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FlowLab Implementation at Cornell University

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... of Mechanical & Aerospace Engineering. Cornell University ... MAE 427: Fluids/ Heat Transfer Laboratory. Required class for Mechanical Engineering seniors ... – PowerPoint PPT presentation

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Title: FlowLab Implementation at Cornell University


1
FlowLab Implementation at Cornell University
  • Rajesh Bhaskaran and David Caughey
  • Sibley School of Mechanical
  • Aerospace Engineering
  • Cornell University
  • Ithaca, New York

2
FlowLab in a Lab Course
  • MAE 427 Fluids/ Heat Transfer Laboratory
  • Required class for Mechanical Engineering seniors
  • About 110 students, 2 professors, 6 TAs
  • Taught in groups of 6-8 students
  • Approach
  • Perform simulation corresponding to experiment
  • Compare experimental and simulation results
  • Experiments considered Heated pipe flow, Flow
    over an airfoil

3
Heated Pipe Flow Experiment
  • Instructor Prof. Elizabeth (Betta) Fisher
  • Raw measurements Wall and gas temperatures
    pressure drops power to heater

4
Heated Pipe Flow Experiment
  • After number crunching, obtain
  • Reynolds number, Re
  • Friction factor, f (dimensionless drag)
  • Nusselt number, Nu (dimensionless heat transfer
    coeff.)
  • To make room for simulation, dropped measurements
    at several unheated conditions (Re and f only)

5
Heated Pipe Flow Simulation
  • FlowLab Interface

6
Heated Pipe Flow Simulation
  • FlowLab output Temperature contours

7
Heated Pipe Flow
  • Mode of FlowLab use
  • While waiting for experimental set-up to reach
    steady state, students walk over to adjacent
    computer lab
  • T.A. provides hands-on introduction to pipe flow
    template with nominal experimental data
  • Students repeat the simulation for their
    experimental data outside of class
  • They calculate friction factor and Nusselt number
    manually and compare with experiment
  • FlowLab available in a 24-hour lab

8
Heated Pipe Flow Results
9
Heated Pipe Flow Handout
  • Developed 8-page handout
  • Strategy of CFD
  • Steps in CFD solution process

10
Heated Pipe Flow Handout
  • Provides brief explanation for each of the steps.
    For instance
  • Geometry Why rectangle? Dimensions of rectangle
  • Physics Flow properties, viscous model, boundary
    conditions (inflow conditions, heat input at the
    wall etc.)
  • Turbulence modeling background
  • Grungy operating details
  • Available on FlowLab website

11
Heated Pipe Flow
  • The simulations help students
  • Gain a better understanding of the experiment
    (through contour and vector plots) than is
    possible from a few point measurements.
  • Confirm some assumptions made in the data
    processing for the experiment (e.g. that mixing
    region is long enough).
  • Compare numerical approach with experiment and
    correlation.
  • Classroom observations
  • Small groups well suited to introducing students
    to the use of FlowLab and CFD background
  • Enthusiasm for learning more about CFD.

12
Heated Pipe Flow
  • FlowLab implementation was facilitated through
    close interaction with Fluent Inc.
  • Enhancements to the standard pipe flow template
  • Troubleshooting poor agreement with experimental
    results
  • Bugs and suggestions
  • Problems were addressed quickly by Fluent
  • This interaction was key to success of the
    implementation

13
Heated Pipe Flow Student Feedback
  • Students were asked to rate statements such as
    As a result of my learning in the CFD Labs, I am
    able to
  • Present results from CFD simulations in written
    and graphical form.
  • Run Flowlab and implement CFD process for
    laminar and turbulent flow.
  • The rating scale ranged from "strongly agree"
    (scored as 6) to "strongly disagree" (scored as
    1).

14
Heated Pipe Flow Student Feedback
  • 80 responses
  • Overall average was 4.16 (SD 1.15) indicating
    that students, on average, "mildly agreed" with
    these statements.
  • Strongest agreement (M4.63, SD 1.16) was for
    I am able to appreciate that simulation
    involves approximations and tradeoffs.
  • Least agreement (M3.68, SD 1.20) was for I
    am able to evaluate iterative convergence through
    setting iterative convergence criteria and
    analysis of solutions residuals.

15
Heated Pipe Flow Student Feedback
  • 58 responses to What are the best things about
    learning in the CFD lab?
  • Visualization of results
  • Increases in understanding and knowledge
  • Hands-on experience with software
  • 41 responses to What needs to be improved in
    the CFD lab to maximize its value to you?
  • Instruction Better trained TAs, more time spent
    on CFD, etc.
  • Technical aspects of FlowLab such as bug fixes
  • Use FLUENT rather than FlowLab

16
Airfoil Experiment
  • Effort led by Prof. David Caughey
  • Flow past NACA0012 airfoil in a wind tunnel
  • Rec 54,000
  • Wall effects are significant

17
Airfoil Simulation
  • FlowLab gives non-physical result Discontinuity
    in lift curve at zero incidence

18
Airfoil Simulation
  • FLUENT results 
  • Steady solution diverges even for zero incidence
  • This suggests flow is unsteady
  • Results differed for the segregated and coupled
    solvers
  • Current FlowLab template designed for steady
    flows Not suited for unsteady, laminar,
    separated flow over an airfoil with wall effects

19
Conclusion
  • FlowLab facilitates better pedagogy
  • Enables simulation use in a lab setting
  • Contributes to improved understanding of the
    experiment
  • Helps students confirm some assumptions made in
    data reduction
  • Pooling of resources by universities for
    curriculum development is essential
  • Partnership with Fluent has been crucial

20
Acknowledgements
  • Professor Elizabeth Fisher
  • NSF Department of Undergraduate Education
  • Swanson Engineering Simulation Program,
    Mechanical Aerospace Engineering, Cornell
    University
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