Question 4.8: In an afterburning jet engine, the gases enter the afterburn......

Since R = 287 J/kg · K,   Cp=\frac{\gamma R}{\gamma -1} ,then

1. For (C_{\text{p}})_{\text{inoperative ab}} = 1100 \text{ J/kg} \cdot \text{K,then }\gamma_1=1.353

2. For (C_{\text{p}})_{\text{operative ab}} = 1315 \text{ J/kg} \cdot \text{K,then }\gamma_2=1.279

The process is plotted in Figure 4.22 for operative and inoperative afterburner.
Since the mass flow rate \dot{m}=P \times A \times M \sqrt{ \gamma/RT} , assuming no losses in the nozzle, then the mass flow for a choked nozzle is

\dot{m}_{\text{choked}}=P^{\ast} \times A^{\ast}\sqrt{\frac{\gamma}{RT^\ast} }

This equation can be expressed in terms of the total conditions between states (6) and (7) as

\dot{m}_{\text{choked}}=\frac{A^\ast P_{06}}{\sqrt{RT_{06}}} \sqrt{\gamma}\left(\frac{2}{\gamma+1} \right) ^{(\gamma+1)/2(\gamma-1)}

where A^\ast is the throat area, which is here the outlet area of the convergent nozzle.
Since in both cases of operative and inoperative afterburner, the nozzle is choked and the mass flow is constant

\therefore \frac{A^\ast_1 P_0}{\sqrt{R \times 900}} \sqrt{\gamma_1}\left(\frac{2}{\gamma_1+1} \right) ^{(\gamma_1+1)/2(\gamma_1-1)}=\frac{A^\ast_2 \times 0.95 P_0}{\sqrt{R \times 2000}} \sqrt{\gamma_2}\left(\frac{2}{\gamma_2+1} \right) ^{(\gamma_2+1)/2(\gamma_2-1)} \\ \therefore \frac{A^\ast_2}{A^\ast_1} =\sqrt{\frac{2000}{900} }\frac{1}{0.95} \sqrt{\frac{1.353}{1.279} }\frac{(0.85)^{3.3329}}{(0.8776)^{4.084}}

The area ratio is

A^\ast_2 / A^\ast_1=1.4907 \times 1.0526 \times 1.0285 \times \frac{0.5817}{0.5867} =1.6.