Chapter 19, Problem 83P

(a)

To determine

To sketch the cycle on PV diagram.

Explanation of Solution

Introduction:

The Brayton cycle consists of various thermodynamic process, an adiabatic compression, an isobaric expansion, an adiabatic expansion and an isobaric compression.

The figure below shows the PV curve of Brayton cycle,

  

Figure (1)

From the range of temperature $T_1$ to $T_2$ , the process called an adiabatic compression, for the temperature range of $T_2$ to $T_3$ , the process is isobaric process, for the temperature $T_3$ to $T_4$ , the process is adiabatic expansion and for the temperature $T_4$ to $T_1$ . The process is isobaric compression.

Conclusion:

Therefore, the diagram of PV curve on Brayton cycle is shown in figure (1).

(b)

To determine

Show that the efficiency of the cycle as $\epsilon =1-\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}$

Answer to Problem 83P

The efficiency of the cycle as $\epsilon =1-\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}$ .

Explanation of Solution

Formula used:

The expression for the efficiency is,

  $E=1-\frac{Q_c}{Q_h}$

Here, the heat absorbed from the heat reservoir during isobaric expansion is $Q_h$ and heat delivered to cold reservoir during isobaric compression is $Q_c$ .

The expression for change in enthalpy from first law of thermodynamics is,

  $Q=d{E}_{in}+W$

The expression for ideal gas law is,

  $pV=nRT$

The expression for work done throught the cycle is,

  $W=W_{AB}+W_{BC}+W_{CD}+W_{DA}$

Calculation:

The heat absorbed from the heat reservoir during isobaric expansion is calculated as,

  $\begin{array}{c}{Q}_h=C_p\left(T_3-T_2\right)+P_h\left(V_3-V_2\right)\\ =C_p\left(T_3-T_2\right)+P_h{V}_3-P_h{V}_2\end{array}$

By using the ideal gas law we get,

  $\begin{array}{c}{Q}_h=C_p\left(T_3-T_2\right)+nR{T}_3-nR{T}_2\\ =C_p\left(T_3-T_2\right)+nR\left(T_3-T_2\right)\\ =\left(C_p+nR\right)\left(T_3-T_2\right)\end{array}$

Similarly,

The delivered to cold reservoir during isobaric compression is calculated as

  $\begin{array}{c}{Q}_c=-\left[C_p\left(T_1-T_4\right)+P_L\left(V_1-V_4\right)\right]\\ =-\left[C_p\left(T_1-T_4\right)+P_L{V}_1-P_L{V}_4\right]\end{array}$

By using the ideal gas law we get

  $\begin{array}{c}{Q}_c=-\left[C_p\left(T_1-T_4\right)+nR{T}_1-nR{T}_4\right]\\ =\left[C_p+nR\right]\left(T_4-T_1\right)\end{array}$

The efficiency is calculated as,

  $\begin{array}{c}E=1-\frac{\left[C_p+nR\right]\left(T_4-T_1\right)}{\left[C_p+nR\right]\left(T_3-T_2\right)}\\ =1-\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}\end{array}$

Conclusion:

Therefore, the efficiency of the cycle as $\epsilon =1-\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}$ .

(c)

To determine

To show the efficiency is $\epsilon =1-r^{\left(1-\gamma \right)/\gamma }$ .

Answer to Problem 83P

The efficiency is $\epsilon =1-r^{\left(1-\gamma \right)/\gamma }$ .

Explanation of Solution

Formula used:

The expression for adiabatic process is given as,

  $p^{1-\gamma }{T}^{\gamma }=\text{constant}$

Calculation:

The relation between pressure and temperature for adiabatic process AB is calculated as,

  $\begin{array}{l}{P}_L{}^{1-\gamma }{T}_1{}^{\gamma }=P_h{}^{1-\gamma }{T}_2{}^{\gamma }\\ P_L{}^{\frac{1-\gamma }{\gamma }}{T}_1=P_h{}^{\frac{1-\gamma }{\gamma }}{T}_2\end{array}$ ........(1)

The relation between pressure and temperature for adiabatic process CD is calculated as,

  $\begin{array}{l}{P}_L{}^{1-\gamma }{T}_4{}^{\gamma }=P_h{}^{1-\gamma }{T}_3{}^{\gamma }\\ P_L{}^{\frac{1-\gamma }{\gamma }}{T}_4=P_h{}^{\frac{1-\gamma }{\gamma }}{T}_3\end{array}$ ........(2)

Subtracting equation (1) with equation (2) we get,

  $\begin{array}{c}{P}_L{}^{\frac{1-\gamma }{\gamma }}{T}_4-P_L{}^{\frac{1-\gamma }{\gamma }}{T}_1=P_h{}^{\frac{1-\gamma }{\gamma }}{T}_3-P_h{}^{\frac{1-\gamma }{\gamma }}{T}_2\\ {\left(\frac{P_h}{P_L}\right)}^{\frac{1-\gamma }{\gamma }}=\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}\\ {\left(r\right)}^{\frac{1-\gamma }{\gamma }}=\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}\end{array}$

By using efficiency from part (a) we get,

  $\begin{array}{l}E=1-\frac{\left(T_4-T_1\right)}{\left(T_3-T_2\right)}\\ E=1-{\left(r\right)}^{\frac{1-\gamma }{\gamma }}\end{array}$

Conclusion:

Therefore, the efficiency is $\epsilon =1-r^{\left(1-\gamma \right)/\gamma }$ .