Nitrogen (N2) enters a well-insulated diffuser operating at steady state at 0.656 bar, 300 K with a velocity of 282 m/s. The inlet area is 4.8 x 10-3 m2. At the diffuser exit, the pressure is 0.9 bar and the velocity is 140 m/s. The nitrogen behaves as an ideal gas with k = 1.4. (a) Determine the exit temperature, in K, and the exit area, in m2. (b) For a control volume enclosing the diffuser, determine the rate of entropy production, in kW/K.

First it is assumed that the diffuser works as a isentropic device. A isentropic device is such that the entropy at the inlet is equal that the entropy T the exit.
It will be used the subscript 1 for the inlet conditions of the nitrogen, and the subscript 2 for the exit conditions of the nitrogen.
It will be called: v the velocity of the nitrogen stream, T the nitrogen temperature, V the volumetric flow of the specific stream, A the area at the inlet or exit of the diffuser and, P the pressure of the nitrogen flow.
It is known that for a fluid flowing, its volumetric flow is obtain as: [tex]V=v*A[/tex],
Then for the inlet of the diffuser: [tex]V_1=v_1*A_1=282\frac{m}{s}*4.8*10^{-3}m^2=1.35\frac{m^3}{s}[/tex]
For an ideal gas working in an isentropic process, it follows that: [tex]\frac{T_{2} }{T_1}=(\frac{P_2}{P_1})^k[/tex] where each variable is defined according with what was presented in step 2 and 3, and k is the heat values relationship, 1.4 for nitrogen.
Then solving for [tex]T_2[/tex], the temperature of the nitrogen at the exit conditions: [tex]T_2=T_1(\frac{P_2}{P_1})^k[/tex] then, [tex]T_2=300 K (\frac{0.9 bar}{0.656 bar})^{(\frac{1.4-1}{1.4})}=331.4 K[/tex]
Also, for an ideal gas working in an isentropic process, it follows that: [tex]\frac{P_2}{P_1}= (\frac{V_1}{V_2})^k[/tex], where each variable is defined according with what was presented in step 2 and 3, and k is the heat values relationship, 1.4 for nitrogen.
Then solving for [tex]V_2[/tex] the volumetric flow at the exit of the diffuser: [tex]V_2=V_1*\frac{1}{\sqrt[k]{\frac{P_2}{P_1}}}=\frac{1.35\frac{m^3}{s}}{\sqrt[1.4]{\frac{0.9bar}{0.656bar} }}=1.080\frac{m^3}{s}[/tex].
Knowing that [tex]V_2=1.080\frac{m^3}{s}[/tex], it is possible to calculate the area at the exit of the diffuser, using the relationship presented in step 4, and solving for the required parameter: [tex]A_2=\frac{V_2}{v_2}=\frac{1.08\frac{m^3}{s} }{140\frac{m}{s}}=7.71*10^{-3}m^2[/tex].
To determine the rate of entropy production in the diffuser, it is required to do a second law balance (entropy balance) in the control volume of the device. This balance is: [tex]S_1+S_{gen}-S_2=\Delta S_{system}[/tex], where: [tex]S_1[/tex] and [tex]S_2[/tex] are the entropy of the stream entering and leaving the control volume respectively, [tex]S_{gen}[/tex] is the rate of entropy production and, [tex]\Delta S_{system}[/tex] is the change of entropy of the system.
If the diffuser is operating at stable state is assumed then [tex]\Delta S_{system}=0 [/tex]. Applying the entropy balance and solving the rate of entropy generation: [tex]S_{gen}=S_2-S_1[/tex].
Finally, it was assume that the process is isentropic, it is: [tex]S_1=S_2[/tex], then [tex]S_{gen}=0[/tex].