Cooling a Solid Disc with Uniform Heat Generation Using Inserts of High Thermal Conductivity within the Constructal Design Platform

In the present study, the problem of cooling a solid disc by way of placing inserts with high thermal conductivity was examined analytically and numerically within the platform of Constructal Theory. The work was accomplished using a fixed amount of a highly conductive material distributed in the form of incomplete inserts from the center (sink). Using Constructal Theory, the magnitudes of the heat resistances in the radial and the branching configurations were calculated analytically. Additionally, to validate the analytical solution, a numerical solution with the Finite Element Method was employed. The one-to-one comparison between the two distinct results reveals a good agreement. In the present case, the length of the inserts was different from the disc radius viz. a new degree of freedom was considered and the solution was remarkably different from the case involving a complete insert. The heat resistance was minimized with respect to the aspect ratio in order to determine the optimal number of inserts as well as the disc radius. It was demonstrated that within in a certain range of parameters, the heat conduction performance of incomplete inserts in the solid disc surpasses the heat conduction performance of standard complete inserts.

[1]  Adrian Bejan,et al.  Conduction tree networks with loops for cooling a heat generating volume , 2006 .

[2]  Fengrui Sun,et al.  Optimization of constructal volume-point conduction with variable cross section conducting path , 2007 .

[3]  Adrian Bejan,et al.  Design with constructal theory , 2008 .

[4]  Fengrui Sun,et al.  The area-point constructal optimization for discrete variable cross-section conducting path , 2009 .

[5]  Adrian Bejan,et al.  Disc cooled with high-conductivity inserts that extend inward from the perimeter , 2004 .

[6]  Adrian Bejan,et al.  Three-dimensional tree constructs of “constant” thermal resistance , 1999 .

[7]  Adrian Bejan,et al.  Two Constructal Routes to Minimal Heat Flow Resistance via Greater Internal Complexity , 1999 .

[8]  J. Z. Zhu,et al.  The finite element method , 1977 .

[9]  Louis Gosselin,et al.  Constructal heat trees at micro and nanoscales , 2004 .

[10]  A. Bejan,et al.  Constructal theory of generation of configuration in nature and engineering , 2006 .

[11]  C. Elphick,et al.  Constructal Theory: From Engineering to Physics, and How Flow Systems Develop Shape and , 2006 .

[12]  Fengrui Sun,et al.  Heat-conduction optimization based on constructal theory , 2007 .

[13]  Louis Gosselin,et al.  Optimal conduction pathways for cooling a heat-generating body: A comparison exercise , 2007 .

[14]  Adrian Bejan,et al.  Constructal optimization of nonuniformly distributed tree-shaped flow structures for conduction , 2001 .

[15]  A. Bejan,et al.  Constructal tree networks for heat transfer , 1997 .

[16]  Adrian Bejan,et al.  Constructal-theory tree networks of “constant” thermal resistance , 1999 .

[17]  Adrian Bejan,et al.  Constructal tree networks for the time-dependent discharge of a finite-size volume to one point , 1998 .

[18]  Vedat S. Arpaci,et al.  Conduction Heat Transfer , 2002 .

[19]  Lotfollah Ghodoossi,et al.  Exact solution for cooling of electronics using constructal theory , 2003 .

[20]  Lotfollah Ghodoossi,et al.  Conductive cooling of triangular shaped electronics using constructal theory , 2004 .

[21]  Adrian Bejan,et al.  Constructal design for cooling a disc-shaped area by conduction , 2002 .