Optimal Shape Design for Heat Conduction and Convection Problems Using NURBS
Subject Areas :
Analytical and Numerical Methods in Mechanical Design
Farbod Fakhrabadi
1
,
Farshad Kowsary
2
1 - Department of Mechanical Engineering, Qazvin Branch, Islamic Azad University, Qazvin, Iran
2 - School of Mechanical Engineering, Faculty of Engineering, University of Tehran, Tehran, Iran
Received: 2022-09-21
Accepted : 2022-09-21
Published : 2022-06-01
Keywords:
NURBS,
Shape Design,
Conduction heat transfer,
Abstract :
This article presents an optimal shape design methodology for heat conduction and convection problems. In this study, the shape of the conductive and convective medium is parameterized by means of non-uniform rational B-spline (NURBS) surfaces, and their control points represent the design variables. The conductive and convective domain is discretized by choosing the parameters of NURBS surfaces as generalized curvilinear coordinates, and the heat conduction and convection equation is solved using the finite difference method. The simplified conjugate-gradient method (SCGM) is used as the optimization method to obtain the optimal shape and adjust the design variables intelligently. By optimizing the profile of a straight fin with the objective of enhancing heat transfer rate and reducing the fin mass the methodology is demonstrated for conduction problems and by optimizing the shape profile of a natural convective cavity with the objective of reducing the maximum wall temperature the methodology is shown for convection problems.
References:
Fabbri, G., 1997, “A Genetic Algorithm for Fin Profile Optimization,” Int. J. Heat Mass Transfer, 40, pp. 2165-2172.
Fabbri, G., 1998, “Heat Transfer Optimization in Internally Finned Tubes under Laminar Flow Conditions,” Int. J. Heat Mass Transfer, 41, pp. 1243-1253.
Fabbri, G., 1999, “Optimum Profiles for Asymmetrical Longitudinal Fins in Cylindrical Ducts,” Int. J. Heat Mass Transfer, 42, pp. 511-523.
Cheng, C. H., and Wu, C. Y., 2000, “An Approach Combining Body-Fitted Grid Generation and Conjugate Gradient Methods for Shape Design in Heat Conduction Problems,” Numerical Heat Transfer, Part B, 37, pp. 69-83.
Lan, C. H., Cheng, C. H., and Wu, C. Y., 2001, “Shape Design for Heat Conduction Problems Using Curvilinear Grid Generation, Conjugate Gradient, and Redistribution Methods,” Numerical Heat Transfer, Part A, 39, pp. 487-510.
Cheng, C. H., and Chang, M. H., 2003, “Shape Design for a Cylinder with Uniform Temperature Distribution on the Outer Surface by Inverse Heat Transfer Method,” Int. J. Heat Mass Transfer, 46, pp. 101-111.
Cheng, C. H., Chan, C. K., and Lai, G. J., 2008, “Shape Design of Millimeter-Scale Air Channels for Enhancing Heat Transfer and Reducing Pressure Drop,” Int. J. Heat Mass Transfer, 51, pp. 2335-2345.
Daun, K. J., Howell, J. R., and Morton, D. P., 2003, “Geometric Optimization of Radiative Enclosures through Nonlinear Programming,” Numerical Heat Transfer, Part B, 43, pp. 203-219.
Hilbert, R., Janiga, G., Baron, R., and Thevenin, D., 2006, “Multi-Objective Shape Optimization of a Heat Exchanger Using Parallel Genetic Algorithms,” Int. J. Heat Mass Transfer, 49, pp. 2567-2577.
Nobile, E., Pinto, F., and Rizetto, G., 2006, “Geometric Parameterization and Multiobjective Shape Optimization of Convective Periodic Channels,” Numerical Heat Transfer, Part B, 50, pp. 425-453.
Balagangadhar, D., and Roy, S., 2001 “Design Sensitivity Analysis and Optimization of Steady Fluid-Thermal Systems” Comput. Methods Appl. Mech. Engrg., 190, 5465-5479.
Landon, M. K., and Campo, A., 2004 “Optimal Shape for Laminar Natural Convective Cavities Containing Air and Heated from the Side” Int. Comm. Heat Mass Transfer, Vol. 26, No. 3, pp. 389-398.
Piegl, L., and Tiller, W., 1997, The NURBS Book, 2nd Ed., Springer-Verlag, Berlin.
Thompson, J. F., Warsi, Z. U. A., and Mastin, C. W., 1985, Numerical Grid Generation, Elsevier Science Publishing Co.
Fletcher, C. A. J., 1988, Computational Techniques for Fluid Dynamics 2, Springer-Verlag, Berlin.
Cheng, C. H., and Chang, M. H., 2003, “A Simplified Conjugate-Gradient Method for Shape Identification Based on Thermal Data,” Numerical Heat Transfer, Part B, 43, pp. 489-507.
