Explanation Given: The speed is 1 m / s . The length is 1 m . The saturated liquid density is 0.75 kg / m 3 . Area is 2 m 2 . Concept used: The kinematic viscosity is 16.2 × 10 − 6 m 2 / s . The thermal conductivity is 0.0265 W / m ⋅ K . The Prandtl number is 0.707. The density is 7832 kg / m 3 . The specific heat transfer is 441 J / kg ⋅ K . The mass diffusivity is 10 − 5 m 2 / s . The latent heat of vaporization is 9 × 10 5 J / kg . Write the expression for Reynolds number. Re = u L ν ....... (1) Here, L is length; Re is Reynolds number, ν is kinematic viscosity and u is the velocity of fluid. Write the expression for Schmidt number. S c = ν D A B ....... (2) Here, Sc is Schmidt number, ν is kinematic viscosity and D A B is mass diffusivity of fluid. Write the expression for the average Nusselt number. N u L = 0.664 Re 1 2 Pr 1 3 ....... (3) Here, N u L average Nusselt number. Write the expression for the average heat transfer coefficient. h ¯ = k L ( N u L ) ....... (4) Here, N u L average Nusselt number, k is thermal conductivity and L is length, h ¯ average heat transfer coefficient. Write the expression for convective mass transfer rate. h m , l = 0.664 Re 1 2 S c 1 3 ( D A B ) L ....... (5) Here, h m , l convective mass transfer. Write the expression for heat transfer. q = h ¯ A ( T i − T ∞ ) + h m , l A ( h f g ) ....... (6) Here, q is heat transfer, T s is surface temperature, T ∞ is outside temperature, A is area, h ¯ is average heat transfer coefficient, h f g is the latent heat of vaporization and h ¯ m , l average mass transfer coefficient. Write the expression for the rate of change of temperature. d T d t = − q ρ δ L 2 c ....... (7) Here, d T d t is rate of temperature change, c is the specific heat, ρ is density and δ is change in length. Calculation: Substitute 1 m for L, 16.2 × 10 − 6 m 2 / s for ν and 1 m / s for u in equation (1) Re = ( 1 ) ( 1 ) 16.2 × 10 − 6 = 6.17 × 10 4 Substitute 16.2 × 10 − 6 m 2 / s for ν and 10 − 5 m 2 / s for D A B in equation (2) S c = 16

7th Edition

ISBN: 9780470501979

Author: Frank P. Incropera, David P. DeWitt, Theodore L. Bergman, Adrienne S. Lavine

Publisher: Wiley, John & Sons, Incorporated

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Chapter 7, Problem 7.128P

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The initial rate of heat transfer from the plate and also find the corresponding rate of change of the plate temperature.

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Chapter 7, Problem 7.127P

Chapter 7, Problem 7.129P

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Chapter 7 Solutions

Fundamentals of Heat and Mass Transfer

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The initial rate of heat transfer from the plate and also find the corresponding rate of change of the plate temperature.

Solution Summary: The author describes the initial rate of heat transfer from the plate and the corresponding temperature change. The kinematic viscosity is 16.2times 10-6

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The initial rate of heat transfer from the plate and also find the corresponding rate of change of the plate temperature.

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Chapter 7 Solutions