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Heat Equations of Change I

Heat Equations of Change I. Outline. So far…. Heat Transfer Mechanisms Conduction Heat Transfer Convection Heat Transfer Combined Heat Transfer Overall Shell Heat Balances Heat Equations of Change. Outline. 6. Heat Equations of Change 7.1. Derivation of Basic Equations

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Heat Equations of Change I

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  1. Heat Equations of Change I

  2. Outline So far… Heat Transfer Mechanisms Conduction Heat Transfer Convection Heat Transfer Combined Heat Transfer Overall Shell Heat Balances Heat Equations of Change

  3. Outline 6. Heat Equations of Change 7.1. Derivation of Basic Equations 7.1.1. Differential Equation for Heat Conduction 7.1.2. Energy Equation 7.1.3. Buckingham Pi Method 7.2. Unsteady-state Conduction 7.2.1. Gurney-Lurie Charts 7.2.2. Lumped Systems Analysis

  4. Differential Equation for Heat Conduction Consider a differential element balance: Assumptions: Solid conduction thermal resistance only. Constant density, thermal conductivity and specific heat.

  5. Differential Equation for Heat Conduction Consider a differential element balance: Rate of HEAT in - out: Rate of HEAT generation: Rate of HEAT accumulation: In Chem 16, this is mcPdT

  6. Differential Equation for Heat Conduction Consider a differential element balance: Heat Balance: Dividing by : Taking the limit :

  7. Differential Equation for Heat Conduction Consider a differential element balance: Substituting Fourier’s Law: Noting that k is constant: Extending to 3D space:

  8. Differential Equation for Heat Conduction Consider a differential element balance: Measure of how quickly a material can carry heat away from a source. Recall the definition of thermal diffusivity: Dividing everything by k: Differential Equation for Heat Conduction

  9. Differential Equation for Heat Conduction Differential Equation for Heat Conduction Simplifications of the equation: No heat generation: Steady-state: Steady-state & no heat generation: Fourier’s Second Law of Conduction Poisson’s Equation Laplace’s Equation

  10. Differential Equation for Heat Conduction Differential Equation for Heat Conduction The equation in different coordinate systems: Rectangular: Cylindrical: Spherical:

  11. Differential Equation for Heat Conduction Example! Determine the steady-state temperature distribution and the heat flux in a slab in the region 0 ≤ x ≤ Lfor thermal conductivity k and a uniform heat generation in the medium at a rate of g0 when the boundary surface at x = 0 is kept at a uniform temperature T0 and the boundary surface at x = L dissipates heat by convection into an environment at a constant temperature T∞ with a heat-transfer coefficient h.

  12. Differential Equation for Heat Conduction Example! Assumptions (or given): Steady-state Unidirectional heat flow (x only) Constant k, ρ, cP, and h. Differential Equation for Heat Conduction:

  13. Differential Equation for Heat Conduction Example! After 1st and 2nd integration:

  14. Differential Equation for Heat Conduction Example! Boundary conditions: *The second B.C. denotes that the heat leaving by conduction is equal to the heat entering by convection.

  15. Differential Equation for Heat Conduction Example! Applying B.C. 1: C2 = T0 Applying B.C. 2:

  16. Differential Equation for Heat Conduction Example! Applying B.C. 1: C2 = T0 Applying B.C. 2: After substitution…

  17. Differential Equation for Heat Conduction Example! After substitution… Further manipulation into a desired form:

  18. Differential Equation for Heat Conduction Example! Manipulating into a desired form even further: Now, we introduce a new dimensionless number…

  19. Differential Equation for Heat Conduction Manipulating into a desired form even further: Finally:

  20. Differential Equation for Heat Conduction Example! Special cases of the problem: I. The Biot Number approaches infinity. In this case, the boundary conditions should have been: *When Bi approaches infinity, then the heat transfer coefficient, h, approaches infinity also.

  21. Differential Equation for Heat Conduction Example! Special cases of the problem: I. The Biot Number approaches infinity. The resulting equation when is: Recall the result when g0 is zero!

  22. Differential Equation for Heat Conduction Example! Special cases of the problem: II. The Biot Number approaches zero. In this case, the boundary conditions should have been: *When Bi approaches zero, then the heat transfer coefficient, h, approaches zero also.

  23. Differential Equation for Heat Conduction Example! Special cases of the problem: II. The Biot Number approaches zero. The resulting equation when is: Q: What does dT/dx = 0 imply?

  24. Differential Equation for Heat Conduction Exercise! A 10-cm diameter nickel-steel sphere has a thermal conductivity, k = 10 W/m-K. Within the sphere, 800 W/m3of heat is being generated. The surrounding air is at 20°C and the heat transfer coefficient from the surroundings to the surface of the sphere is 10 W/m2-K. What is the temperature at the center of the sphere?

  25. Energy Equation Consider a differential volume element: Recall: Combined Energy Flux Recall: First Law of Thermodynamics

  26. Energy Equation Consider a differential volume element: Rate of Increase in KE and Internal Energy: (Accumulation) Rate of Energy IN – OUT: Rate of Work Done by External Forces, g:

  27. Energy Equation Consider a differential volume element: Combining them: Expanding the combined energy flux term…

  28. Energy Equation Consider a differential volume element: THE ENERGY EQUATION

  29. Energy Equation Consider a differential volume element: The complete form of the Energy Equation

  30. Energy Equation Consider a differential volume element: If we subtract the mechanical energy balance from the energy equation: THE EQUATION OF CHANGE FOR INTERNAL ENERGY

  31. Energy Equation Consider a differential volume element: If we subtract the mechanical energy balance from the energy equation: THE EQUATION OF CHANGE FOR INTERNAL ENERGY

  32. Energy Equation Consider a differential volume element: Putting the internal energy in substantial derivative form: By absorbing the pressure force term, U becomes H. Since then at constant pressure: Convenient Form!

  33. Energy Equation Special Cases of the Energy Equation: 1. Fluid at constant pressure and small velocity gradients. R: C: S:

  34. Energy Equation Special Cases of the Energy Equation: 2. For solids Fourier’s Second Law of Conduction 3. With Heat Generation (simply added)

  35. Energy Equation Example! A solid cylinder in which heat generation is occurring uniformly as g W/m3 is insulated on the ends. The temperature of the surface of the cylinder is held constant at Tw K. The radius of the cylinder is r = R m. Heat flows only in the radial direction. Using the Energy Equation only, derive the temperature profile at steady-state if the solid has a constant k.

  36. Energy Equation Example! Using the solids special case with cylindrical coordinates: This can be rewritten as:

  37. Energy Equation Example! From here on, the solution is just the same as with the electrical wire:

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