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Mono- , Di- Tri- Ethylene Glycols (Meg, Deg, Teg)

A major petrochemicals and find application in manufacture of polyester and as antifreeze accounts for 70% of Ethylene oxide production. Ethylene oxide preheated to 195oC. EO:H2O ratio 10:1 to maximize MEG production By Products DEG, TEG. Figure M- VII 5.3 gives detail manufacturing of MEG, DEG and TEG from Ethylene Oxide

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Figure M- VII 5.3: MEG, DEG and TEG from Ethylene Oxide

Vinyl Chloride
 

Vinyl chloride is one of the important petrochemical feedstocks and find use in manufacture of poly vinyl chloride the second largest tonnage commercial polymer after polyethylene. About 95percent of the present vinyl chloride production worldwide is used in polymer production or copolymer application. Another important use of vinyl chloride is in the production of vinylidiene chloride. According to SRI consulting global production and consumption of Ethylene dichloride (EDC) in 2009 (which accounts for 95 percent consumption in vinyl chloride manufacture), was about 33.7 million tones with global capacity of about 73 percent in 2009.

Process Technology 

The original process of manufacture of vinyl chloride was by reaction of acetylene derived from calcium carbide with hydrochloric acid in gaseous phase in presence of mercuric chloride catalyst at temperature around 100- 180 oC. However with the availability of ethylene from cracker plant now vinyl chloride is made from ethylene obtain from cracker plant

Direct Chlorination

  • The process of vinyl chloride manufacture takes place in two stages.
  • First stage: Ethylene is reacted with chlorine in either liquid or vapor phase in presence of ferric chloride. However, the liquid phase process is more common and the reaction takes place at around 50- 90 oC and 3- 5 atm pressure.
  • Second stage: Vinyl chloride is produced by pyrolysis of vaporised ethylene dichloride in a set of tubular furnaces at temperature of about 400- 500 oC.
  • Direct chlorination: Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Process Technology

The process of vinyl chloride manufacture takes place in two stages.

First Stage: Ethylene is reacted with chlorine in either liquid or vapor phase in presence of ferric chloride. However, the liquid phase process is more common and the reaction takes place at around 50- 90 oC and 3- 5 atm pressure.

Second Stage: Vinyl chloride is produced by pyrolysis of vaporised ethylene dichloride in a set of tubular furnaces at temperature of about 400- 500oC.
Ethylene chloride by direct Chlorination of Ethylene:

  • The original process of manufacture of vinyl chloride by ethylene chlorination and cracking of ethylene dichloride had been replaced by oxychlorination process in which no hydrochloric acid is formed as byproduct. Process diagram of vinyl chloride from oxychlorination process is shown in Figure M- VII 5.4.
  • The process involves production of ethylene dichloride by exothermic reaction of ethylene, hydrochloric acid and oxygen
  • Liquid phase: Fixed or fluidized bed reactor is used at 170- 180oC and 15- 20 atm pressure in presence of copper chloride.
  • Vapor phase reaction: The temperature and pressure are 200- 220oC and 20- 50 atm pressure.

Reactions

Vinyl Chloride by Chlorination

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Propagation:

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Termination:

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

The first stage is typical electrophilic addition of a halogen to an alkene. The second stage is a free radical chain reaction.

Oxychlorination

The original process of manufacture of vinyl chloride by ethylene chlorination and cracking of ethylene dichloride had been replaced by oxychlorination process in which no hydrochloric acid is formed as byproduct. The process involves production of ethylene dichloride by exothermic reaction of ethylene, hydrochloric acid and oxygen. Liquid phase: at about 170- 180 oC in at 15-20 atm pressure in presence of copper chloride in either fixed or fluidised bed reactor.Vapor phase reaction: the temperature and pressure are 200- 220 oC and 20- 50 atm pressure

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Figure M-VII 5.4: Vinyl Chloride from Oxychlorination Process

Vinyl Acetate

Vinyl acetate is one of the important derivatives of ethylene which is used as intermediate for manufacture of polyvinyl alcohol, polyvinyl acetate, polyvinyl butyral, etc.
Global end use pattern of vinyl acetate is:- Adhesives (23%), paints and coating (29%), textiles (21%), plastics (17%), paper and board (10%). Consumption pattern of vinyl acetate in India is polyvinyl acetate emulsions & resins (50%), polyvinyl alcohol (25%), ethylene vinyl acetate (10%), others (15%).

End use pattern of vinyl acetate in India is :- Adhesives (35- 40%), textiles (30- 35%), paints and coating (15-20%), others (10-15%)

Process Technology: 

  • The ethylene route has replaced the traditional process of manufacture of vinyl acetate. The production of vinyl acetate through acetylene route, which was developed by Wacker in 1930, involves reaction of acetylene and acetic acid in liquid phase at 60- 80 oC and 1- 2 atm pressure in presence of mercury salt catalyst.

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Vinyl acetate from Ethylene route 

  • Vinyl acetate is made by reaction of ethylene with acetic acid by liquid phase process or by vapor phase process in presence of palladium and cupric chloride catalyst. In the vapor phase process, following reactions take place:

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering  

Use of Vinyl Acetate

 

Polyvinyl Acetate

Surface coating adhesives, Textile resins

 

Polyvinyl Alcohol

Textile size, Grease proofing paper, Vinyl

emulsifier, Thickener, Viscosity regulators, Adhesives,

 

Acrylo- nitrile Copolymer

Acrylic Fibers

Vinyl Acetate

Polyvinyl Formate

Water resistant insulation enamel

Ethylene Vinyl Acetate Copolymers

Textile and Paper Coating

 

 

Vinyl chloride comonomers

VC-VAC, LP Records, VC-VAC Coating

 

Polyvinyl Butryaldehyde

Safety Glass

 
Ethanol
Ethanol apart from its major use as a beverage is one of the most versatile chemicals and is one of the basic building blocks of the organic chemical industry. Ethanol is generally produces by fermentation of molasses, due to the development of petrochemical industry and availability of ethylene, now ethylene provides another major route of formation of ethanol.
 
However, still molasses were used to produce ethanol in India. In India some of the important chemical are still prepared through ethanol which were earlier prepared through petrochemical route. Two such important complexes are Jubilant Organosys Ltd., Gajraula (Uttar Pradesh) and Indian Glycol Ltd., Kashipur (Uttar Pradesh), where large number of ethanol derivatives are manufactured through ethanol route.
 
Various routes for manufacture of ethanol
  • Fermentation of molasses
  • Catalytic hydration of ethylene
  • Ethylene esterification and hydrolysis

Fermentation of Molasses:

Ethyl alcohol is prepared from molasses by fermentation process utilising yeast enzymes.Separation of 8-10% alcohol is achieved in a series of distillation columns, as alcohol and water at 95% concentration form azeotropic mixture.

Ethanol by Esterification and Hydrolysis 

  • Ethylene and sulphuric acid are reacted at 80 oC and 1.5 MPa to form a mixture of ethyl sulphates, which are then hydrolysed to ethyl alcohol.
  • Ethylene and sulphuric acid are reacted in absorber from which the mixture of ethylene sulphates thus formed is fed to hydrolyser from which the crude alcohol and sulphuric acid are fed to stripping section and caustic scrubbing section and finally to a series of two distillation columns for separation of ether and alcohol.

         Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Ethanol by Vapor Phase Hydration of Ethylene

  • An ethylene rich gas is mixed with water and heated to about 300 oC and passed on to fixed bed catalytic reactor where catalytic hydration of ethylene takes place

         Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

  • The catalyst used is phosphoric acid deposited on silica gel. The reactor effluents are sent to separator for separation of vapor and liquid. The gases from the separator are cooled and scrubbed with water to recover traces of alcohol. The alcohol water mixture is sent to a series of distillation columns where ether is separated in the light end column and finally 95% by volume ethanol water azeotrope is separated.

Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering

Figure M- VII 5.5: Ethanol from Catalytic Recycle Hydration of Ethylene

Acetaldehyde

Table M-VII 5.8: Product Profile of Acetaldehyde

 

Product

Uses

Pyridine, Picoline

Solvent, Drugs, Dyes, Agricultural chemicals

Chlor-aldehydes

Insecticides, Fungicides, Disinfectants

Acetaldol

1,3-Butylene Glycol (Polyesters),Urethane coating,

Humcetant, Printing ink,Crotonaldehyde,n-butyl alcohol, n-butyric acid

anhydride, 2-ethyl hexanol ,Rubber accelerator, Sorbic acid

Paraldehyde

Rubber accelerator, Antioxidant dye,stuff

Per-acetic acid

Epoxidation reaction, Reagent in caprolactam,

Synthetic glycerols

Penta-erythritol

Alkyl resin, Stabilizer, Plasticizers, Chlorinated

polyether resin, Intumescents

Acetic, anhydride

Acetyl salicylic acid, Cellulose acetate, Esters

Acetic acid

Cellulose acetate, Vinyl acetate Chloro-acetic acid

Ammonium acetate

Lactic acid

Food and, beverages, lactates, adhesives,

Leather processing

 
The document Ethylene Derivatives (Part - 2) | Chemical Technology - Chemical Engineering is a part of the Chemical Engineering Course Chemical Technology.
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FAQs on Ethylene Derivatives (Part - 2) - Chemical Technology - Chemical Engineering

1. What are the major uses of ethylene derivatives in chemical engineering?
Ans. Ethylene derivatives are widely used in chemical engineering for various purposes. Some of the major applications include the production of plastics, solvents, detergents, synthetic fibers, and pharmaceuticals.
2. How is ethylene converted into ethylene oxide in the chemical industry?
Ans. Ethylene oxide is produced by the direct oxidation of ethylene with oxygen or air in the presence of a catalyst, such as silver. This process is commonly known as the ethylene oxide process and is an important step in the production of various ethylene derivatives.
3. What are the challenges in the production of ethylene derivatives?
Ans. The production of ethylene derivatives can pose several challenges in chemical engineering. Some of the common challenges include the need for specialized catalysts, control of reaction conditions, safety considerations due to the flammability of ethylene, and the management of by-products and waste streams.
4. How is the purity of ethylene derivatives ensured in industrial production?
Ans. The purity of ethylene derivatives is crucial in industrial production to meet the required quality standards. Various purification techniques, such as distillation, filtration, and solvent extraction, are employed to remove impurities and ensure the desired purity of the ethylene derivatives.
5. What are the environmental impacts of the production of ethylene derivatives?
Ans. The production of ethylene derivatives can have environmental impacts, primarily due to the emission of greenhouse gases and the generation of waste streams. However, advancements in technology and process optimization have helped reduce these impacts by improving energy efficiency, implementing waste treatment systems, and exploring eco-friendly alternatives in the production of ethylene derivatives.
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