku Raatikainen
Cooling design of the frequency converter for a wind power station
Prediction of Temperature Distribution of Steady State Rolling Tires
2004/01/17 Sangjin Park PREM, Hanyang University
University of Chemical Technology and Metallurgy Department of Material Science and Engineering FINITEELEMENT METHOD By eng. Veselin Paunov Prof. Veselin.
Transient Thermal Problems Jake Blanchard Spring 2008.
HEAT TRANSFER ANALYSIS
PAT328, Section 3, March 2001MAR120, Lecture 4, March 2001S16-1MAR120, Section 16, December 2001 SECTION 16 HEAT TRANSFER ANALYSIS.
Transient Thermal Analysis Winter Semester
Copyright © 2010 Altair Engineering, Inc. All rights reserved.Altair Proprietary and Confidential Information Section 18 Set Creation & Solver Interface.
Micro-Resistor Beam.
Workshop 7: Thermal Steady State Analysis of a Composite Slab University of Puerto Rico at Mayagüez Department of Mechanical Engineering Modified by (2008):
Thermo-mechanics J. Cugnoni, LMAF / EPFL Three kind of « thermo-mechanics » 1. Un-coupled: Known temperature field => mechanical model (linear statics.
ANSYS for MEMS by Manjula1 FEM of MEMS on ANSYS MEMS Summer 2007 Why FEM for MEMS? Features in ANSYS Basic Procedures Examples.
Application of QuickField Software to Heat Transfer Problems i j k By Dr. Evgeni Volpov.
August 7, 2003K. Chow, LHC Luminosity Detector Thermal Analysis1 Analysis cases Approach: Start simple to get information— with speed with confidence that.
Copyright © 2010 Altair Engineering, Inc. All rights reserved.Altair Proprietary and Confidential Information Section 20 Flux and Convection.
HEAT CONDUCTION EQUATION
Tutorial 6-1: 3D Modeling.
HEAT TRANSFER FINITE ELEMENT FORMULATION
Micro-valve Estimated Time for Completion: ~30min Experience Level: Lower MSC.Patran 2005 r2 MSC.Marc 2005 r2.
Heat flux through the wall
GIGATRACKER SUPPORTING PLATE COOLING SYSTEM SIMULATION 1Vittore Carassiti - INFN FECERN, 11/12/2007.
1 CHAP 5 FINITE ELEMENTS FOR HEAT TRANSFER PROBLEMS FINITE ELEMENT ANALYSIS AND DESIGN Nam-Ho Kim Audio by Raphael Haftka.
MECH4450 Introduction to Finite Element Methods
Investigation of the Thermal Stresses in a Steel Plate.
Chapter 2: Heat Conduction Equation
Innovation Intelligence ® Section 18 Set Creation & Solver Interface.
FINAL YEAR PROJECT DEPARTMENT OF MECHANICAL ENGINEERING A.V.C COLLEGE OF ENGINEERING.
Thermal Analysis Assumptions: Body Temperature (Environment) is 37˚C Heat distribution on outside of device will be modeled via FEA Heat transfer method.
COUPLED ANALYSES Chapter 7. Training Manual May 15, 2001 Inventory # Fluid-Structure Analysis “One Way” Analysis –Structural deformation effect.
Innovation Intelligence ® Section 20 Flux and Convection.
Winter/ IntroductionM. Shapiro 1 Can calculate Q 12 [J] from the first law of thermo. קצב מעבר חום heat transfer rate can’t calculate from thermo.
CFD Analysis of Buoyancy Driven Liquid Argon in MicroBooNe Cryostat Erik Voirin Fermilab Process Engineering Group Erik Voirin - Fermilab1MicroBooNe Buoyancy.
TS Cool Down Studies TSu Unit Coils (24-25) N. Dhanaraj and E. Voirin Tuesday, 10 March 2015 Reference: Docdb No:
Tutorial 2b: Thermo-physical properties
THERMO-STRUCTURAL ANALYSIS
HW/Tutorial # 1 WRF Chapters 14-15; WWWR Chapters ID Chapters 1-2
Continuum Mechanics (MTH487)
Temperature distribution and deflection in a bimetal
Power Magnetic Devices: A Multi-Objective Design Approach
Chapter 2. Mathematical Expression of Conduction
Temperature distribution in the target
Tutorial 4: 2D Plane (CST/Q4)
Fundamentals of Heat Transfer
Spencer Ferguson and Natalie Siddoway April 7, 2014
CE 808: Structural Fire Engineering SAFIR - Computer Program
Implementation of 2D stress-strain Finite Element Modeling on MATLAB
Thermal behavior of the LHCb PS VFE Board
ANALYSIS OF THE HORN UNDER THERMAL SHOCK – FIRST RESULTS
Fundamentals of Heat Transfer
Thermo-mechanics J. Cugnoni, LMAF / EPFL 2012.
Presentation transcript:

Thermo-mechanics J. Cugnoni, LMAF / EPFL 2009

Three kind of « thermo-mechanics » Un-coupled: Known temperature field => mechanical model (linear statics + th. expansion) One way coupling: solve thermal problem => temperature field => solve mechanical problem Fully coupled: solve at the same time temperature & displacement field (includes mechanical dissipation)

Thermal problem Variables Material Boundary conditions: Essential variable: Temperature field T Natural variable: heat flux q Material Conductivity l Density r & specific heat cp if transient Boundary conditions: Temperature: Tsurf = f(t) if transient Surface heat fluxes: Imposed heat flux qsurf=f(t) Convection: qsurf = h (T –Text(t)) Volume heat source: s = f(t) q T, l, r, cp, s Text

Thermal problem in Abaqus Select Step = Heat transfer Choose steady state or transient If transient: set time period, set small initial increment, set max DT per increment (<1/10 of max DT) In Mesh: select element type: Heat transfer, linear Loading: Need to impose at least one temp. (rigid body) Adiabatic interface: leave free = no flux! Flux = load, Temperature = BC Convection: in interaction module, create Surface Film condition, enter h and Text If transient: define an amplitude curve (tool => amplitude), need to start at zero for t=0,

Coupled Thermo mechanics in Abaqus Select Step = Coupled Temp-Displacement Choose steady state or transient If transient: set time period, set small initial increment, set max DT per increment (<1/10 of max DT) In Mesh: select element type: Coupled Temp.-Displacement, quadratic Loading: Need to impose at least one temp. & block 6 rigid body motions Adiabatic interface: leave free = no flux! Flux = load, Temperature = BC Convection: in interaction module, create Surface Film condition, enter h and Text If transient: define an amplitude curve (tool => amplitude), need to start at zero for t=0

Démos Bi-material beam: Thermal switch Coupled Thermo-mechanical problem Transient analysis Heat transfer & expansion properties Heat transfer BC: Temperature Convection Heat Flux Time dependent boundary conditions

Demo: thermal switch Beam dimensions 60 x 5 x 1 mm Invar, 0.5 mm Block: clamped, T= 0°C Convection: q=h (T-Text), h = 100 W/m2/K Water Prop. Steel Invar Young’s modulus 210 GPa 141 GPa Poisson ratio 0.3 Th. Expansion 1e-5 1e-6 Density 7800 kg/m3 8000 kg/m3 Conductivity 30 W/m/K 10 W/m/K Specific heat 1000 J/kg/K 500 J/kg/K Steel, 0.5 mm T water = f(time) T=100°C T=0°C 1 Time (s) 60

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.