In this process, acrylic acid (AA) is produced through the oxidation of propylene at 300°C and  2.57 atm with water as the by-product. In a year, this chemical plant operates 24 hours a day  for 330 working days, with a total production of 250,000 metric tonnes of AA. The main product  is AA, while the side products are acetic acid (ACA), water (H2O), and carbon dioxide (CO2). The selectivity of AA over ACA is 16 and the conversion of propylene to the side reaction 2 is  half of the side reaction 1. Details of the reaction are as follows: C3H6 (g) + 1.5O2 (g) → C3H4O2 (v) + H2O (v) (Main reaction) C3H6 (g) + 2.5O2 (g) → C2H4O2 (v) + CO2 (g) + H2O (v) (Side reaction 1) C3H6 (g) + 4.5O2 (g) → 3CO2 (g) + 3H2O (v) (Side reaction 2) Pure oxygen is added to a recycle stream containing a mixture of carbon dioxide and oxygen before being fed to an oxidation reactor. Before feeding it to the reactor, the mixed stream is  heated to 300°C and compressed to 2.57 atm. Pure propylene is fed to the reactor through  another stream. The preheated gases react exothermically in a jacketed reactor that uses cooling water as a cooling medium to maintain the reaction temperature at 300°C. Propylene  is the limiting reactant, and oxygen is fed in excess of 20% into the oxidation reactor. A hot gaseous mixture is produced from the reactor contain acrylic acid as the major product.  Acetic acid, carbon dioxide, and water are the side products with unreacted oxygen. The hot  gaseous mixture is cooled down in a condenser from 300 to 50°C and fed to a flash column.The column separates the mixture and sends gaseous material such as carbon dioxide and  unreacted oxygen through the top product stream to a gas separator. The bottom stream from  the flash column contains acrylic acid, acetic acid, and water. The gas separator is used to  separate the carbon dioxide gas from the oxygen, and the oxygen is then recycled and mixed  with the oxygen feed stream. The efficiency of the gas separator is around 95% and the recycle  stream have composition 99 mol% of Oxygen. Before it is recycled, the stream’s pressure is  reduced to 1 atm through a valve to match the pressure of the oxygen feed stream. The pressure and temperature of the bottom stream for the flash column are increased to 3  atm and 148°C using a pump, and a heater, respectively. Then, it is fed to a distillation column  (DC1) to purify the acrylic acid. The top outlet stream contains water, acetic acid and 5% of  the total molar flow of acrylic acid fed to the DC1. The bottom consists of acetic acid and  acrylic acid only, where the purity of the acrylic acid obtained is 99.0 mol%. The top outlet is  sent to the liquid-liquid extractor (LLE) to separate the water from the acetic acid. 31,680  kmol/hr of ethylene glycol (EG) is used as a solvent to extract the water and flows out as the  top stream of the extractor column, leaving acetic acid, solvent, and a small amount of water  in the bottom stream. The extraction efficiency is 90% and 1% of solvent fed to the extractor  loss to the top stream. The bottom stream will then undergo a distillation process (DC2) to  separate the solvent and the acetic acid. The distillate stream contains 95 mol% of acetic acid  fed to the distillation column and water, while the bottom stream contains only a small amount  of acetic acid and solvent. Draw Process Flow Diagram Only

Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
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In this process, acrylic acid (AA) is produced through the oxidation of propylene at 300°C and 
2.57 atm with water as the by-product. In a year, this chemical plant operates 24 hours a day 
for 330 working days, with a total production of 250,000 metric tonnes of AA. The main product 
is AA, while the side products are acetic acid (ACA), water (H2O), and carbon dioxide (CO2).
The selectivity of AA over ACA is 16 and the conversion of propylene to the side reaction 2 is 
half of the side reaction 1. Details of the reaction are as follows:
C3H6 (g) + 1.5O2 (g) → C3H4O2 (v) + H2O (v) (Main reaction)
C3H6 (g) + 2.5O2 (g) → C2H4O2 (v) + CO2 (g) + H2O (v) (Side reaction 1)
C3H6 (g) + 4.5O2 (g) → 3CO2 (g) + 3H2O (v) (Side reaction 2)
Pure oxygen is added to a recycle stream containing a mixture of carbon dioxide and oxygen
before being fed to an oxidation reactor. Before feeding it to the reactor, the mixed stream is 
heated to 300°C and compressed to 2.57 atm. Pure propylene is fed to the reactor through 
another stream. The preheated gases react exothermically in a jacketed reactor that uses
cooling water as a cooling medium to maintain the reaction temperature at 300°C. Propylene 
is the limiting reactant, and oxygen is fed in excess of 20% into the oxidation reactor.
A hot gaseous mixture is produced from the reactor contain acrylic acid as the major product. 
Acetic acid, carbon dioxide, and water are the side products with unreacted oxygen. The hot 
gaseous mixture is cooled down in a condenser from 300 to 50°C and fed to a flash column.The column separates the mixture and sends gaseous material such as carbon dioxide and 
unreacted oxygen through the top product stream to a gas separator. The bottom stream from 
the flash column contains acrylic acid, acetic acid, and water. The gas separator is used to 
separate the carbon dioxide gas from the oxygen, and the oxygen is then recycled and mixed 
with the oxygen feed stream. The efficiency of the gas separator is around 95% and the recycle 
stream have composition 99 mol% of Oxygen. Before it is recycled, the stream’s pressure is 
reduced to 1 atm through a valve to match the pressure of the oxygen feed stream.
The pressure and temperature of the bottom stream for the flash column are increased to 3 
atm and 148°C using a pump, and a heater, respectively. Then, it is fed to a distillation column 
(DC1) to purify the acrylic acid. The top outlet stream contains water, acetic acid and 5% of 
the total molar flow of acrylic acid fed to the DC1. The bottom consists of acetic acid and 
acrylic acid only, where the purity of the acrylic acid obtained is 99.0 mol%. The top outlet is 
sent to the liquid-liquid extractor (LLE) to separate the water from the acetic acid. 31,680 
kmol/hr of ethylene glycol (EG) is used as a solvent to extract the water and flows out as the 
top stream of the extractor column, leaving acetic acid, solvent, and a small amount of water 
in the bottom stream. The extraction efficiency is 90% and 1% of solvent fed to the extractor 
loss to the top stream. The bottom stream will then undergo a distillation process (DC2) to 
separate the solvent and the acetic acid. The distillate stream contains 95 mol% of acetic acid 
fed to the distillation column and water, while the bottom stream contains only a small amount 
of acetic acid and solvent.

Draw Process Flow Diagram Only

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