Chapter 9.12, Problem 147P

To determine

The exergy destruction for each of the processes of the cycle

Answer to Problem 147P

The exergy destruction associated with process 1-2 is $19.2\text{kJ}/\text{kg}$.

The exergy destruction associated with process 5-3 is $38\text{kJ}/\text{kg}$.

The exergy destruction associated with process 3-4 is $16.1\text{kJ}/\text{kg}$.

The exergy destruction associated with process 6-1 is $85.5\text{kJ}/\text{kg}$.

The exergy destruction associated at regenerator is $0.41\text{kJ}/\text{kg}$.

Explanation of Solution

Draw the $T-s$ diagram of the regenerative Brayton cycle as shown in Figure (1).

Write the expression for the temperature and pressure relation for the isentropic process 1-2.

$T_{2s}=T_1{r}_p^{(k-1)/k}$ (I)

Here, the pressure ratio is $r_p$, and the specific heat ratio is k.

Write the expression for the efficiency of the compressor $\left({\eta }_C\right)$.

${\eta }_C=\frac{c_p\left(T_{2s}-T_1\right)}{c_p\left(T_2-T_1\right)}$ (II)

Here, the specific heat at constant pressure is $c_p$.

Write the expression for the temperature and pressure relation ratio for the expansion process 4-5s.

$T_{5s}=T_4{\left(\frac{1}{r_p}\right)}^{\left(k-1\right)/k}$ (III)

Write the expression for the efficiency of the turbine $\left({\eta }_T\right)$.

${\eta }_T=\frac{c_p\left(T_4-T_5\right)}{c_p\left(T_4-T_{5s}\right)}$ (IV)

Apply first law to the heat exchanger.

$\begin{array}{l}m{c}_p(T_3-T_2)=m{c}_p(T_5-T_6)\\ (T_3-T_2)=(T_5-T_6)\\ T_6=T_5+T_2-T_3\end{array}$ (V)

Write the expression for the net work done per kg for the Brayton cycle with regeneration $\left(w_{\text{net}}\right)$.

$w_{\text{net}}=c_p\left(T_4-T_5\right)-c_p\left(T_2-T_1\right)$                                   (VI)

Here, the specific heat at constant pressure is $c_p$.

Write the expression of heat addition to the regenerative Brayton cycle $\left(q_{\text{in}}\right)$.

$q_{\text{in}}=c_p\left(T_4-T_3\right)$                                       (VII)

Write the expression for rate of heat rejection in the regenerative Brayton cycle $\left(q_{\text{out}}\right)$.

$q_{\text{out}}=c_p\left(T_6-T_1\right)$ (VIII).

Write the expression for the exergy destruction during the process of as steam from an inlet to exit state.

$\begin{array}{l}{x}_{\text{destroyed}}=T_0{s}_{gen}\\ x_{\text{destroyed}}=T_0\left(s_e-s_i-\frac{q_{in}}{T_{source}}+\frac{q_{in}}{T_{\text{sink}}}\right)\end{array}$

Write the expression of exergy destruction for process 1-2 $\left(x_{\text{destroyed,1-2}}\right)$.

$x_{\text{destroyed,1-2}}=T_0\left(c_p\ln \frac{T_2}{T_1}-R\ln \frac{P_2}{P_1}\right)$ (IX)

Here, pressure at state 2 is $P_2$, the pressure at state 1 is $P_1$ and surrounding temperature is $T_0$.

Write the expression of exergy destruction for process 5-3 $\left(x_{\text{destroyed,5-3}}\right)$.

$x_{\text{destroyed,5-3}}=T_0\left(c_p\ln \frac{T_3}{T_5}-R\ln \frac{P_3}{P_5}-\frac{q_{in}}{T_{\text{source}}}\right)$ (X)

Here, pressure at state 5 is $P_5$ and the pressure at state 6 is $P_6$.

Write the expression of exergy destruction for process 3-4 $\left(x_{\text{destroyed,3-4}}\right)$.

$x_{\text{destroyed,3-4}}=T_0\left(c_p\ln \frac{T_4}{T_5}-R\ln \frac{P_4}{P_3}\right)$ (XI)

Here, pressure at state 7 is $P_7$

Write the expression of exergy destruction for process 6-1 $\left(x_{\text{destroyed,6-1}}\right)$.

$x_{\text{destroyed,6-1}}=T_0\left(c_p\ln \frac{T_1}{T_6}-R\ln \frac{P_1}{P_{10}}-\frac{q_{out}}{T_{\text{sink}}}\right)$ (XII)

Here, pressure at state 10 is $P_{10}$ and temperature at state 10 is $T_{10}$.

Write the expression of exergy destruction for regenerator $\left(x_{\text{destroyed,regen}}\right)$.

$\begin{array}{l}{x}_{\text{destroyed,regen}}=T_0\left(\Delta s_{2-5}+\Delta s_{4-6}\right)\\ x_{\text{destroyed,regen}}=T_0\left(c_p\ln \frac{T_5}{T_2}+c_p\ln \frac{T_6}{T_4}\right)\end{array}$ (XIII)

Conclusion:

Substitute $20°\text{C}$ for $T_1$, $8$ for $r_p$ and 1.4 for k in Equation (I).

$\begin{array}{c}{T}_{2s}=\left(20°\text{C}\right){\left(8\right)}^{1.4-1/1.4}\\ =\left(20+273\right)\text{K}{\left(8\right)}^{1.4-1/1.4}\\ =530.8\text{K}\end{array}$

Substitute $20°\text{C}$ for $T_1$, $530.8\text{K}$ for $T_{2s}$ and 0.87 for ${\eta }_C$ in Equation (II).

$\begin{array}{c}{T}_2=20°\text{C}+\frac{585\text{K}-20°\text{C}}{0.87}\\ =\left(20+273\right)\text{K+}\frac{585\text{K}-\left(20+273\right)\text{K}}{0.87}\\ =566.3\text{K}\end{array}$

Substitute $800°\text{C}$ for $T_4$, $8$ for $r_p$ and 1.4 for k in Equation (III).

$\begin{array}{c}{T}_{5s}=\left(800°\text{C}\right){\left(\frac{1}{8}\right)}^{1.4-1/1.4}\\ =\left(800+273\right)\text{K}\times {\left(\frac{1}{8}\right)}^{1.4-1/1.4}\\ =592.3\text{K}\end{array}$

Substitute $800°\text{C}$ for $T_4$, $592.3\text{K}$ for $T_{5s}$ and 0.93 for ${\eta }_T$ in Equation (IV).

$\begin{array}{c}{T}_5=800°\text{C}-\left(0.93\right)\left(800°\text{C}-592.3\text{K}\right)\\ =\left(800+273\right)\text{K}-\left(0.93\right)\left[\left(800+273\right)\text{K}-592.3\text{K}\right]\\ =625.9\text{K}\end{array}$

The cold airstream $\left(T_3\right)$ leaves the regenerator 10°C cooler than the hot airstream $\left(T_5\right)$ at the inlet of the regenerator.

$T_3=T_5-10$ (XIV).

Substitute $625.9\text{K}$ for $T_5$ in Equation (XIV).

$\begin{array}{c}{T}_3=\left(625.9\text{K}-\text{273}°\text{C}\right)-10°\text{C}\\ T_3\text{= 352}\text{.9}°\text{C}-10°\text{C}\end{array}$

$\begin{array}{c}{T}_3\text{= 342}\text{.9}°\text{C}\\ \text{=}\left(\text{342}\text{.9}+273\right)\text{K}\\ \text{= 615}\text{.9}\text{K}\end{array}$

Substitute $\text{615}\text{.9}\text{K}$ for $T_3$, $625.9\text{K}$ for $T_5$ and $566.3\text{K}$ for $T_2$ in Equation (V).

$\begin{array}{c}{T}_6=625.9\text{K}+566.3\text{K}-\text{615}\text{.9}\text{K}\\ =576.3\text{K}\end{array}$

Substitute $1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$, $800°\text{C}$ for $T_4$, $625.9\text{K}$ for $T_5$, $566.3\text{K}$ for $T_2$ and $20°\text{C}$ for $T_1$ in Equation (VI).

$\begin{array}{c}{w}_{\text{net}}=\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\left(800°\text{C}-625.9\text{K}\right)\right]-\left[\left(566.3\text{K}-20°\text{C}\right)\right]\\ =\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\left(\left(800+273\right)\text{K}-625.9\text{K}\right)\right]-\left[\left(566.3\text{K}-\left(20+273\right)\text{K}\right)\right]\\ =174.7\text{kJ}/\text{kg}\end{array}$

Substitute $1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$, $800°\text{C}$ for $T_4$ and $\text{615}\text{.9}\text{K}$ for $T_3$ in Equation (VII).

$\begin{array}{c}{q}_{\text{in}}=\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left(800°\text{C}-\text{615}\text{.9}\text{K}\right)\\ =\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\left(800+273\right)\text{K}-\text{615}\text{.9}\text{K}\right]\\ =\text{459}\text{.4}\text{kJ}/\text{kg}\end{array}$

Substitute $1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$, $576.3\text{K}$ for $T_6$ and $20°\text{C}$ for $T_1$ in Equation (VIII).

$\begin{array}{c}{q}_{\text{out}}=\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left(576.3\text{K}-20°\text{C}\right)\\ =\left(1.005\text{}\text{kJ}/\text{kg}\cdot \text{K}\right)\left[576.3\text{K}-\left(20+273\right)\text{K}\right]\\ =\text{284}\text{.7}\text{kJ}/\text{kg}\end{array}$

Substitute $20°\text{C}$ for $T_0$, $1.005\text{kJ}/\text{kg}$ for $c_p$ , $566.3\text{K}$ for $T_2$ , $20°\text{C}$ for $T_1$ , $0.287\text{kJ}/\text{kg}\cdot \text{K}$ for $R$ and $8$ for $\left(\frac{P_2}{P_1}\right)$ in Equation (IX).

$\begin{array}{c}{x}_{\text{destroyed,1-2}}=20°\text{C}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\right)\ln \frac{566.3\text{K}}{20°\text{C}}\\ -\left(0.287\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \left(8\right)\end{array}\right)\\ =\left(20+273\right)\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\right)\ln \frac{566.3\text{K}}{\left(20+273\right)\text{K}}\\ -\left(0.287\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \left(8\right)\end{array}\right)\\ =19.2\text{kJ}/\text{kg}\end{array}$

Thus, the exergy destruction associated with process 1-2 is $19.2\text{kJ}/\text{kg}$.

Here, $\left(P_3=P_5\right)$

Substitute $293\text{K}$ for $T_0$, $1.005\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$ , $1073\text{K}$ for $T_3$ , $615.9\text{K}$ for $T_5$ ,$0.287\text{kJ}/\text{kg}\cdot \text{K}$ for $R$ , $\text{459}\text{.4}\text{kJ}/\text{kg}$ for $q_{in}$ and $1073\text{K}$ for $T_{\text{source}}$ in Equation (X).

$\begin{array}{c}{x}_{\text{destroyed,5-3}}=293\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{1073\text{K}}{615.9\text{K}}\\ -\left(0.287\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \left(\frac{P_5}{P_5}\right)-\frac{\text{459}\text{.4}\text{kJ}/\text{kg}}{1073\text{K}}\end{array}\right)\\ =293\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{1073\text{K}}{615.9\text{K}}\\ -0-\frac{\text{459}\text{.4}\text{kJ}/\text{kg}}{1073\text{K}}\end{array}\right)\\ =38\text{kJ}/\text{kg}\end{array}$

Thus, the exergy destruction associated with process 5-3 is $38\text{kJ}/\text{kg}$.

Substitute $625.9\text{K}$ for $T_4$, $1.005\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$ , $1073\text{K}$ for $T_5$ , $293\text{K}$ for $T_0$ , $0.287\text{kJ}/\text{kg}\cdot \text{K}$ for $R$ and $\frac{1}{8}$ for $\left(\frac{P_4}{P_3}\right)$ in Equation (XI).

$\begin{array}{c}{x}_{\text{destroyed,3-4}}=293\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{625.9\text{K}}{1073\text{K}}\\ -\left(0.287\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \left(\frac{1}{8}\right)\end{array}\right)\\ =16.1\text{kJ}/\text{kg}\end{array}$

Thus, the exergy destruction associated with process 3-4 is $16.1\text{kJ}/\text{kg}$.

Here,$\left(P_1=P_6\right)$

Substitute $520\text{R}$ for $T_0$, $1.005\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$ , $576.3\text{K}$ for $T_6$ , $520\text{R}$ for $T_1$ , $0.287\text{kJ}/\text{kg}\cdot \text{K}$ for $R$ , $\text{284}\text{.7}\text{kJ}/\text{kg}$ for $q_{out}$ and $293\text{K}$ for $T_{\text{sink}}$ in Equation (XII).

$\begin{array}{c}{x}_{\text{destroyed,6-1}}=293\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{293\text{K}}{576.3\text{K}}\\ -\left(0.287\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{P_6}{P_6}-\frac{q_{out}}{293\text{K}}\end{array}\right)\\ =293\text{K}\left(\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{293\text{K}}{576.3\text{K}}\\ -0-\frac{\text{284}\text{.7}\text{kJ}/\text{kg}}{293\text{K}}\end{array}\right)\\ =85.5\text{kJ}/\text{kg}\end{array}$

Thus, the exergy destruction associated with process 6-1 is $85.5\text{kJ}/\text{kg}$.

Substitute $615.9\text{K}$ for $T_5$, $1.005\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$ , $625.9\text{K}$ for $T_4$ , $576.3\text{K}$ for $T_6$ , $566.3\text{K}$ for $T_2$, and $293\text{K}$ for $T_0$ in Equation (XIII).

$\begin{array}{c}{x}_{\text{destroyed,regen}}=\left(293\text{K}\right)\times 1.005\text{kJ}/\text{kg}\cdot \text{K}\left(\ln \frac{615.9\text{K}}{566.3\text{K}}+\ln \frac{576.3\text{K}}{625.9\text{K}}\right)\\ =0.41\text{kJ}/\text{kg}\end{array}$

Thus, the exergy destruction associated at regenerator is $0.41\text{kJ}/\text{kg}$.