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Lesson 13 CONVECTION HEAT TRANSFER

Lesson 13 CONVECTION HEAT TRANSFER. Given the formula for heat transfer and the operating conditions of the system, CALCULATE the rate of heat transfer by convection. Convection. Heat transfer by the motion and mixing of the molecules of a liquid or gas

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Lesson 13 CONVECTION HEAT TRANSFER

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  1. Lesson 13 CONVECTION HEAT TRANSFER Given the formula for heat transfer and the operating conditions of the system, CALCULATE the rate of heat transfer by convection.

  2. Convection • Heat transfer by the motion and mixing of the molecules of a liquid or gas • Natural convection is used if this motion and mixing is caused by density variations resulting from temperature differences within the fluid. • Affected by: • Fluid velocity • Fluid viscosity • Heat flux • Surface roughness • Type of flow (single-phase/two-phase)

  3. Convection

  4. Convection • The convective heat transfer coefficient (h) is dependent upon the physical properties of the fluid and the physical situation. • Laminar flow – relatively low h • Turbulent flow – higher h stagnant fluid film layer is thinner on the heat transfer surface. • Values of h have been measured and tabulated for the commonly encountered fluids and flow situations occurring during heat transfer by convection.

  5. Heat Transfer Coefficient • Heat transfer processes encountered in nuclear facilities involve a combination of both conduction and convection. • For a heat exchanger, there are two values for h. • Convective heat transfer coefficient (h) for the fluid film inside the tubes • Convective heat transfer coefficient for the fluid film outside the tubes. • Thermal conductivity (k) and thickness (Δx) of the tube wall must also be accounted for. • Uo - Overall heat transfer coefficient • Total rate of heat transfer (Q) must be related to the cross-sectional area for heat transfer (Ao) and the overall heat transfer coefficient (Uo).

  6. Overall Heat Transfer Coefficient

  7. Combined Heat Transfer

  8. Combined Heat Transfer • Three processes - • Heat transfer by convection between temperatures T1 and T2; • Heat transfer by conduction between temperatures T2 and T3 • Heat transfer occurs by convection between T3 and T4. • Each has an associated heat transfer coefficient, cross-sectional area for heat transfer, and temperature difference.

  9. Overall heat transfer coefficient in cylindrical geometry Where : Δr = ro – rin k = Thermal conductivity coefficient of the tube wall h1 = Convective heat transfer coefficient inside tube h2 = Convective heat transfer coefficient outside the tube

  10. Summary

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