b) A nuclear reactor with its core constructed of parallel vertical plates 2.2 m high and 1.4 m wide has been designed on free convection heating of liquid bismuth. The maximum temperature of the plate surfaces is limited to 960°C while the lowest allowable temperature of bismuth is 340°C. Calculate the maximum possible heat dissipation from both sides of each plate. For the convection coefficient, the appropriate correlation is Nu = 0.13 (Gr.Pr)0.333 where different parameters are evaluated at the mean film temperature. P = 104 * kg/m³; u = 3.12 kg/m-h; c, = 150.7 J/kg°C; k= 13.02 W/m°C %3D
b) A nuclear reactor with its core constructed of parallel vertical plates 2.2 m high and 1.4 m wide has been designed on free convection heating of liquid bismuth. The maximum temperature of the plate surfaces is limited to 960°C while the lowest allowable temperature of bismuth is 340°C. Calculate the maximum possible heat dissipation from both sides of each plate. For the convection coefficient, the appropriate correlation is Nu = 0.13 (Gr.Pr)0.333 where different parameters are evaluated at the mean film temperature. P = 104 * kg/m³; u = 3.12 kg/m-h; c, = 150.7 J/kg°C; k= 13.02 W/m°C %3D
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
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Transcribed Image Text:b) A nuclear reactor with its core constructed of parallel vertical plates 2.2 m high and 1.4 m
wide has been designed on free convection heating of liquid bismuth. The maximum
temperature of the plate surfaces is limited to 960°C while the lowvest allowable temperature of
bismuth is 340°C. Calculate the maximum possible heat dissipation from both sides of each
plate. For the convection coefficient, the appropriate correlation is
Nu = 0.13 (Gr.Pr)0.333
where different parameters are evaluated at the mean film temperature.
p = 104 kg/m3;
µ = 3.12 kg/m-h; c, = 150.7 J/kg°C; k= 13.02 W/m°C
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