the plane Wall seen in the figure is L=20 cm and the heat conduction coefficient is 57 W/mK. Inside the wall there is a uniform distributed volumetric heat generation of 120 kW/m3. One surface of the wall is a fluid alloy with a temperature of 15 Co, the other its surface is subjected to heat flux of Q0 = 50 kW/m2. Since the heat transfer coefficient between the wall and the fluid is 400 W / m2 K, accepting the temperature change within the wall as one-dimensional and continuous, a) draw the temperature change curve by finding the correlation that gives the temperature distribution inside the Wall b) find the maximum temperature inside the Wall? E) find in x=L?
the plane Wall seen in the figure is L=20 cm and the heat conduction coefficient is 57 W/mK. Inside the wall there is a uniform distributed volumetric heat generation of 120 kW/m3. One surface of the wall is a fluid alloy with a temperature of 15 Co, the other its surface is subjected to heat flux of Q0 = 50 kW/m2. Since the heat transfer coefficient between the wall and the fluid is 400 W / m2 K, accepting the temperature change within the wall as one-dimensional and continuous, a) draw the temperature change curve by finding the correlation that gives the temperature distribution inside the Wall b) find the maximum temperature inside the Wall? E) find in x=L?
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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the plane Wall seen in the figure is L=20 cm and the heat conduction coefficient is 57 W/mK. Inside the wall there is a uniform distributed volumetric heat generation of 120 kW/m3. One surface of the wall is a fluid alloy with a temperature of 15 Co, the other
its surface is subjected to heat flux of Q0 = 50 kW/m2. Since the heat transfer coefficient between the wall and the fluid is 400 W / m2 K, accepting the temperature change within the wall as one-dimensional and continuous,
a) draw the temperature change curve by finding the correlation that gives the temperature distribution inside the Wall
b) find the maximum temperature inside the Wall?
E) find in x=L?
Transcribed Image Text:9.
b. T-
1111
X-0
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