Computational Directions in Mechanical Engineering at The University of Alabama

1. Computational Directions in Mechanical Engineering at The University of Alabama Will Schreiber Keith Woodbury

2. Overview • Inverse Problems and Optimization in Heat Transfer • Keith Woodbury • Heat Transfer • IC Engines • Will Schreiber

3. Inverse Problems and Optimization in Heat Transfer Keith A. Woodbury Mechanical Engineering University of Alabama

4. What are inverse problems? • An Inverse Problem is one of determining unknown causes on the basis of observed effects • Contrast with a Direct Problem of computing system responses based on specified inputs

5. Classes of Inverse Problems • Inverse Boundary Problem • Determine unknown action at a physical boundary; typically a function of time • Inverse Coefficient Problem • Determine unknown coefficients, such as thermophysical properties

6. General Approach • Combine • Model • Complete mathematical description of physics, usually heat conduction process • Data • Measured temperature histories at one or more locations in the domain • Fitness Measure • Quantify discrepancy between model and data, usually with sum-squared error • Minimization Technique

7. Numerical Modelswe use… • Finite element methods are our primary choice • Custom codes for inverse problems • Commercial package FIDAP used for routine simulations

8. Minimization Techniques we have used… • Sequential Function Specification Method (a.k.a. Beck’s method) • Gradient Methods (a.k.a. Adjoint Method) • Evolutionary Algorithms (a.k.a. Genetic Algorithms) • Neural Networks

9. Projects • Identification of thermal contact resistance in sand castings • American Foundryman’s Society and DOE

10. Projects • Toward Improved Al-Be Castings • NASA – thru Auburn University

11. Projects • Design and CFD Analysis of Water/Fuel Evaporator for Fuel Cell Reformer • Ballard Corporation / TACOM

12. Selected Publications… • Pohanka, M., and Woodbury, K. A., “A Downhill Simplex Method for Computation of Interfacial Heat Transfer Coefficients in Alloy Casting,” Inverse Problems in Engineering, to appear 2003. • Woodbury, K. A., Woolley, J. W., Piwonka, T. S., and Pohanka, M., “Metal/Mold and Mold/Environment Interfacial Heat Transfer Coefficients in Active and Passive Cooling of Investment Castings,” AFS Transactions, Vol. 111, 03-114, 2003, pp. 1-13 • Krejsa, J., Woodbury, K. A., Ratliff, J. D., and Raudensky, M., “Assessment of Strategies and Potential for Neural Networks in the IHCP,” Inverse Problems in Engineering, Vol 7, n 3, 1999, pp. 197-213. • Beck, J. V., and Woodbury, K. A., “Inverse Problems and Parameter Estimation: Integration of Measurements and Analysis,” Measurement Science and Technology, Vol. 9, no. 6, June, 1998, pp. 839-847.

13. Selected Publications… • Woodbury, K. A., “Application of Genetic Algorithms and Neural Networks to the Solution of Inverse Heat Conduction Problems: A Tutorial,” 4th International Conference on Inverse Problems in Engineering, May, 2002, Angra dos Reis, BRAZIL • Woodbury, K. A., and Ke, Q., “A boundary Inverse Heat Conduction Problem with phase change for moisture-bearing porous medium,” Third International Conference on Inverse Problems in Engineering, Port Ludlow, WA, June 13-18, 1999, pp. 363-369 • Woodbury, Keith A., Krishnamurthy, S., and Durrans, S. Rocky, “Solution of a Non-Linear Inverse Problem in Open Channel Flow by Mollification and Space Marching,'' ASME Proceedings of the 32nd National Heat Transfer Conference Volume 2, HTD Vol. 340, ASME/AIChE 1997 National Heat Transfer Conference, August, 1997, pp. 69-74.

14. Selected Publications… • Woodbury, K. A., and Boohaker, C. G., “Simultaneous Determination of Temperature-Dependent Thermal Conductivity and Volumetric Specific Heat,'' HTD Vol. 332, 1996 ASME IMECE, pp. 269-274. • Woodbury, K. A., and Premanand B., “Finite Element Solution of the 2D-IHCP: Application to Steady-State Problems,” Second International Conference on Inverse Problems in Engineering, Engineering Foundation, June 9-14, 1996, Le Croisic, France. pp 499-504. • Woodbury, K. A., and Jin, X., “A Temperature-Based Sequential Function Specification Method for the IHCP,” HTD Vol. 312, 1995 National Heat Transfer Conference, Portland, OR, August 1995, pp. 141-150.

15. IC Engines Will Schreiber Mechanical Engineering University of Alabama

16. Computational Methodologies Used to Study Combustion in IC Engines • Phenomenological model of Diesel fuel jet developed on principle of packets • Phenomenological model of Diesel fuel jet currently under development based on analytical and numerical principles

17. Computational Methodologies Used to Study Combustion in IC Engines • Three-dimensional fluid flow solvers (KIVA and FIDAP) • Adaptive meshes • Experimental study of jets for validation

18. Recent Projects in IC Engines • Optimization of Diesel for lowering emissions using AGI and EGR • Study of effect of O2 enriched air on Diesel emissions • Effect of EGR and split fuel injection on Diesel emissions • Development of fuel jet combustion model using a combination of analytical and numerical methods.

19. Recent Publications Concerning IC Engines • Schreiber, W., 2003, “A Mathematical Model for Predicting Scalar Transport in a Transient Incompressible Jet”, 3rd Joint Meeting of the U.S. Sections of The Combustion Institute, Chicago, IL, March 16 – 19, 2003, paper E20. • Gao, Z., and Schreiber, W., 2001a, “A Phenomenologically Based Computer Model To Predict Soot And Nox Emission In A Direct Injection Engine”, International Journal of Engine Research, Vol. 3, pp. 177 – 188. • Gao, Z., and Schreiber, W., 2001b, “The Effects Of EGR And Split Fuel Injection On Diesel Engine Emission”, International Journal of Automotive Technology, Vol. 2, pp. 123 – 133.

20. Recent Publications Concerning IC Engines • Gao, Z., and Schreiber, W., 2002 “A Theoretical Investigation of Two Possible Modifications to Reduce Pollutant Emissions from a Diesel Engine”, Journal of Automotive Engineering, in review. • Gao, Z., and Schreiber, W., “A Multizone Analysis of Soot Emission in a D.I. Diesel Engine as a Function of Engine Load, Wall Temperature, and Intake Air O2 Content”, 2000 Fall Technical Conference, Proceedings ASME, ICE Division , Section VII_paper 4, September 24-27, 2000. • Gao, Z., and Schreiber, W., “The Use of a Multi-zone Model for Prediction of Soot Emission in a D.I. Diesel Engine as a Function of Intake Air O2 Content”, The 2000 International Mechanical Engineering Congress & Exposition November 5-10, 2000, Orlando, Florida HTD-Vol 366-5. pp. 95 – 103.

21. Other Heat Transfer Projects • Simulation of boiling heat transfer • Solidification of binary fluids • Thermal ground water simulation for environmental flows

22. AGI Used to Lower Soot and NOx