A mixture of benzene and toluene containing 10%by mole benzene is continuously distilled at a rate of 1000kmole/h in a distillation column 95% of the benzene in the feed iis recovered as distilled product which contain 98% benzene and2% toluene. calculate the following a. the moles i of the bottom
Answers
Answer:
A binary mixture of benzene and toluene containing 40% of benzene is to be distilled at 1 atm pressure to recover 95% of the benzene. Estimate the molal percent of mixture to be distilled and the composition of the distillate obtained if distillation is carried out by Differential distillation, collecting all the distillate together.
The average relative volatility of benzene to toluene is 2.5.
Calculations:
Basis: 1 mol of feed
Formula:
For an ideal mixture of constant relative volatility, the following equation is used to find the number of moles present in the residue to the moles present initially in the feed:
nB/noB = (nA/noA)(1/aAB) (Reference: Example 18.6 in page no: 508 'Unit Operations of Chemical Engineering, McCabe-Smith, Fourth Edition')
Given:
noA = 0.4 mol
noB = 0.6 mol
nA = (1 - 0.95) x 0.4 = 0.02 mol
aAB = 2.5
Substituting,
nB = 0.6 x (0.02/0.4)(1/2.5) = 0.181 mol
Composition of residue:
xW = 0.02/(0.02 + 0.181) = 0.0995
Composition of distillate:
Moles of benzene in distillate = moles of benzene in feed - moles of benzene in residue
= 0.4 - 0.02 = 0.38
Moles of toluene in distillate = 0.6 - 0.181 = 0.419
xD = 0.38/(0.38 + 0.419) = 0.4756
Mole percent of mixture to be distilled = 100 x (0.38 + 0.419)/1 = 79.9%
The above calculations can also done with the modification of Rayleigh's equation for constant relative volatility system:

Basis: 1 mole of feed mixture
Given:
Moles of Benzene present in the feed = 0.4 = FxF
95% of benzene that was present in the feed is to be recovered in the distillate. Therefore, moles of Benzene present in the residue = (1 - 0.95) x 0.4 = 0.05 x 0.4 = 0.02 = WxW
And xF = 0.4; a = 2.5
F(1 - xF) = F - FxF = 1 - 0.4 = 0.6
Substituting the known quantities in the above equation,
ln (0.4/0.02) = 2.5 x ln [0.6/(W (1 - xW))]
(0.4/0.02)1/2.5 = 0.6 / [W(1 - xW)]
3.31445 = 0.6 / [W(1 - xW)]
W(1 - xW) = 0.181
Therfore, W = W(1 - xW) + WxW = 0.181 + 0.02 = 0.201
Moles percent of mixture to be distilled = F - W = 1 - 0.201 = 0.799
Mole percent of mixture to be distilled = 0.799 x 100 = 79.9%
Composition of distillate:
Moles of toluene in residue = W(1 - xW) = 0.181
Moles of toluene in distillate = moles of toluene in feed - mole of toluene in residue = 0.6 - 0.181 = 0.419
Moles of benzene in distillate = moles of benzene in feed - moles of benzene in residue = 0.4 - 0.02 = 0.38
Mole fraction of benzene in distillate = 0.38 / (0.38 + 0.419) = 0.4756