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Introduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) | Chemical Technology - Chemical Engineering PDF Download

Elastomer 

Rubber can be broadly classified as natural rubber and synthetic rubber. Natural rubber is a product of the tree Heveabrasiliensis while synthetic rubber is elastomer derived from petrochemical feedstock product. Table M-VIII 1.4 shows the general and special purpose of rubber. 

Table M-VIII 1.4: General Purpose and Special Purpose Rubber

 

General Purpose Rubber

Special Purpose

Styrene butadiene rubber (SBR)

Polychloroprene(CR)

Styrene butadiene Emulsion/Solution

Styrene isoprene rubber(SIR)

Polybutadiene (BR)

Acrylonitrile Butadiene(NBR)

Polyisoprene (PS)

Silicone rubbers

Ethylene propylene (EP) and

Ethylene propylene diene (EPDM) Butyl rubber (BR)

Ethylene vinyl acetate (EVA)

Acrylic rubber

Polyester urethanes

Polyether urethane elastomer Epichlorohydrin

Poly isobutylene

Polydialkyl siloxane (Silicon Rubber)

Vinyl Pyridine butadiene rubber (PBR)

Hypalon

Polysulphide rubber

Fluorocarbon rubber

Synthetic Fibre 

  • First manmade fiber – natural occurring polymers from cellulose and protein – Viscose rayon first manufactured in 1986 in England
  • First true synthetic in 1935 – Nylon by DuPont
  • Nylon was followed by acrylic and mod acrylic fiber based on Acrylonitrile in 1950.
  • Polyester Fiber in 1953 in India
  • Viscose rayon in India started in 1950
  • Acetate rayon in 1954 in India

World consumption of non-woven man-made fibre is mention in Table M-VIII 1.5.\

Rayon Grade Pulp : Harihar Polyfibre, Gwalior Rayon, Travancore Rayon, Baroda Rayon, Andhra Rayon, Shri Ram Rayon, Kesoram Rayon, South India Viscose Rayon

Caprolactam: Gujarat state fertilizer and chemicals vadodara, Fertilizer and chemicals travancore

DMT /PTA: Bombay Dying, BRPL, Reliance (Patal Ganga, Hazira, Vadodara), IOC Panipat

p-Xylene: BRPCL, Reliance (Patal Ganga, Hazira, Vadodara, Jamnagar), Indian oil Corporation

Projected Consumption of Fiber in India 

Table M-VIII 1.5: World Consumption of Non woven Man-made Fibers (% of total)

Man-made Fibers

1998

2000

2005

2007

Polyester

24

22.5

23.0

23

Polyamides

1.5

1.5

1.5

1.5

Acrylic fibers

1.5

2.0

3.0

3.0

Polypropylene fibers

62.0

63.0

62.7

62.7

Viscose rayon

8.0

8.0

7.0

7.0

Other synthetic fibers

3.0

3.0

2.8

2.8

Total consumption, million tonnes

2.4

3.3

2.5

4.0

Raw Materials for Manmade Fibre 

  • Synethetic fibre polymer production needs extremely pure raw materials and chemicals. The most important chemicals are monomers, catalysts, and solvents.
  • The most common monomers dealing with large volume organic chemicals are as follows:
    • Ethylene, propylene, butadiene, isoprene, styrene
    • Vinyl chloride, vinyl esters, vinyl ethers, chloroprene
    • Acrylic and methaacrylic esters, vinyl ethers, chloroprene
    • Adipic acid, hexamethylenediamine, caprolactam
    • Terephthalic acid, ethylene glycol
    • Formaldehyde
    • Aromatics, like phenol, cresol, bisphenol A
    • Maleic anhydride, etc
  • Catalysts are chemicals used to speed up or initiate the polymerization reaction. Common catalysts include Zieger catalysts (titanium chloride and aluminium alkyl compounds), chromium-containing compounds, and organic peroxides.
  • Solvents are sometimes used to dissolve or dilute the monomer or reactants. The use of solvents facilitates polymer transport through the plant, increases heat dissipation in the reactor, and promotes uniform mixing in the reactor

Details of man made fibre is shown in Figure M-VIII 1.6.

 Some terms used in synthetic fibre industry 

Denier: denier is the measure of coarseness of a yarn and is defined as the  weight in grams of a length  9000meter of a yarn or filament.

Tex and Millitex: Tex is the defined as the weight in grams of 1000 meter

 Tenacity: The tenacity or strength of rayon is expressed as grams per denier. IF a load of 250 gms will just break at a denier yarn, the tenacity is said to be 2.5 gms per denier.

Elongation at break: Elongation is a important properties of a yarn.  If a length of 100cm of a yarn can be stretched 112 cm before breaks, it is said to have elongation at break of 12%

Moisture regain: Regain is of a fibre is the percentage of moisture calculated on oven dry basis.

Staple: The choped fibre is called staple .

Filament yarn:  Reeled filaments yarn

Elasticity: The elasticity of a fibre is its ability to recover from strain. 

Introduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) | Chemical Technology - Chemical Engineering

Figure M-VIII 1.6: Manmade Fibre and Raw Material 

Overview of Indian Man-Made Textile Industry 

  • Second Largest producer of cellulosic fibre/yarn
  • Fifth largest producer of synthetic fibres/yarns.
  • Production of synthetic fibres nearly 10 lakh MT (2009-10) 
  • Production of Synthetic yarn about 15 lakh MT (2009-10)

Indian: Fibre Demand 

  • Current All fibre demand is arround 80 lakh MT
  • Cotton 43 lakh MT and polyester around 30 lakh MT
  • All fibre demand to grow nearly 130 lakh MT by 2020 @ 5% CAGR
  • PFY has grown at around 10% CAGR in last decade and is likely to sustain similar growth rates

Indian: Textile Growth Drivers 

Figure M-VIII 1.7 shows emerging trends of man made textiles

  • Higher disposable income and changing life style
  • Increasing fashion awareness even in tier B, C cities
  • New emerging segment of non-apparel application
  • Increasing urban households and working women population
  • Rapid spread of organised retail sector
  • Rise in exports to traditional and new markets
  • Favourable govt policies like TUFS, SITP (textile Parks)

Table M-VIII 1.6 give the details of demands of man-made fibre in India. Brief details of various synthetic fibre producing units in India is given is Table M-VIII 1.7. Table M-VIII 1.8 gives the details of rising demand of polyester. Per-capita consumption of cotton and manmade fibre is mention in Table M-VIII 1.9.

Introduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) | Chemical Technology - Chemical EngineeringIntroduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) | Chemical Technology - Chemical Engineering

Figure M-VIII 1.7: Emerging Trends in Man-made Textiles 

 

KT

2000

2005

2010

2015

2020

CAGR

2010/2000

CAGR

2020/2010

Polyester

1381

1672

2844

4591

5513

7%

7%

Nylon

86

117

111

118

107

3%

0%

Viscose

284

271

309

334

293

1%

-1%

Acrylic

111

110

96

121

110

-1%

1%

Polypropylene

42

54

64

80

76

4%

2%

Total MMF

1904

2224

3424

5244

6099

6%

6%

All Fibres

4948

5735

7826

10871

12984

5%

5%

 

 

Table M-VIII 1.7: Various synthetic fibre producing units in India 

 

Sl.No

Name and Location of Industrial Unit

Product

1

J.K.Synthetics, Rajasthan

NFY, PFY, NTC,

PSF, ASF

2

Garware Nylon, Pune

NFY, PFY

3

Nirlon Synthetic Fibers and Chemicals

NFY, PFY, NTC

4

Modipon, Modi Nagar, Uttar Pradesh

NFY, PFY

5

Century Enka, Pune,

NFY, PFY

6

Baroda Rayon Corporation

NFY, PFY, VFY,

NTC

7

Shree Synthetics, Madhya Pradesh

NFY, PFY

8

Stretch Fibers

NFY

9

Petrofils Cooperative

PFY

10

Chemicals and Fibers, Thane

PSF

11

Ahmedabad Manufacturing and Calico Printing Company

PSF

12

Swadeshi Polytex , Uttar Pradesh

PSF

13

Indian Organic chemicals, Manali, Tamil Nadu

PSF

14

Bongaigaon Refinery and Petrochemicals

PSF

15

Reliance industries [formally Indian Petrochemicals

Corporation, Koyali, Baroda, Gujarat]

ASF

16

Neomar Ltd.,

PPSF

17

Shriram Fibers, Manali, Tamil Nadu

NTC

18

National rayon Corporation, Kalyan,

NTC, VTC, VFY

19

Travancore rayon, Rayanopuram, Kerala

VFY

20

Century Rayon, Kalyan,

VFY, VTC

21

J.K.Rayon,, Uttar Pradesh

VFY

22

Kesoram Rayon, Triveni, west

VFY

23

South Indian Vescose, Tamil Nadu

VFY, VSF, PNSF

24

Indian Rayon Corporation, Veraval

VFY

25

Sirsilk Ltd, Kaghaznagar, Andhra Pradesh

AFY, ATSF

26

Rayon, Nagda, Madhya Pradesh

VSF

27

Rayon, Mavoor, Kerala

VSF

28

Shriram Rayon, Rajasthan

VTC

29

Harihar Poly Fibers, Harihar, Karnataka

PNSF

 

 

Kg per Capital

Mkt share (%)

 

Cotton

Polyester

 

1960

3.3

0.0

67

1970

3.3

0.5

55

1980

3.2

1.2

48

1990

3.5

1.6

47

2000

3.3

3.2

37

2010

3.6

5.2

33

 
Table M-VIII 1.9: Percapita Consumption of Cotton and Manmade Fibre 

Year

Cotton Kg, per capita

Man-made fiber kg, per capita

2005

1.85

2.4

2010

1.65

2.75

2015

1.51

3.3

2020

1.52

3.6

 
The document Introduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) | Chemical Technology - Chemical Engineering is a part of the Chemical Engineering Course Chemical Technology.
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FAQs on Introduction to Polymer, Elastomer and Synthetic Fibre, Polymerisation (Part - 2) - Chemical Technology - Chemical Engineering

1. What is the difference between a polymer and an elastomer?
Ans. Polymers are large molecules made up of repeating subunits called monomers, while elastomers are a specific type of polymer that have the ability to stretch and return to their original shape. Elastomers have a high degree of elasticity, whereas not all polymers exhibit this property.
2. How are synthetic fibers produced?
Ans. Synthetic fibers are produced through a process called polymerization. This process involves the combination of small molecules, known as monomers, to form long chains called polymers. The monomers are usually derived from petrochemicals and are subjected to various chemical reactions to form the desired synthetic fiber.
3. What are the advantages of using synthetic fibers over natural fibers?
Ans. Synthetic fibers offer several advantages over natural fibers. They are generally more durable, have higher strength-to-weight ratios, and are resistant to wrinkles, shrinking, and fading. Synthetic fibers also tend to be more cost-effective and can be engineered to possess specific properties such as flame resistance or moisture-wicking abilities.
4. Can polymers be recycled?
Ans. Yes, many polymers can be recycled. Recycling involves breaking down the polymer into its original monomer units, which can then be used to produce new polymer products. However, the recyclability of polymers depends on the specific type of polymer and the recycling infrastructure available in a particular region.
5. How does the process of polymerization occur?
Ans. Polymerization is a chemical reaction that involves the combination of monomers to form polymers. This reaction can occur through various mechanisms such as addition polymerization, condensation polymerization, or ring-opening polymerization. The process typically requires the use of catalysts, heat, or other initiating agents to facilitate the reaction and create the desired polymer structure.
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