Iraqi Journal of Chemical and Petroleum Engineering 

 Vol.9 No.4 (December 2008) 29-33 
ISSN: 1997-4884 

 

Study of the Performance of Batch Reactive Distillation Column 
Dr. Cecilia K. Haweel

*
and Taha M.A. Hamza

** 

 
*
Chemical Engineering Department - College of Engineering - University of Baghdad – Iraq 

**
Ministry of Oil- Com. of North Refineries 

Abstract 

Batch reactive distillation was studied in packed bed column. Esterification of methanol with acetic acid to produce 

methyl acetate and water with homogenous sulfuric acid as a catalyst was considered. This system was chosen because 

the reaction is reversible and the boiling point of reactant and products are different.   

The reaction was carried out with and without distillation column and shows that the reactive distillation is more 

efficient from the conventional process (reactor and then separation). The conversion of acetic acid and concentration 

of methyl acetate increase by (30.43% and 75.14%) respectively at the best condition (reflux ratio 2, feed mole ratio 2 

and batch time 90 minute).  

The influence of various parameters, such as batch time, reflux ratio, and feed mole ratio (methanol to acetic acid) on 

the performance of the batch reactive distillation column was studied, through the effect of the concentration of product 

and conversion of reactant.   

The results obtained for the non-ideal packed bed reactive batch distillation column show that the conversion of acetic 

acid is 90% at the best condition reflux ratio 2, feed mole ratio 2, and batch time 90 minute    

 
 

 

 

Introduction 

In recent years, increasing attention has been directed 

towards reactive distillation process as alternative to 

conventional processes (reactor and then separation). 

This has led to the development of a variety of techniques 

for reactive multistage column; however the problem of 

design and synthesis of batch reactive distillation 

processes have not yet been addressed [1]. 

Most of the distillation synthesis studies to date have 

been concerned with multi component non-ideal 

mixtures. The main advantages of this process relative to 

the conventional alternatives are the possibility of 
carrying equilibrium–limited chemical reaction to 

completion, and the simultaneous separation of the 

reaction products in only one unit .This reduces or 

eliminates reactor and recycle costs. This advantages of 

reactive distillation, and flexibility of a batch process can 

be combined in batch reactive distillation device, and the 

effect of operating parameter on yield and selectivity is 

studied [2].    

The aim of the present work is to study the efficiency and 

the characteristics of the batch reactive distillation 

process and distinguished between it and the 

conventional reactor – distillation process. The present 

work provides a process for the production high purity 

methyl acetate from methanol and acetic acid, to study 
the effect of major variables (such as batch time, reflux 

ratio, and feed mole ratio) on the conversion of acetic 

acid and the concentration of methyl acetate in the 

product.  

Experimental Work 

A schematic sketch of the apparatus is illustrated in 

figure (1). It is comprised of all items, flask with two 

necks, one for the thermometer to measure the 

temperature at the still (vapor temperature) and the other 

connected to 3cm diameter and 57cm length distillation 

University of Baghdad 

College of Engineering 
Iraqi Journal of Chemical 

and Petroleum Engineering 

 



Study of the Performance of Batch Reactive Distillation Column 

 

 
IJCPE Vol.9 No. 4 (2008) 

30 

 

column. Packed with packing to a height of 30cm. The 

distillation column connected at the top with a 

thermometer to measure the top distillation temperature. 

The raising vapor from the distillation column was 

condensate by a condenser.  

The condense accumulates in the receiver which has two 

necks one for product through valve (1) and the other 

return back to the distillation column as reflux with fixed 

ratio (R) through valve (2). 

Dosing pump was used to control the quantity of the 

reflux to the distillation column. Heat was supplied to the 
still by electrical heater and was controlled on the 

temperature of the component in the still to desired value 

by using a variac. 

 

Fig. 1: Sketch of the experimental equipment  

 

Selection of Liquid- Liquid System 

The reaction of methyl acetate with acetic acid in the 

presence of sulfuric acid as homogenous catalyst to 

produced water and methyl acetate is: 

 
                         H2SO4 

CH3COOH+CH3OH                         CH3COOCH3 + H2O  

 
Specification of Variables 

 

The variables considered for the present work are: 

a- Reflux ratio (0, 1, 2, and 3). 
b- Feed mole ratio (1, 1.5, 2, and 2.5) of 

methanol to acetic acid. 

c- Batch time (40, 60, 90, and 120 minute) 
 

These variables are studied and the results are compared 

with previous work. 

 

Results and Discussion 

Variable Effect on Product Concentration 

-Effect of Batch Time 

Figure (2) shows the relation between concentration of 

methyl acetate against time at variable feed mole ratio 

and constant reflux ratio (2). Form this figure it clear that 

the concentration of methyl acetate increase sharply up to 

(20) minute then it begin to increase slightly to value of 

(60) minute after that it remain constant, for a period of 

time  depend on feed mole ratio and then decrease. At a 

low mole ratio along time is required for the 

concentration to be reduced because of the low  mole 

ratio consist of high percent of acetic acid, methanol 

return to the still through the reflux and react with 

residual acetic acid to produce methyl acetate. For a high 

mole ratio, a short time is required for the concentration 

to be reduced. That mean a low percent of acetic acid 

which can be consumed rapidly and then concentration of 

methanol in the distillate will be increase to reduce the 

concentration of methyl acetate.  

 

Fig. 2: Concentration of methyl acetate vs. time 

at reflux ratio=2 and different 

feed mole ratio 

 

-Effect of Reflux Ratio 

Figure (3) shows the relation of methyl acetate 

concentration against reflux ratio for a batch time 90 

minute and different feed mole ratio. This figure shows 

that the maximum concentration is at  reflux ratio equal 

to  (2)  for all feed mole ratio except the value of feed 

mole ratio (2.5) where in this feed mole ratio the 

concentration increase directly mainly in straight line as it 

be explained previously. From this figure it can be 

deduced that the best reflux ratio is (2).  

 

V1 V2 

TIME ( min)

M
E

A
C

  
c
o
n
c
e
n
tr

a
ti
o
n
  
(v

o
l.
 %

)

0

10

20

30

40

50

60

70

80

90

100

0 10 20 30 40 50 60 70 80 90 100 110 120 130

FMR=1

FMR=1.5

FMR=2

FMR=2.5



Dr. Cecilia K. Haweel and Taha M.A. Hamza 

31 
IJCPE Vol.9 No. 4 (2008) 

 

 

 

Fig. 3: concentration of methyl acetate vs. reflux ratio at 
90 minute and different feed mole ratio. 

 

-Effect of Feed Mole Ratio 

Figure (4) show the concentration of methyl acetate 

against feed mole ratio at variable reflux ratio and 

constant time. The figures represented that if the 

mole ratio increase the concentration will decrease, 

because of if the percent of methanol increase in 

feed, it will vaporize more than methyl acetate, 

causes decrease of methyl acetate concentration.    

Fig.4: concentration of methyl acetate V.s. feed mole 

ratio at 90 minute and different reflux ratio 

 

Variable Effect on Conversion of Acetic Acid  

- Effect of batch Time 
Figure (5) shows the conversion of acetic acid against 

batch time for variable feed mole ratio and constant 

reflux ratio 2. this figure shows that  the conversion of 

acetic acid increase slightly up to (60) minute then 

increase sharply up to the (120) minute as an over all the 

conversion of acetic acid increase with time due to the 

increase  of consumption of acetic acid with time which 

cause a high conversion value. 

 

Fig.5: conversion of acetic acid V.s. time at R=2 and 

different feed mole ratio. 

- Effect of reflux ratio 
Figure (6) shows the conversion against reflux ratio at 

constant batch time 90 minute and different feed mole 

ratio. From this figure the conversion of acetic acid 

increase with reflux ratio up to reflux rate (2) and then 

decrease for all value of feed mole ratio, except for feed 

mole ratio (2.5) which shows a maximum value of 
conversion at reflux ratio equal to(1) this is in agreement 

with (Kai 
6
, Agreda

 7
, and Doherty 

8
). This is because of 

at increase reflux ratio, the distillate is rich in methyl 

acetate and when it return to the still, the reversible 

reaction is occurred and more acetic acid is produced 

which causes a decrease in the conversion of acetic acid.  

Fig. 6: conversion of acetic acid V.s. reflux at 90 minute 

and different feed mole ratio 

REFLUX

M
E

A
C

  
c
o
n
c
e
n
tr

a
ti
o
n
  
(v

o
l.
 %

)

58

64

70

76

82

88

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

FMR=1

FMR=1.5

FMR=2

FMR=2.5

FEED MOLE RATIO

M
E

A
C

 c
o

n
ce

n
tr

a
ti

o
n

 (
vo

l.
 %

)

35

45

55

65

75

85

95

0.8 1.2 1.6 2.0 2.4 2.8

R=0

R=1

R=2

R=3

R=    

TIM E(min)

C
O

N
V

E
R

S
IO

N

60

65

70

75

80

85

90

95

100

30 50 70 90 110 130

FM R=1

FM R=1.5

FM R=2

FM R=2.5

REFLUX

C
O

N
V

E
R

S
IO

N

60

64

68

72

76

80

84

88

92

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

FMR=1

FMR=1.5

FMR=2

FMR=2.5



Study of the Performance of Batch Reactive Distillation Column 

 

 
IJCPE Vol.9 No. 4 (2008) 

32 

 

- Effect of feed mole ratio 

Figure (7) shows the conversion against feed mole ratio 

at batch time 90 minute and different reflux ratio. In the 

case of (0, 1) reflux ratio the conversion will increase 

when the mole ratio increase, because of the continues of 

with draw the desired product, the reaction is always to 

foreword and cause consumption of the limited 

component (acetic acid), and increase it is conversion. If 

reflux ratio is increase to (2, 3) the conversion will 

increase with mole ratio up to (2) after that the 

conversion will decrease with increase of the feed mole 

ratio. That is because of low percent of methanol in feed, 

not all acid will react, so the conversion is low. As the 

percent of methanol in the feed increase to a limited 

amount the conversion increase, then it will decrease 

because of reversible reaction will occur. 

Fig.7: conversion of acetic acid VS. feed mole ratio at 90 

minute and different reflux ratio. 

 

CONCLUSIONS 

 
From the present work the following conclusions are 

made: 

 

1- The concentration of methyl acetate increase 
with increasing the reflux ratio to maximum 

value of reflux ratio equal (2) then decrease. 

 

2- The concentration of methyl acetate increase 
with decrease feed mole ratio. 

 

3- The concentration of methyl acetate increase 
with time to a limit value depending on the feed 

mole ratio. 

 

4- The higher concentration of methyl acetate in 
thee product was obtained at reflux ratio 2, feed 

mole ratio 1, and for batch time 60 minute. 

 

5- The conversion of acetic acid increase with feed 
mole ratio and reflux ratio to maximum value 

equal 2 then decrease. 

 

6- The conversion of acetic acid increase with time. 
 

7- The reactive distillation is more efficient than 
the conventional process at the best condition 

mentioned above for reactive distillation the 

conversion of acetic acid increase by 30.43% 

than that of conventional process, and the 

concentration of methyl acetate in the product 

increase by 75.14% than the conventional 

process. 

 

 
REFERENCE 

 
 

1-     Barabosa D. and Doherty, M. “The Simple 
Distillation of Homogeneous Reactive 

Mixture”, chem. Eng. Sci., Vol. 43, P. 541-

550, 1988.  

  

2-     Isao, S., Yagi, H., Komatsu, H. and Hirata, 
M. “calculation of Multi component 

Distillation Accompanied by Chemical 

reaction” Jour. Chem. Eng. Jap. Vol.4, 

P26-33, 1971. 

 

3-    Taylor R. and Krishna, R. “Modeling 
Reactive Distillation” Chem. Eng. Sci., 

Vol.55, P.5183-5229, 2000. 

 
4-    Towler, G.P. and Frey, S.J. (2000) Reactive 

Distillation, Chapter 2 in Reactive 

Separation. 

 

5-        kai Sundmacher “ Modren Methods in 

Heterogeneous Catalysis Research” Fritz Haber 

institute, Berlin, 14 November 2003. 

 

7-       Victor H. Agreda, Lee R.U.S. Patent 

4435595 “Reactive Distillation Process for 

the Production of Methyl Acetate” 1984. 

 

8- Doherty M.F., and M.F. Malone “Recent 
Advances in Reactive Distillation” AICHE 

Annual Meting, Dallas, paper203c, 

November 3, 1999.  

feed mole ratio

c
o

n
v
e

rs
io

n

55

60

65

70

75

80

85

90

95

0.8 1.2 1.6 2.0 2.4 2.8

R=0

R=3

R=2

R=1

R=  



Dr. Cecilia K. Haweel and Taha M.A. Hamza 

33 
IJCPE Vol.9 No. 4 (2008) 

 

 

 دراسة اداءعمود التقطير التفاعلي

 

   
ٔانُظاو انًسحخذو ْٕ جفاعم انًٍثإَل يع حايض انخهٍك , جى دساسة انحقطٍش انحفاعهً رٔ انذفعات فً عًٕد رٔ حشٕات

ٔجى اخحٍاس ْزا انحفاعم الٌ انحفاعم عكسً ٔدسخات انغهٍاٌ , الَحاج خالت انًثٍم ٔانًاء بٕخٕد حايض انكبشٌحٍك كعايم يساعذ
. نهًٕاد انًحفاعهّ ٔانُاجدّ يحباعذِ

 
انحفاعم نٕحذِ )جى انعًم بٓزا انُظاو بٕخٕد أ عذو ٔخٕد عًٕد انحقطٍش ٔجبٍٍ اٌ انحقطٍش انحفاعهً اكفأ يٍ انطشٌقّ انعادٌّ 

عهى  ( 75.14% ٔ 30.43)%حٍث اٌ َسبّ انححٕل نحايض انخهٍك ٔانحشكٍض نخالت انًثٍم جضٌذ بًقذاس . (ٔانحقطٍش نٕحذِ
.  ( دقٍق90ّ ٔصيٍ 2 َٔسبّ انًٕاد انًحفاعهّ 2عُذ ساخع )انحٕانً عُذ افضم انظشٔف

 
جى دساسّ جاثٍش انعذٌذ يٍ انًحغٍشات يُٓا َسبّ انشاخع َٔسب انًٕاد انًحفاعهّ ٔجاثٍش انضيٍ عهى اداء بشج انحقطٍش رٔ 

انذفعات انًصاحب نهحفاعم انكًٍٍأي خالل خشٌاٌ انسائم ٔانبخاس داخم انبشج ٔجاثٍشْا عهى جشكٍض انًٕاد انُاجدّ ٔجحٕل انًٕاد 
. انًحفاعهّ

 
انُحائح انحً جى انحصٕل عهٍٓا نهخالئط انغٍش يثانٍّ ندٓاص انحقطٍش رٔ انذفعات انًصاحب نهحفاعم انكًٍٍأي كاَث َسبّ انححٕل 

.   دقٍق90ّ ٔصيٍ 2 َٔسبّ انًٕاد انًحفاعهّ 2عُذيا جكٌٕ َسبّ انشاخع %90نحايض انخهٍك جسأي