Simultaneous Material and Energy Balances The ethanol dehydrogenation reaction of Example 9.5-3 is carried out with the feed entering at 300°C. The feed contains 90.0 mole% ethanol and the balance acetaldehyde and enters the reactor at a rate of 150 mol/s. To keep the temperature from dropping too

Question

Simultaneous Material and Energy Balances
The ethanol dehydrogenation reaction of Example 9.5-3 is carried out with the feed entering at 300°C. The feed contains 90.0 mole% ethanol and the balance acetaldehyde and enters the reactor at a rate of 150 mol/s.
To keep the temperature from dropping too much and thereby decreasing the reaction rate to an unacceptably low level, heat is transferred to the reactor. When the heat addition rate is 2440 kW, the outlet temperature is 253°C. Calculate the fractional conversion of ethanol achieved in the reactor.

Accepted Answer

A degree-of-freedom analysis based on atomic species balances (see Section 4.7) is as follows:

[latex]\begin{matrix}3 unknown labeled variables (\dot{n}_{1},\dot{n}_{2},\dot{n}_{3}) \ - 2 independent atomic species balances (C and H)\ - 1 energy balance \ \hline =0 degrees of freedom \end{matrix} [/latex]

(Convince yourself that there are only two independent atomic balances by writing the C and O balances and observing that they yield the same equation.)
Balance on C

[latex]\begin{matrix}\begin{array}{c|c|c} 150 mol& 0.900 mol C_{2}H_{5}OH &2 mol C\ \hline s &mol &1 mol C_{2}H_{5}OH\end{array} + \begin{array}{c|c|c}150 mol &0.100 mol CH_{3}CHO& 2 mol C \ \hline s& mol &1 mol CH_{3}CHO\end{array} \ = \begin{array}{c|c} \dot{n}_{1} (mol C_{2}H_{5}OH)& 2 mol C\ \hline s&1 mol C_{2}H_{5}OH \end{array} + \begin{array}{c|c} \dot{n}_{2} (mol CH_{3}CHO)& 2 mol C\ \hline s&1 mol CH_{3}CHO \end{array} \\left. \Large{\Downarrow} ight.\ \dot{n}_{1}+\dot{n}_{2}= 150 mol/s \pmb{(1)}\end{matrix} [/latex]

Balance on H

[latex]\begin{matrix}[(150)(0.900)(6)+(150)(0.100)(4)] mol H/s = 6\dot{n}_{1}+4\dot{n}_{2}+ 2\dot{n}_{3} (Convince yourself)\\left. \Large{\Downarrow} ight.\ 3\dot{n}_{1}+2\dot{n}_{2}+ \dot{n}_{3}= 435 mol H/s \pmb{(2)}\end{matrix} [/latex]

Energy Balance
In the last example we used molecular species as references for specific enthalpy calculations. This time we will use elemental species [C(s), [latex]H_{2}(g), O_{2}(g)[/latex]] at 25°C and 1 atm. (For a single reaction both choices require about the same computational effort.) The energy balance neglecting shaft work and kinetic and potential energy changes becomes

[latex]\dot{Q}=\Delta \dot{H}= \sum{\dot{n}_{out}\hat{H}_{out}} - \sum {\dot{n}_{in}\hat{H}_{in}}[/latex]

[latex]\Delta \dot{H}= \sum{\dot{n}_{out}\hat{H}_{out}} - \sum{ \dot{n}_{in} \hat{H}_{in}}[/latex] (9.5-2)

The value of [latex]\dot{Q}[/latex] is 2440 kJ/s and the expression forΔ[latex]\dot{H}[/latex] is that of Equation 9.5-2. The specific enthalpies of the species at the inlet and outlet of the process relative to their elemental constituents are calculated as

[latex]\hat{H}_{i} = \Delta \hat{H}^{°}_{fi} + \int_{25°C}^{T}{C_{pi}(T) dT} [/latex]

where T is 300°C at the inlet and 253°C at the outlet. Taking standard heats of formation from Table B.1 (or APEx function DeltaHfg), formulas for C[latex]_{p}[/latex] of ethanol vapor and hydrogen from Table B.2 (or APEx function Enthalpy for the integrals of those formulas), and the formula for C[latex]_{p}[/latex] of acetaldehyde vapor from Example 9.5-3, we calculate the values of [latex]\hat{H}_{i}[/latex] shown in the inlet–outlet enthalpy table.

The energy balance ( [latex]\dot{Q}= \sum{\dot{n}_{out} \hat{H}_{out}} - \sum {\dot{n}_{in}\hat{H}_{in}}[/latex] ) becomes

[latex]\begin{matrix}2440 kJ/s =[- 216.81\dot{n}_{1} - 150.90\dot{n}_{2}+6.595\dot{n}_{3} - (135)(- 212.19) - (15)(- 147.07)] kJ/s\\left. \Large{\Downarrow} ight.\216.81\dot{n}_{1} + 150.90\dot{n}_{2} - 6.595\dot{n}_{3} = 28,412 kJ/s \pmb{(3)}\end{matrix} [/latex]

Solving Equations 1 through 3 simultaneously (e.g., with Excel’s Solver) yields

[latex]\dot{n}_{1}= 92.0 mol C_{2}H_{5}OH/s\ \dot{n}_{2} = 58.0 mol CH_{3}CHO/s\ \dot{n}_{3} = 43.0 mol H_{2}/s[/latex]

The fractional conversion of ethanol is

[latex]x= \frac{(\dot{n}_{C_{2}H_{5}OH})_{in} - (\dot{n}_{C_{2}H_{5}OH})_{out}}{(\dot{n}_{C_{2}H_{5}OH})_{in}} = \frac{(135 - 92.0) mol/s}{135 mol/s} =\boxed{0.319} [/latex]

Substance	$\dot{n}_{in}$ (mol/s)	$\hat{H}_{in}$ (kJ/mol)	$\dot{n}_{out}$ (mol/s)	$\hat{H}_{out}$ (kJ/mol)
$C_{2}H_{5}OH$	135	-212.19	$\dot{n}_{1}$	– 216.81
$CH_{3}CHO$	15	-147.07	$\dot{n}_{2}$	– 150.90
$H_{2}$	—	—	$\dot{n}_{3}$	6.595

Question 9.5.4: Simultaneous Material and Energy Balances The ethanol dehydr......

Related Answered Questions

Verified Answer:

Verified Answer:

Verified Answer:

Verified Answer:

Energy Balance About an Ammonia Oxidizer One hundred mol NH3/s and 200 mol O2/s at 25°C are fed into a reactor in which the ammonia is completely consumed. The product gas emerges at 300°C. Calculate the rate at which heat must be transferred to or from the reactor, assuming operation at ...

Verified Answer:

Determination of a Heat of Reaction from Heats of Formation Determine the standard heat of reaction for the combustion of liquid n-pentane, assuming H2O(l) is a combustion product. C5H12(l) + 8O2(g) → 5CO2(g) + 6H2O(l) ...

Verified Answer:

Calculation of a Heat of Reaction from Heats of Combustion Calculate the standard heat of reaction for the dehydrogenation of ethane: C2H6 → C2H4 + H2 ...

Verified Answer:

Calculation of an Adiabatic Flame Temperature Liquid methanol is to be burned with 100% excess air. The engineer designing the furnace must calculate the highest temperature that the furnace walls will have to withstand so that an appropriate material of construction can be chosen. Perform this ...

Verified Answer:

Verified Answer:

Verified Answer: