A binary \(A\)-\(B\) liquid mixture containing 30 mol% \(A\) is subjected to differential (Rayleigh) distillation at atmospheric pressure in order to recover 60 mol% \(A\) in the distillate. Assuming a constant relative volatility \(\alpha_{AB} = 2.2\), the average composition of the collected distillate is __________ mol% \(A\) (rounded off to the nearest integer).
A binary \(A\)-\(B\) liquid mixture containing 30 mol% \(A\) is subjected to differential (Rayleigh) distillation at atmospheric pressure in order to recover 60 mol% \(A\) in the distillate. Assuming a constant relative volatility \(\alpha_{AB} = 2.2\), the average composition of the collected distillate is __________ mol% \(A\) (rounded off to the nearest integer).
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Solution and Explanation
\[ x_0 = 30\% \quad \text{(mole fraction of A in the feed)} \] \[ y_D = 60\% \quad \text{(mole fraction of A in the distillate)} \] \[ \alpha_{AB} = 2.2 \quad \text{(relative volatility)} \]
Step 2: Apply Rayleigh Equation.The Rayleigh equation for differential distillation is:
\[ \frac{d \ln\left(\frac{x}{1 - x}\right)}{d \ln\left(\frac{y}{1 - y}\right)} = \alpha_{AB} \]
After integrating and applying the given conditions, the average composition of the distillate is found to be:
\[ \boxed{47} \, \text{mol\% A} \]
Final Answer: The average composition of the distillate is 47 mol% A.Top Questions on Distillation
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