Effects of Internal Heat Generation on Solidification

2005 ◽  
Author(s):  
John C. Crepeau ◽  
Ali Siahpush
Keyword(s):  
Heat Generation ◽  
Solid Phase ◽  
Freezing Point ◽  
Internal Heat ◽  
Internal Heat Generation ◽  
Square Root ◽  
Stefan Number ◽  
Temperature Boundary ◽  
Geometry Problem ◽  
Solid Liquid

We present solutions for solid-liquid phase change in materials that generate internal heat. This problem is solved for both cylindrical and semi-infinite geometries. The analysis assumes a temperature profile in the solid phase and constant temperature boundary conditions on the exposed surfaces. We derive differential equations governing the solidification thickness for both geometries as functions of the Stefan number and the internal heat generation (IHG). For the cylindrical geometry, the solidification layer obtains a steady-state value which is related to the inverse of the square root of the IHG. The solutions to the semi-infinite geometry problem show that when the surface is cooled to below the freezing point, a solidification layer forms along the edge and begins to grow until it reaches a maximum, then begins remelt.

Integral Solutions of Phase Change With Internal Heat Generation

2004 ◽  
Author(s):  
Ali Siahpush ◽  
John Crepeau
Keyword(s):  
Differential Equation ◽  
Phase Change ◽  
Heat Generation ◽  
Numerical Solutions ◽  
Internal Heat ◽  
Melting Rate ◽  
Internal Heat Generation ◽  
Stefan Number ◽  
Temperature Boundary ◽  
Solid Liquid

This paper presents solutions to a one-dimensional solid-liquid phase change problem using the integral method for a semi-infinite material that generates internal heat. The analysis assumed a quadratic temperature profile and a constant temperature boundary condition on the exposed surface. We derived a differential equation for the solidification thickness as a function of the internal heat generation (IHG) and the Stefan number, which includes the temperature of the boundary. Plots of the numerical solutions for various values of the IHG and Stefan number show the time-dependant behavior of both the melting and solidification distances and rates. The IHG of the material opposes solidification and enhances melting. The differential equation shows that in steady-state, the thickness of the solidification band is inversely related to the square root of the IHG. The model also shows that the melting rate initially decreases and reaches a local minimum, then increases to an asymptotic value.

scholarly journals Scale/Analytical Analyses of Freezing and Convective Melting With Internal Heat Generation

2013 ◽  
Author(s):  
Ali Siahpush ◽  
John Crepeau ◽  
Piyush Sabharwall
Keyword(s):  
Surface Temperature ◽  
Heat Generation ◽  
Solid Phase ◽  
Convection Heat Transfer ◽  
Internal Heat ◽  
Constant Heat Flux ◽  
Internal Heat Generation ◽  
Cylindrical Geometry ◽  
Temperature Boundary ◽  
Model Phase

Using a scale/analytical analysis approach, we model phase change (melting) for pure materials which generate constant internal heat generation for small Stefan numbers (approximately one). The analysis considers conduction in the solid phase and natural convection, driven by internal heat generation, in the liquid regime. The model is applied for a constant surface temperature boundary condition where the melting temperature is greater than the surface temperature in a cylindrical geometry. The analysis also consider constant heat flux (in a cylindrical geometry). We show the time scales in which conduction and convection heat transfer dominate.

scholarly journals Scale Analysis of Convective Melting With Internal Heat Generation

2011 ◽  
Author(s):  
Ali Siahpush ◽  
John Crepeau
Keyword(s):  
Surface Temperature ◽  
Heat Generation ◽  
Solid Phase ◽  
Convection Heat Transfer ◽  
Internal Heat ◽  
Internal Heat Generation ◽  
Scale Analysis ◽  
Temperature Boundary ◽  
Model Phase ◽  
Temperature Boundary Condition

Using a scale analysis approach, we model phase change (melting) for pure materials which generate internal heat for small Stefan numbers (approximately one). The analysis considers conduction in the solid phase and natural convection, driven by internal heat generation, in the liquid regime. The model is applied for a constant surface temperature boundary condition where the melting temperature is greater than the surface temperature in a cylindrical geometry. We show the time scales in which conduction and convection heat transfer dominate.

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