Answer:
R= 1.25
Explanation:
As given the local heat transfer,
[tex]Nu_x = 0.035 Re^{0.8}_x Pr^{1/3}[/tex]
But we know as well that,
[tex]Nu=\frac{hx}{k}\\h=\frac{Nuk}{x}[/tex]
Replacing the values
[tex]h_x=Nu_x \frac{k}{x}\\h_x= 0.035Re^{0.8}_xPr^{1/3} \frac{k}{x}[/tex]
Reynolds number is define as,
[tex]Re_x = \frac{Vx}{\upsilon}[/tex]
Where V is the velocity of the fluid and \upsilon is the Kinematic viscosity
Then replacing we have
[tex]h_x=0.035(\frac{Vx}{\upsilon})^{0.8}Pr^{1/3}kx^{-1}[/tex]
[tex]h_x=0.035(\frac{V}{\upsilon})^{0.8}Pr^{1/3}kx^{0.8-1}[/tex]
[tex]h_x=Ax^{-0.2}[/tex]
*Note that A is just a 'summary' of all of that constat there.
That is [tex]A=0.035(\frac{V}{\upsilon})^{0.8}Pr^{1/3}k[/tex]
Therefore at x=L the local convection heat transfer coefficient is
[tex]h_{x=L}=AL^{-0.2}[/tex]
Definen that we need to find the average convection heat transfer coefficient in the entire plate lenght, so
[tex]h=\frac{1}{L}\int\limit^L_0 h_x dx\\h=\frac{1}{L}\int\limit^L_0 AL^{-0.2}dx\\h=\frac{A}{0.8L}L^{0.8}\\h=1.25AL^{-0.2}[/tex]
The ratio of the average heat transfer coefficient over the entire plate to the local convection heat transfer coefficient is
[tex]R = \frac{h}{h_L}\\R= \frac{1.25Al^{-0.2}}{AL^{-0.2}}\\R= 1.25[/tex]
