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Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering PDF Download

Isopropanol 

Ever since its first commercial introduction in 1920 as one of the first petrochemicals, isopropyl alcohol has found wide use as a solvent and raw material for other chemical products like acetone, isopropyl acetate, glycerol, isopropyl and disopropyl amines, corrosion inhibitor di -soprpopyl ammonium nitrate, floatation agent isopropyl xanthate, isopropyl myristates etc. 

Process Technology: 

Two major processes for isopropanol manufacture are 

  • Esterification of propylene by sulphuric acid and hydrolysis 

         Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

  • Direct catalytic hydration of propylene ( vapor phase, liquid phase and mixed phase) 

           Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Although originally isopropyl alcohol was made by esterification of propylene and hydrolysis, problems of corrosion and a high heat requirement has led to the use of direct hydration process. 

Direct Hydration of Propylene: In liquid phase hydration of propylene( Tokuyama Process) silico tungstate is used. The catalytic hydration process takes at 250-27oC at 200 atm pressure. Propylene conversion has been reported around 60-70%. 

Butanols (N-BUTANOL AND ISO-BUTANOL) 

Various routes for making butanol are

  • Acetaldehyde route
  • Hydroformylation of propylene
  • Oxidation of Butane 

Condensation of Acetaldehyde: The process involves Aldolization, dehydration, hydrogenation  

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Hydroformylation of propylene

Butanol is manufactured from hydrogenation of n-butyraldehyde and iso-butyraldehyde mixture obtained by hydroformylation reaction of propylene and synthesis gas. Hydrogenation takes place at temperature 150-200 0C and 5-10 MPa pressure using copper or nickel catalyst. The butanols from the hydrogenation reactor go to a series of distillation columns for separation of light effluents and n-butanol and iso-butanol. About 88% of n-butanol and 12% iso-butanol are obtained.

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical EngineeringPropylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Butadiene [Ch2=Ch-Ch=Ch2]

Butadiene is one of the major petrochemicals with a wide range of uses as feedstock for production of a variety of synthetic rubbers and polymer resins, the bulk of which are related to styrene butadiene rubber (SBR), nitrile rubber, chloroprene rubber, polybutadiene rubber, and acrylonitrile butadiene styrene (ABS) resin. Another major use of butadiene is in the manufacture of adiponitrile which is a raw material for the production of Nylon 66. Global demand growth for butadiene is set to accelerate. Butadiene based synthetic rubbers are mainly used in the automotive industry. It is also widely used for manufacturing of engineering resins.

There are four major routes for production of butadiene:

  • Steam cracking of naphtha
  • Catalytic dehydrogenation of butenes
  • Catalytic dehydrogenation of butanes
  • Dehydrogenation-dehydration of ethanol (molasses route)

2-Ethyl Hexanol

Major use of 2-ethyl hexanol is in the manufacture of di -2-ethylhexylphthalate which is used as plasticiser for vinyl resins. Other application are in synthetic lubricants, antioxidants and antifoams. 2-Ethyl hexanol is made either by the oxo-synthesis or from acetaldehyde route by condensation and hydrogenation. . 2-Ethyl hexanol is also used in the manufacture of ethyl hexa acrylate. Ethyl hexaacylateprodices soft and tacky film with excellent low temperature flexibilities. Ethylhexanol also find application cable coating compositions, nitrocellulose lacquers, as softener in nitrile rubber compounds, in plastic compounds for water proof agents . 

Propylene Route: In first step 4n-butyraldehyde is produced along with 1-isobutyraldehyde. 4n-butyraldehyde is further hydrogenated to 2-ethylhexanol

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Propylene Carbonate [C3H6CO3

Propylene carbonate is prepared by reaction of propylene oxide and carbon dioxide in presence of ion-exchange resins 

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

Uses: Propylene carbonate is used as special solvent. It is used in solvent extraction, plasticisers, organic synthesis, natural gas purification, and fiber spinning solvent.

Acrylic Acid 

Acrylic acid is a versatile chemical which find application in the manufacture of glacial acrylic acid and acrylic esters (Acacrylates and metha acrylates), polyacrylic acid which is used in manufacture of super absorbent polymers, flocculants, detergents, paper chemicals and resin. SAP is used for water retention in infants diaper, adult in continence products and feminehygine products . Various acrylic esters are methyl acylate, ethyl acrylate, butyl acylate, 2-ethyl hexyl acrylate.

Process Technology:  

Various routes for making acrylic acid are

  • Acetylene route
  • Ethylene Oxide Route
  • Ethylene Route
  • Chlorination of Propianic acid
  • Propylene route
  • Formaldehyde and Acetic Acid Route

Amongst the above process propylene oxidation through acrolein is commonly used

Propylene Route: In this route, acrolein is made in first stage by oxidation of propylene in presence of mixed catalysts (prepared from oxides of bismuth, potassium, cobalt, and iron, nickel, tin, tellurium, tungsten, etc). In the second stage, acrolein is oxidised to acrylic acid in the presence of mixed oxides of molybdenum and vanadium at 250-280 oC in the presence of steam.

Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering

The document Propylene, Propylene Oxide And Isopropanol (Part - 2) | Chemical Technology - Chemical Engineering is a part of the Chemical Engineering Course Chemical Technology.
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FAQs on Propylene, Propylene Oxide And Isopropanol (Part - 2) - Chemical Technology - Chemical Engineering

1. What is the production process of propylene oxide?
Ans. Propylene oxide can be produced through the chlorohydrin process or the styrene monomer process. In the chlorohydrin process, propylene reacts with chlorine and water to form propylene chlorohydrin, which is then treated with sodium hydroxide to produce propylene oxide. In the styrene monomer process, propylene reacts with benzene and oxygen in the presence of a catalyst to produce styrene monoxide, which is then converted to propylene oxide.
2. What are the main applications of propylene oxide?
Ans. Propylene oxide has several important applications. It is primarily used as a raw material in the production of polyurethane foams, which are widely used in furniture, bedding, and insulation. It is also used in the production of propylene glycol, a versatile chemical that is used in a variety of applications such as automotive antifreeze, cosmetics, and food products. Additionally, propylene oxide is used in the production of glycol ethers, which are solvents used in paints, coatings, and cleaning products.
3. How is propylene oxide converted to isopropanol?
Ans. Propylene oxide can be converted to isopropanol through a process called hydrolysis. In this process, propylene oxide is reacted with water in the presence of an acid or base catalyst. The reaction produces isopropanol and forms a byproduct called propylene glycol. The byproduct can be further processed to obtain propylene glycol or used in various applications.
4. What are the safety considerations for handling propylene oxide?
Ans. Propylene oxide is a flammable liquid and can form explosive mixtures with air. It is also a skin and eye irritant and can cause respiratory irritation if inhaled. Therefore, proper safety precautions should be followed when handling propylene oxide, including wearing appropriate personal protective equipment such as gloves, goggles, and respiratory protection. Adequate ventilation should be provided in areas where propylene oxide is used or stored, and it should be stored in a cool, well-ventilated area away from sources of ignition.
5. Is propylene oxide harmful to the environment?
Ans. Propylene oxide can have negative environmental impacts if released into the environment. It is classified as a hazardous air pollutant and can contribute to the formation of ground-level ozone, which is a major component of smog. In water, propylene oxide can contaminate water sources and pose a risk to aquatic life. Proper handling, storage, and disposal of propylene oxide are necessary to prevent environmental contamination.
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