Chapter 8.8, Problem 49P

(a)

To determine

The amount of heat lost to the surroundings.

Answer to Problem 49P

The amount of heat lost to the surroundings is $\text{2563}\text{kJ}$.

Explanation of Solution

Express the final volume of the air.

${\nu }_{a2}={\nu }_{a1}-{\nu }_w$ (I)

Here, initial volume of air is ${\nu }_{a1}$ and volume of water is ${\nu }_w$.

Express the mass of air in the large tank.

$m_a=\frac{P_1{\nu }_{a1}}{R{T}_{a1}}$ (II)

Here, initial pressure is $P_1$, universal gas constant of air is $R$ and initial temperature of air is $T_{a1}$.

Express the pressure of air at the final state.

$P_{a2}=\frac{m_{a}R{T}_{a2}}{{\nu }_{a2}}$ (III)

Here, final temperature of air is $T_{a2}$.

Express the mass of water.

$m_w={\rho }_w{\nu }_w$ (IV)

Here, density of water is ${\rho }_w$.

Express the amount of heat lost to the surroundings.

$Q_{\text{out}}=-\left[m_w{c}_w\left(T_2-T_{w1}\right)+m_a{c}_{va}\left(T_2-T_{a1}\right)\right]$ (V)

Here, specific heat of water is $c_w$, final temperature is $T_2$, initial temperature of water is $T_{w1}$, specific heat constant of air is $c_{va}$ and initial temperature of air is $T_{a1}$.

Conclusion:

Refer Table A-2, “ideal gas specific heats of various gases”, and write the properties of air at room temperature.

$\begin{array}{l}R=0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\\ c_p=1.005\text{kJ}/\text{kg}\cdot \text{K}\\ c_{va}=0.718\text{kJ}/\text{kg}\cdot \text{K}\end{array}$

Refer Table A-3 (a), “properties of common liquids, solids and foods”, and write the properties of water at room temperature.

$\begin{array}{l}{\rho }_w=997\text{kg}/{\text{m}}^{\text{3}}\\ c_w=4.18\text{kJ}/\text{kg}\cdot \text{K}\end{array}$

Substitute $\text{0}\text{.04}{\text{m}}^{\text{3}}$ for ${\nu }_{a1}$ and $\text{15}\text{L}$ for ${\nu }_w$ in Equation (I).

$\begin{array}{c}{\nu }_{a2}=\text{0}\text{.04}{\text{m}}^{\text{3}}-\text{15}\text{L}\\ =\text{0}\text{.04}{\text{m}}^{\text{3}}-\text{15}\text{L}\left[\frac{{\text{m}}^{\text{3}}}{\text{1000}\text{L}}\right]\\ =\text{0}\text{.04}{\text{m}}^{\text{3}}-0.015{\text{m}}^{\text{3}}\\ =0.025{\text{m}}^{\text{3}}\end{array}$

Substitute $\text{100}\text{kPa}$ for $P_1$, $\text{0}\text{.04}{\text{m}}^{\text{3}}$ for ${\nu }_{a1}$, $0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$ and $\text{22°C}$ for $T_{a1}$ in Equation (II).

$\begin{array}{c}{m}_a=\frac{\left(\text{100}\text{kPa}\right)\left(\text{0}\text{.04}{\text{m}}^{\text{3}}\right)}{\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{22°C}\right)}\\ =\frac{\left(\text{100}\text{kPa}\right)\left(\text{0}\text{.04}{\text{m}}^{\text{3}}\right)}{\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{22}+273\right)\text{K}}\\ =\frac{\left(\text{100}\text{kPa}\right)\left(\text{0}\text{.04}{\text{m}}^{\text{3}}\right)}{\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(295\text{K}\right)}\\ =0.04724\text{kg}\end{array}$

Substitute $0.04724\text{kg}$ for $m_a$, $0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$, $\text{44°C}$ for $T_{a2}$ and $\text{0}\text{.025}{\text{m}}^{\text{3}}$ for ${\nu }_{a2}$ in Equation (III).

$\begin{array}{c}{P}_{a2}=\frac{\left(0.04724\text{kg}\right)\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(\text{44°C}\right)}{\text{0}\text{.025}{\text{m}}^{\text{3}}}\\ =\frac{\left(0.04724\text{kg}\right)\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(44+273\right)\text{K}}{\text{0}\text{.025}{\text{m}}^{\text{3}}}\\ =\frac{\left(0.04724\text{kg}\right)\left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(317\text{K}\right)}{\text{0}\text{.025}{\text{m}}^{\text{3}}}\\ =171.9\text{kPa}\end{array}$

Substitute $997\text{kg}/{\text{m}}^{\text{3}}$ for ${\rho }_w$ and $\text{15}\text{L}$ for ${\nu }_w$ in Equation (IV).

$\begin{array}{c}{m}_w=\left(997\text{kg}/{\text{m}}^{\text{3}}\right)\left(\text{15}\text{L}\right)\\ =\left(997\text{kg}/{\text{m}}^{\text{3}}\right)\left[\text{15}\text{L}\times \frac{{\text{m}}^{\text{3}}}{\text{1000}\text{L}}\right]\\ =\left(997\text{kg}/{\text{m}}^{\text{3}}\right)\left(0.015{\text{m}}^{\text{3}}\right)\\ =14.96\text{kg}\end{array}$

Substitute $14.96\text{kg}$ for $m_w$, $4.18\text{kJ}/\text{kg}\cdot \text{K}$ for $c_w$, $\text{44°C}$ for $T_2$, $\text{85°C}$ for $T_{w1}$, $\text{0}\text{.04724}\text{kg}$ for $m_a$, $0.718\text{kJ}/\text{kg}\cdot \text{K}$ for $c_{va}$ and $\text{22°C}$ for $T_{a1}$ in Equation (V).

$\begin{array}{c}{Q}_{\text{out}}=-\left[\begin{array}{l}\left(14.96\text{kg}\right)\left(4.18\text{kJ}/\text{kg}\cdot \text{K}\right)\left\{\left(44\text{°C}-85\text{°C}\right)\text{K}\right\}+\left(\text{0}\text{.04724}\text{kg}\right)\\ \left(0.718\text{kJ}/\text{kg}\cdot \text{K}\right)\left\{\left(44\text{°C}-22\text{°C}\right)\text{K}\right\}\end{array}\right]\\ =-\left[\begin{array}{l}\left(14.96\text{kg}\right)\left(4.18\text{kJ}/\text{kg}\cdot \text{K}\right)\left(-41\text{K}\right)+\left(\text{0}\text{.04724}\text{kg}\right)\\ \left(0.718\text{kJ}/\text{kg}\cdot \text{K}\right)\left(22\text{K}\right)\end{array}\right]\\ =2563\text{kJ}\end{array}$

Hence, the amount of heat lost to the surroundings is $\text{2563}\text{kJ}$.

(b)

To determine

The exergy destruction during the process.

Answer to Problem 49P

The exergy destruction during the process is $\text{318}\text{kJ}$.

Explanation of Solution

Express entropy change in water.

$\Delta S_w=m_w{c}_w\ln \frac{T_{w1}}{T_2}$ (VI)

Express entropy change in air.

$\Delta S_a=m_a\left[c_p\ln \frac{T_{a1}}{T_2}-R\ln \frac{P_{a1}}{P_2}\right]$ (VII)

Here, initial pressure of air is $P_{a1}$.

Express net internal energy of water.

$\Delta U_w=m_w{c}_w\left(T_{1w}-T_2\right)$ (VIII)

Express net internal energy of air.

$\Delta U_a=m_a{c}_{va}\left(T_{1a}-T_2\right)$ (IX)

Express the exergy destruction during the process.

$X_{\text{dest}}=\Delta U_w-T_0\Delta S_w+\Delta U_a-T_0\Delta S_a$ (X)

Here, surrounding temperature is $T_0$.

Conclusion:

Substitute $\text{14}\text{.96}\text{kg}$ for $m_w$, $4.18\text{kJ}/\text{kg}\cdot \text{K}$ for $c_w$, $\text{44°C}$ for $T_2$ and $\text{85°C}$ for $T_{w1}$ min Equation (VI).

$\begin{array}{c}\Delta S_w=\left(\text{14}\text{.96}\text{kg}\right)\left(4.18\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{\text{85°C}}{\text{44°C}}\\ =\left(\text{14}\text{.96}\text{kg}\right)\left(4.18\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\ln \frac{\text{358}\text{K}}{\text{317}\text{K}}\right]\\ =7.605\text{9}\text{kJ}/\text{K}\end{array}$

Substitute $\text{0}\text{.04724}\text{kg}$ for $m_a$, $1.005\text{kJ}/\text{kg}\cdot \text{K}$ for $c_p$, $\text{44°C}$ for $T_2$, $\text{22°C}$ for $T_{a1}$, $0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}$ for $R$, $\text{100}\text{kPa}$ for $P_{a1}$ and $\text{171}\text{.9}\text{kPa}$ for $P_2$ in Equation (VII).

$\begin{array}{c}\Delta S_a=\left(\text{0}\text{.04724}\text{kg}\right)\left[\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{\text{22°C}}{\text{44°C}}-\\ \left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\ln \frac{\text{100}\text{kPa}}{\text{171}\text{.9}\text{kPa}}\end{array}\right]\\ =\left(\text{0}\text{.04724}\text{kg}\right)\left[\begin{array}{l}\left(1.005\text{kJ}/\text{kg}\cdot \text{K}\right)\ln \frac{\text{295}\text{K}}{317\text{K}}-\\ \left(0.287\text{kPa}\cdot {\text{m}}^{\text{3}}/\text{kg}\cdot \text{K}\right)\left(-0.5417\right)\end{array}\right]\\ =0.003931\text{kJ}/\text{K}\end{array}$

Substitute $\text{14}\text{.96}\text{kg}$ for $m_w$, $4.18\text{kJ}/\text{kg}\cdot \text{K}$ for $c_w$, $\text{44°C}$ for $T_2$ and $\text{85°C}$ for $T_{w1}$ min Equation (VIII).

$\begin{array}{c}\Delta U_w=\left(\text{14}\text{.96}\text{kg}\right)\left(4.18\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\left(\text{85°C}-\text{44°C}\right)\text{K}\right]\\ =2564\text{kJ}\end{array}$

Substitute $\text{0}\text{.04724}\text{kg}$ for $m_a$, $0.718\text{kJ}/\text{kg}\cdot \text{K}$ for $c_{va}$ and $\text{22°C}$ for $T_{a1}$, and $\text{44°C}$ for $T_2$ in Equation (IX).

$\begin{array}{c}\Delta U_a=\left(\text{0}\text{.04724}\text{kg}\right)\left(0.718\text{kJ}/\text{kg}\cdot \text{K}\right)\left[\left(\text{22°C}-\text{44°C}\right)\text{K}\right]\\ =-0.7462\text{kJ}\end{array}$

Substitute $2564\text{kJ}$ for $\Delta U_w$, $\text{22°C}$ for $T_0$, $7.605\text{9}\text{kJ}/\text{K}$ for $\Delta S_w$, $-0.7462\text{kJ}$ for $\Delta U_a$ and $0.003931\text{kJ}/\text{K}$ for $\Delta S_a$ in Equation (X).

$\begin{array}{c}{X}_{\text{dest}}=\left[\begin{array}{l}\left(2564\text{kJ}\right)-\left(\text{22°C}\right)\left(7.605\text{9}\text{kJ}/\text{K}\right)\\ +\left(-0.7462\text{kJ}\right)-\left(\text{22°C}\right)\left(0.003931\text{kJ}/\text{K}\right)\end{array}\right]\\ =\left[\begin{array}{l}\left(2564\text{kJ}\right)-\left(\text{22}+273\right)\text{K}\left(7.605\text{9}\text{kJ}/\text{K}\right)\\ +\left(-0.7462\text{kJ}\right)-\left(\text{22}+273\right)\text{K}\left(0.003931\text{kJ}/\text{K}\right)\end{array}\right]\\ =\left[\begin{array}{l}\left(2564\text{kJ}\right)-\left(295\text{K}\right)\left(7.605\text{9}\text{kJ}/\text{K}\right)\\ +\left(-0.7462\text{kJ}\right)-\left(295\text{K}\right)\left(0.003931\text{kJ}/\text{K}\right)\end{array}\right]\\ =318\text{kJ}\end{array}$

Hence, the exergy destruction during the process is $\text{318}\text{kJ}$.