Chapter 8.8, Problem 75P

a)

To determine

The maximum work potential $\left({\Phi }_1\right)$ of the helium at the initial state

Answer to Problem 75P

The maximum work potential $\left({\Phi }_1\right)$ of the helium at the initial state is $\underset{\_}{5.27\text{kJ}}$.

Explanation of Solution

Write the expression for the initial mass $\left(m_1\right)$ of helium in the cylinder.

$m_1=\frac{P_{1}V}{R{T}_1}$ (I)

Here, initial pressure is $P_1$, initial volume of the cylinder is $V_1$, mass of helium gas is $m$ and gas constant of helium gas is $R$.

Write the expression for the final mass $\left(m_2\right)$ of helium in the cylinder.

$\begin{array}{c}{m}_2=m_e\\ =\frac{m_1}{2}\end{array}$ . (II)

Here, exit mass of helium from the cylinder is $m_e$.

Write the expression for the initial specific volume $\left(v_1\right)$ of helium.

$v_1=\frac{R{T}_1}{P_1}$ . (III)

Write the expression for the dead-state volume $\left(v_0\right)$ of helium.

$v_0=\frac{R{T}_0}{P_0}$ . (IV)

Here, dead-state temperature is $T_0$ and dead-state pressure is $P_0$.

Write the expression for the difference between initial entropy $\left(s_1\right)$ and dead-state entropy $\left(s_0\right)$ as;

$s_1-s_0=c_p\ln \frac{T_1}{T_0}-R\ln \frac{P_1}{P_0}$ . (V)

Here, specific heats of helium is $c_p$.

Write the expression for the maximum work potential $\left({\Phi }_1\right)$ of the helium at the initial state.

${\Phi }_1=m_1\left[P_0\left(v_1-v_0\right)-T_0\left(s_1-s_0\right)\right]$ . (VI)

Conclusion:

From the Table A-2, “Ideal-gas specific heats of various common gases table”, select the value of $R$ for helium as $\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\left(\text{2}\text{.0769}\text{kJ}/\text{kg}\cdot \text{K}\right)$.

Substitute $\text{200}\text{kPa}$ for $P_1$, $\text{0}\text{.12}{\text{m}}^{\text{3}}$ for $V_1$, $\text{20°C}$ for $T_1$ and $\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$ in equation (I).

$\begin{array}{c}{m}_1=\frac{\left(\text{200}\text{kPa}\right)\left(\text{0}\text{.12}{\text{m}}^{\text{3}}\right)}{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20°C}\right)}\\ =\frac{\text{24}\text{kPa}\cdot {\text{m}}^{\text{3}}}{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20}+\text{273}\right)\text{K}}\\ =\frac{\text{24}\text{kPa}\cdot {\text{m}}^{\text{3}}}{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{293}\text{K}\right)}\\ =0.03944\text{kg}\end{array}$

Substitute $0.03944\text{kg}$ for $m_1$ in Equation (II).

$\begin{array}{c}{m}_2=\frac{0.03944\text{kg}}{2}\\ =0.01972\text{kg}\end{array}$

Substitute $\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$, $\text{20°C}$ for $T_1$, and $\text{200}\text{kPa}$ for $P_1$ in equation (III)

$\begin{array}{c}{v}_1=\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20°C}\right)}{\text{200}\text{kPa}}\\ =\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20}+273\right)\text{K}}{\text{200}\text{kPa}}\\ =\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{29}3\text{K}\right)}{\text{200}\text{kPa}}\\ =3.043{\text{m}}^{\text{3}}/\text{kg}\end{array}$

Substitute $\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$, $\text{20°C}$ for $T_0$, and $\text{95}\text{kPa}$ for $P_0$ in equation (IV).

$\begin{array}{c}{v}_0=\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20°C}\right)}{\text{95}\text{kPa}}\\ =\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{20}+273\right)\text{K}}{\text{95}\text{kPa}}\\ =\frac{\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{29}3\text{K}\right)}{\text{95}\text{kPa}}\\ =6.406{\text{m}}^{\text{3}}/\text{kg}\end{array}$

From the Table A-2, “Ideal-gas specific heats of various common gases table”, select the value of $c_p$ for helium as $\text{5}\text{.1926}\text{kJ}/\text{kg}\cdot \text{K}$

Substitute $\text{5}\text{.1926}\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$, $\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$, $\text{20°C}$ for $T_1\text{and}{T}_0$ respectively, $\text{95}\text{kPa}$ for $P_0$, and $\text{200}\text{kPa}$ for $P_1$ in Equation (V).

$\begin{array}{c}{s}_1-s_0=\left(\text{5}\text{.1926}\text{kJ}/\text{kg}\cdot \text{K}\right)\left(\ln \frac{\text{20°C}}{\text{20°C}}\right)-\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\ln \frac{\text{200}\text{kPa}}{\text{95}\text{kPa}}\right)\\ =\left[\left(\text{5}\text{.1926}\text{kJ}/\text{kg}\cdot \text{K}\right)\left(0\right)\right]-\left(\text{2}\text{.0769}\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(0.7444\right)\\ =-1.546\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\end{array}$

Substitute $0.03944\text{kg}$ for $m_1$, $\text{20°C}$ for $T_0$, $-1.546\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $s_1-s_0$, $\text{95}\text{kPa}$ for $P_0$, $3.043{\text{m}}^{\text{3}}/\text{kg}$ for $v_1$ and $6.406{\text{m}}^{\text{3}}/\text{kg}$ for $v_2$ in equation (VI).

$\begin{array}{c}{\Phi }_1=\left(0.03944\text{kg}\right)\left[\begin{array}{c}\text{95}\text{kPa}\left(3.043-6.406\right){\text{m}}^{\text{3}}/\text{kg}-\\ \text{20°C}\left(-1.546\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\end{array}\right]\\ =\left(0.03944\text{kg}\right)\left[\begin{array}{l}\text{95}\text{kPa}\left(-3.363{\text{m}}^{\text{3}}/\text{kg}\right)\\ -\left(\text{20}+\text{273}\right)\text{K}\left(-1.546\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\end{array}\right]\\ =\left(0.03944\text{kg}\right)\left[\begin{array}{l}-319.485\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\\ -\left(\text{293}\text{K}\right)\left(-1.546\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\end{array}\right]\\ =\left(0.03944\text{kg}\right)\left(-319.485\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}+452.978\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\right)\end{array}$

$\begin{array}{c}=\left(0.03944\text{kg}\right)\left(133.493\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\right)\\ =5.27\text{kPa}\cdot {\text{m}}^{\text{3}}\left(\frac{\text{kJ}}{\text{kPa}\cdot {\text{m}}^{\text{3}}}\right)\\ =5.27\text{kJ}\end{array}$

Thus, the maximum work potential $\left({\Phi }_1\right)$ of the helium at the initial state is $\underset{\_}{5.27\text{kJ}}$.

b)

To determine

The exergy destroyed during the process $\left(X_{\text{destroyed}}\right)$

Answer to Problem 75P

The exergy destroyed during the process $\left(X_{\text{destroyed}}\right)$ is $\underset{\_}{0}$.

Explanation of Solution

Write the mass balance equation for the system as,

$\begin{array}{l}{m}_{\text{in}}-m_{\text{out}}=\Delta m_{\text{system}}\\ m_e=m_1-m_2\end{array}$ . (VII)

Here, mass of the helium at the inlet of cylinder is $m_{\text{in}}$, mass of the helium coming out from the cylinder is $m_{\text{out}}$, net mass of the helium within the system is $\Delta m_{\text{system}}$, mass of helium at the exit is $m_e$, initial and final mass of the helium is $m_1\text{and}{m}_2$ respectively.

Write the Energy balance for the uniform flow system as;

$\begin{array}{l}{E}_{\text{in}}-E_{\text{out}}=\Delta E_{\text{system}}\\ Q_{\text{in}}-m_e{h}_e+W_{b,in}=m_2{u}_2-m_1{u}_1\end{array}$ . (VIII)

Here, net energy transfer in to the control volume is $E_{\text{in}}$, net energy transfer exit from the control volume is $E_{\text{out}}$, change in internal energy of system is $\Delta E_{\text{system}}$.heat transfer during the process is $Q_{\text{in}}$, enthalpy of helium at exit is $h_e$, boundary work done inside the cylinder is $W_{b,\text{in}}$, initial internal energy is $u_1$ and final internal energy is $u_2$.

Combine Equation (VII) and Equation (VIII) to get,

$\begin{array}{c}{Q}_{\text{in}}=\left(m_1-m_2\right)h_e+m_2{u}_2-m_1{u}_1-W_{b,in}\\ =\left(m_1-m_2\right)h_e+m_2{h}_2-m_1{h}_1-W_{b,in}\\ =\left(m_1-m_2\right)h_1+m_2{h}_1-m_1{h}_1-W_{b,in}\\ =\left(m_1-m_2+m_2-m_1\right)h_1-0\\ =0\end{array}$

Write the expression for the entropy balance for helium.

$\begin{array}{l}{S}_{\text{in}}-S_{\text{out}}+S_{\text{gen}}=\Delta S_{\text{system}}\\ -m_e{s}_e+S_{\text{gen}}=m_2{s}_2-m_1{s}_1\\ S_{\text{gen}}=m_2{s}_2-m_1{s}_1+m_e{s}_e\end{array}$ (IX)

Here, entropy generation is $S_{\text{gen}}$, change of entropy is $\Delta S_{\text{system}}$, entropy at inlet condition is $S_{\text{in}}$, entropy at outlet condition is $S_{\text{out}}$, and source temperature is $T_{\text{source}}$.

Substitute $m_1-m_2$ for $m_e$ in Equation (IX).

$S_{\text{gen}}=m_2{s}_2-m_1{s}_1+\left(m_1-m_2\right)s_e$

$\begin{array}{c}{S}_{\text{gen}}=m_2{s}_1-m_1{s}_1+\left(m_1-m_2\right)s_1\\ =\left(m_2-m_1+m_1-m_2\right)s_1\\ =0\end{array}$

Write the expression for the exergy destroyed during the process $\left(X_{\text{destroyed}}\right)$.

$X_{\text{destroyed}}=T_0{S}_{\text{gen}}$ (X)

Conclusion:

Substitute $\text{20°C}$ for $T_0$ and 0 for $S_{\text{gen}}$ in equation (X)

$\begin{array}{c}{X}_{\text{destroyed}}=\left(\text{20°C}\right)\left(0\right)\\ =0\end{array}$

Thus, the exergy destroyed during the process $\left(X_{\text{destroyed}}\right)$ is $\underset{\_}{0}$.