Contents
Introduction
Textiles have such an important bearing on our daily lives that everyone should know something about the basics of fibres and their properties.
Textile fibres are used for a wide range of applications such as covering, warmth, personal adornment and even to display personal wealth.
Textile technology has come a long way in meeting these requirements. A basic knowledge of textile fibres will facilitate an intelligent appraisal of fibre brands and types and help in identifying the right quality for the application.
This bulletin covers various textile fibres and the properties that are important for a suitable textile application.
Fibre Classification
Textile fibres can be broadly classified into two categories:
- Natural fibres
- Man-made fibres
Natural Fibres
Natural fibres are subdivided further, as outlined below, by their origin.
Table below when available.
Fibre name | Source | Composition |
Vegetable | ||
Cotton | Cotton boll | Cellulose |
Kapok | Kapok tree | Cellulose |
Linen | Flax stalk | Cellulose |
Jute | Jute stalk | Cellulose |
Hemp | Hemp or Abaca | Cellulose |
Ramie | Rhea and China | Cellulose |
Sisal | Agave leaf | Cellulose |
Coir | Coconut husk | Cellulose |
Pina | Pineapple leaf | Cellulose |
Animal | ||
Wool | Sheep | Protein |
Silk | Silkworms | Protein |
Hair | Hair bearing animals | Protein |
Mineral | ||
Asbestos | Varities of rock | Silicate of Magnesium and Calcium |
Man-made Fibres
Man-made fibres are subdivided as shown below with their various compositions and origin.
Fibre Name | Source |
Cellulosic | |
Rayon | Cotton linters or wood |
Acetate | Cotton linters or wood |
Tri-acetate | Cotton linters or wood |
Non-Cellulosic Polymers | |
Nylon | Aliphatic polyamide |
Aramid | Aromatic polyamid |
Polyester | Dihydric alcohol and terephthalic acid |
Acrylic | Acrylonitrile |
Modacrylic | Acrylonitrile |
Spandex | Polyurethene |
Olefin | Ethylene or propylene |
Vinyon | Vinyl chloride |
Saran | Vinylidene chloride |
Novoloid | Phenol based navolac |
Polycarbonate | Carbonic acid (polyester derivative) |
Fluorocarbon | Tetrafluoroethylene |
Protein | |
Azlon | Corn, soybean, etc. |
Rubber | |
Rubber | Natural or synthetic rubber |
Metallic | |
Metal | Aluminum, silver, gold, stainless steel |
Mineral | |
Glass | Silica sand, limestone, other minerals |
Ceramic | Aluminium, silica |
Graphite | Carbon |
1. Natural Fibres
Cotton
Cotton, the natural fibre most widely used in apparel, grows in a boll around the seeds of cotton plants. A single fibre is an elongated cell that is a flat, twisted, hollow, ribbon-like structure.
Characteristics
- Fair to good strength
- Very little elasticity
- Less resilient and prone to wrinkling
- Comfortable and soft feel
- Good absorbency
- Conducts heat well
- Damaged by insects, mildew, rot and moths
- Weakened by extended sunlight exposure
Applications
- Widely used in number of textile products
- Commonly used in woven and knitted apparel
- Home textile – bath towels, bath robes, bed covers etc.
- Used as a blend with other fibres as rayon, polyester, spandex etc.
Linen
Linen, one of the most expensive natural fibres, is made from the flax plant. It is labour-intensive to produce, hence produced in small quantities. However linen fabric is valued for its exceptional coolness and freshness in hot weather.
It is composed of 70% cellulose and 30% pectin, ash, woody tissue and moisture.
Characteristics
- Strongest vegetable fibre
- Poor elasticity, hence wrinkles easily
- Relatively smooth, becomes softer when washed
- Highly absorbent
- Good conductor of heat and feels cool
- Lustrous
- More brittle, constant creasing in the sharp folds, tends to break
- Damaged by mildew, perspiration and bleach
- Resistant to moths and carpet beetles
Applications
- Apparel – suits, dresses, skirts, shirts etc.
- Home and commercial furnishing items – table cloths, dish towels, bed sheets, wallpaper / wall coverings, window treatments etc.
- Industrial products – luggage, canvas etc.
- Used as blend with cotton
Wool
Wool fibre grows from the skin of sheep and is a relatively coarse and crimped fibre with scales on its surface. It is composed of protein. The fibre appearance varies depending on the breed of the sheep. Finer, softer and warmer fibres tend to be with more and smoother scales. Thicker, less warm fibres have fewer and rougher scales. Normally, the better wool fibres with finer scales are duller in appearance than the poorer quality fibres which have fewer scales.
Characteristics
- Crimped in appearance
- Elastic
- Hygroscopic, readily absorbs moisture
- Ignites at a higher temperature than cotton
- Lower rate of flame spread, heat release and combustion heat
- Resistant to static electricity
Applications
- Clothing – jackets, suits, trousers, sweaters, hats etc.
- Blankets, carpets, felt and upholstery
- Horse rugs, saddle cloths
Silk
Silk is a fine, continuous strand unwound from the cocoon of a moth caterpillar known as the silkworm. It is composed of protein. It is very shiny due to the triangular prism-like structure of the silk fibre, which allows silk cloth to refract incoming light at different angles.
Characteristics
- Lustrous, smooth and soft texture and not slippery
- Lightweight, strong, but can lose up to 20% of its strength when wet
- Elasticity is moderate to poor. If elongated, it remains stretched
- Can be weakened if exposed to too much sunlight
- May be affected by insects, especially if left dirty
- Can regain up to 11% of its moisture
Applications
- Shirts, ties, blouses, formal dresses, high-fashion clothes
- Lingerie, pyjamas, robes, dress suits and sun dresses
- Many furnishing applications
- Upholstery, wall coverings, and wall hangings
Other Natural Fibres
Jute
Jute is taken from a tall plant of the same name and it is easy to cultivate and harvest. It is the cheapest fibre and is used in great quantities.
Characteristics
- It is not durable as it deteriorates rapidly when exposed to moisture
- Less strength
- Cannot be bleached to make it pure white due to lack of strength
Applications
- Binding threads for carpets, coarse and cheap fabrics, heavy bagging etc.
Kapok
It is a white hair-like fibre obtained from the seed capsules of plants and trees called Ceiba Pentandra grown in Java and Sumatra (Indonesia), Mexico, Central America and the Caribbean, Northern South America and tropical West Africa.
It is called silk cotton due to its high lustre which is equal to that of silk.
Characteristics
- Smooth texture
- Very lustrous
- Weak
- Short fibre length
- Resistant to moisture, dries quickly when wet
Applications
- Mattresses, cushions, upholstered furniture
Ramie
A woody fibre resembling flax and it is also known as rhea and China grass. It is taken from a tall flowering plant.
Characteristics
- Stiff
- More brittle
- Lustrous
Applications
- Canvas, upholstery, clothing, etc.
2. Man-made Fibres
2.1. Man-made (Regenerated)
Cellulosic
They are derived either from the cellulose of the cell walls of short cotton fibres that are called linters or, more frequently from pine wood. There are three types of man made cellulosic fibres: Rayon, acetate and tri-acetate.
Rayon
Rayon [link to Raylon] is made from naturally occurring polymers that simulate natural cellulosic fibres. It is neither a truly synthetic fibre nor a truly natural fibre.
There are two varieties of Rayon; viscose and high wet modulus (HWM). These in turn are produced in a number of types to provide certain specific properties.
Characteristics
- Soft, smooth and comfortable
- Naturally high in lustre
- Highly absorbent
- Durability and shape retention is low, especially when wet
- Low elastic recovery
- Normally weak, but HWM rayon is much stronger, durable and has good appearance retention.
Applications
- Apparel – blouses, dresses, jackets, lingerie, linings, suits, neck ties etc.
- Furnishing items – bedspreads, bed sheets, blankets, window treatments, upholstery etc.
- Industrial uses e.g. medical surgery products, non-woven products, tyre cord etc.
- Other uses – feminine hygiene products, diapers, towels etc.
Acetate
Acetate consists of a cellulose compound identified as acetylated cellulose – a cellulose salt. Hence it possesses different qualities compared to rayon.
Acetate is thermoplastic and can be formed into any shape by application of pressure combined with heat. Acetate fibres have good shape retention.
Characteristics
- Thermoplastic
- Good drapability
- Soft, smooth and resilient
- Wicks and dries quickly
- Lustrous appearance
- Weak, rapidly loses strength when wet, must be dry-cleaned
- Poor abrasion resistance
Applications
- Primarily in apparel – blouses, dresses, jackets, lingerie, linings, suits, neck ties, etc.
- Used in fabrics such as satins, brocades, taffetas, etc.
Tri-acetate
Tri-acetate consists of acetylated cellulose that retains acetic groupings, when it is being produced as triacetate cellulose. It is a thermoplastic fibre and is more resilient than other cellulosic fibres
Characteristics
- Thermoplastic
- Resilient
- Shape retentive and wrinkle resistant
- Shrink resistant
- Easily washable, even at higher temperatures
- Maintains creases and pleats well
Applications
- Primarily apparel
- Used in clothing where crease / pleat retention is important e.g. skirts and dresses
- Can be used with polyester to create shiny apparel
2.2. Man-made – Non-cellulosic
Polymer Fibres
This group of fibres is distinguished by being synthesised or created from various elements into larger molecules that are called linear polymers.
The molecules of each particular compound are arranged in parallel lines in the fibre. This arrangement of molecules is called molecular orientation.
The properties of such fibres are dependent on their chemical composition and kinds of molecular orientation.
Nylon
In nylon, the fibre forming substance is a long-chain synthetic polyamide in which less than 85% of the amide linkages are attached directly to two aromatic rings. The elements carbon, oxygen, nitrogen and hydrogen are combined by chemical processes into compounds which react to form long-chain molecules, chemically known as polyamides and are then formed into fibres. There are several forms of nylon. Each depends upon the chemical synthesis.
They are: Nylon 4; 6; 6.6; 6.10; 6.12; 8; 10; and 11.
Characteristics
- Highly resilient
- High elongation and elasticity
- Very strong and durable
- Excellent abrasion resistance
- Thermoplastic
- Has the ability to be very lustrous, semi-lustrous or dull
- Resistant to insects, fungi, mildew and rot
Applications
- Apparel – pantyhose, stockings, leggings, etc.
- Home furnishing
- Industrial applications – parachutes, tyre cords, ropes, airbags, hoses, etc.
Polyester
In polyester, the fibre forming substance is any long-chain synthetic polymer composed of at least 85% by weight of an ester of a substituted aromatic carboxylic acid, but not restricted to substituted terapthalate units and para-substituted hydroxybenzoate units.
In producing such fibres, the basic elements of carbon, oxygen and hydrogen are polymerised. Variations are possible in the methods of production, in the combination of ingredients and in the ultimate molecular structures of the fibre forming substance.
Characteristics
- Thermoplastic
- Good strength
- Hydrophobic (non absorbent)
Applications
- Apparel – woven and knits, shirts, pants, jackets, hats etc.
- Home furnishing – bed sheets, blankets, upholstered furniture, cushioning material
- Industrial uses – conveyor belts, safety belts, tyre reinforcement
Spandex
The fibre forming substance used to produce spandex is any long-chain synthetic polymer composed of at least 85% of segmented polyurethane. Variations are possible when producing this fibre.
The basic elements of nitrogen, hydrogen, carbon and oxygen are synthesised with other substances to ethyl ester compounds in polymer chains of soft segments or sections that provide stretch and harder segments that hold the chain together.
Trademarks of three spandex fibres are Cleer-span, Glospan and Lycra.
Characteristics
- Highly elastic
- Comfortable
- High shape retention
- Durable
Applications
- Never used alone, but always blended with other fibres
- Apparel and clothing items with stretch for comfort and fit
- Hosiery
- Foundation garments
- Swimwear, athletic, aerobic apparel
- Lingerie, leggings and socks
- Shaped garments e.g. bra cups
- Gloves
Acrylic
In acrylics, the fibre forming substance is any long chain polymer composed of at least 85% by weight of acrylonitrile units. Using complicated processes, carbon, hydrogen and nitrogen, the basic elements are synthesised with small amounts of other chemicals into larger polymer combinations. Variations are possible in the methods of production, in the combination of ingredients and in the ultimate molecular structures of the fibre forming substance.
Characteristics
- Soft, warm handling characteristics similar to wool
- Resilient
- Shape retentive
Applications
- Vêtement
- Home furnishing
3. Man-made – Protein Fibres
The protein from such products as corn and milk has been processed chemically and converted into fibre. However, such fibres are not commercially successful.
4. Man-made – Rubber Fibres
The fibre forming substance is comprised of natural and synthetic rubber. The treated rubber is produced in strands, so that the cross-section is either round or square and the longitudinal surface is relatively smooth.
5. Man-made – Metallic Fibres
These fibres are composed of metal, plastic-coated metal, metal-coated plastic, or a core completely covered by metal. These fibres are usually produced in flat, narrow, smooth strips which possess high lustre.
Applications
- Decorative yarns in apparel and home furnishing items.
6. Man-made – Mineral Fibres
Various minerals have been manufactured into glass, ceramic and graphite fibres having prescribed properties for specific uses.
Glass
Although glass is a hard and inflexible material, it can be made into a fine, translucent textile fibre that has an appearance and feel of silk.
Natural minerals such as silica sand, limestone, soda ash, borax, boric acid, feldspar and fluorspar have been fused under very high temperatures into glass which is processed into a fibre.
Characteristics
- Inert
- Highly flame resistant
Applications
- Heat resistant industrial applications
Textile Fibre Parameters
Fibrous materials should possess certain properties to become a suitable textile raw material. Properties which are essential for acceptance as a suitable raw material may be classified as ‘primary properties’. The other properties which add specific desirable character or aesthetics to the end product and its use may be classified as ‘secondary properties’.
Primary Properties
1. Length
2. Tenacity (strength)
3. Flexibility
4. Cohesion
5. Uniformity of properties
Secondary Properties
1. Physical shape
2. Specific gravity (influence weight, cover etc.)
3. Moisture regain and absorption (comfort, static electricity etc.)
4. Elastic character
5. Thermo plasticity (softening point and heat – set character)
6. Dyeability
7. Resistance to solvents, corrosive chemicals, micro-organisms and environmental conditions
8. Flammability
9. Lustre
Physical Properties
Cotton
Property | Characteristics |
Microscopic appearance | Flat, twisted and ribbon-like |
Length | Staple fibre, length ranges from 1 to 5.5 cm |
Colour | Creamy white in natural form, unless treated |
Lustre | Medium, unless treated for lustre |
Strength | Fair |
Elasticity | Low |
Resilience | Low |
Moisture absorption | Excellent |
Heat | Will withstand moderate heat / Decomposes after prolonged exposure to temperatures of 150°C / 320°F or over |
Flammability | Burns readily |
Linen
Property | Characteristics |
Microscopic appearance | Cross-section is made up of irregular polygonal shapes |
Length | Long staple, 25 to 120 cms |
Colour | Off white |
Lustre | High |
Strength | Good |
Elasticity | Low |
Resilience | Little |
Moisture absorption | Good |
Heat | Will withstand moderate heat |
Flammability | Scorches and flames readily |
Wool
Property | Characteristics |
Microscopic appearance | Crimped |
Length | Staple fibre, up to 40 cms |
Colour | Generally creamy white, some breeds of sheep produce natural colours such as black, brown, silver, and random mixes. |
Lustre | High |
Strength | High |
Elasticity | Good |
Resilience | High |
Moisture absorption | Tends to repel initially, but good absorption. |
Heat | Becomes harsh at 100°C / 212°F, decomposes at slightly higher temperatures. |
Flammability | Scorches at 204°C / 400°F, will char |
Silk
Property | Characteristics |
Microscopic appearance | Triangular prism-like structure |
Length | Continuous filament |
Colour | Usually off white, and also shades of pale beige, brown, and grey |
Lustre | Excellent |
Strength | Good |
Elasticity | High |
Resilience | High |
Moisture absorption | Good |
Heat | Sensitive and gets decomposed |
Flammability | Burns at 165°C / 330°F |
Rayon
Property | Characteristics |
Microscopic appearance | Striations seen in viscose and high strength rayon
If delustred, scattered specks of pigment can be seen |
Length | Filament and Staple |
Colour | Transparent unless dyed |
Lustre | High |
Strength | Fair to excellent Regular rayon has fair strength High tenacity types have good strength |
Elasticity | Regular rayon: low High strength rayon: good |
Resilence | High wet strength rayon is better |
Moisture absorption | Higher than natural cellulose Fibres swell in water Weaker when wet |
Heat | Loses strength above 148°C / 300°F Decomposes between 176°C / 350°F and 204°C / 400°F |
Flammability | Burns rapidly unless treated |
Electrical conductivity | Fair – static charge can be reduced with special finishes |
Acetate
Property | Characteristics |
Microscopic appearance | Striations farther apart than viscose rayon Lobed cross-section |
Length | Filament and staple |
Colour | Transparent unless dulled by pigments |
Lustre | Bright, semi bright or dull |
Strength | Moderate, less than rayon when it is wet |
Elasticity | Not very high, similar to rayon |
Resilience | Poor |
Moisture absorption | 6%, little strength loss when it is wet |
Heat | Ironing temperatures of 135°C / 275°F are satisfactory |
Flammability | Slowly combustible |
Electrical conductivity | Good |
Nylon
Property | Characteristics |
Microscopic appearance | Very smooth and even |
Length | Filament and staple |
Colour | Off white |
Lustre | High natural lustre that can be controlled |
Strength | Exceptionally high |
Elasticity | Exceptionally high |
Resilience | Very good |
Moisture absorption | 3.8% |
Heat | High resistance, melts at 250°C / 482°F |
Flammability | Melts slowly Does not support combustion |
Electrical conductivity | Low, generates static |
Polyester
Property | Characteristics |
Microscopic appearance | Smooth, even, rod like, different cross sectional shapes |
Length | Filament and staple |
Colour | White |
Lustre | Bright or dull |
Strength | Good to excellent |
Elasticity | Fair to good |
Resilience | Excellent |
Moisture absorption | Less than 1% |
Heat | Softening or sticking temperature is above 204°C / 400°F |
Flammability | Burns slowly |
Electrical conductivity | Accumulates static charges |
Acrylic
Property | Characteristics |
Microscopic appearance | Uniform and smooth surface Irregular spaced striations |
Length | Mainly a staple fibre |
Colour | White |
Lustre | Bright or dull |
Strength | Fair to good strength |
Elasticity | Good |
Resilience | Good |
Moisture absorption | 1 – 3% |
Heat | Yellowing may occur above 148°C / 300°F Softening or stocking about 232°C / 450°F |
Flammability | Burns with yellow flame |
Electrical conductivity | Fair to good |
Fibre Properties – Comparison
Absorbency
Fibre | Moisture regain* |
Cotton | 7 -11 |
Flax | 12 |
Silk | 11 |
Wool | 13 – 18 |
Acetate | 6.0 |
Acrylic | 1.3 – 2.5 |
Aramid | 4.5 |
Glass | 0 – 0.3 |
Nylon | 4.0 – 4.5 |
Polyester | 0.4 – 0.8 |
Rayon | 15 |
Rayon HWM | 11.5 – 13 |
Spandex | 0.75 – 1.3 |
*Moisture regain is expressed as a percentage of the moisture-free weight at 70º Fahrenheit and 65% relative humidity.
Thermal properties
Fibre | Melting Point | Softening Sticking Point | Safe Ironing Temperature | ||||
˚F | ˚C | ˚F | ˚C | ˚F | ˚C | ||
Cotton | Non melting | 425 | 218 | ||||
Flax | Non melting | 450 | 232 | ||||
Silk | Non melting | 300 | 149 | ||||
Wool | Non melting | 300 | 149 | ||||
Acetate | 446 | 230 | 364 | 184 | 350 | 177 | |
Acrylic | 400 – 490 | 204 – 254 | 300 – 350 | 149 – 176 | |||
Aramid | Does not melt, carbonises above 426°C / 800°F | ||||||
Glass | 1400 – 3033 | ||||||
Nylon 6 | 414 | 212 | 340 | 171 | 300 | 149 | |
Nylon 66 | 482 | 250 | 445 | 229 | 350 | 177 | |
Polyester PET | 480 | 249 | 460 | 238 | 325 | 163 | |
Polyester PCDT | 550 | 311 | 490 | 254 | 350 | 177 | |
Rayon | Non melting | 375 | 191 | ||||
Spandex | 446 | 230 | 347 | 175 | 300 | 149 |
Effects of Acids
Fibre | Behaviour |
Cotton | Disintegrates in hot dilute and cold concentrated mineral acids |
Linen | Disintegrates in hot dilute and cold concentrated acids |
Wool | Destroyed by hot sulphuric, otherwise unaffected by acids |
Silk | Organic acids do not harm, concentrated mineral acids will dissolve |
Rayon | Disintegrates in hot dilute and cold concentrated acids |
Acetate | Soluble in acetic acid, decomposed by strong acids |
Tri-acetate | Soluble in acetic acid, decomposed by strong acids |
Nylon | Decomposed by strong mineral acids, resistant to weak acids |
Polyester | Resistant to most mineral acids; disintegrated by 96% sulphuric acid |
Spandex | Resistant to most mineral acids, some discolouration can happen |
Acrylic | Resistant to most acids |
Glass | Resistant to most acids |
Effects of Alkalis
Fibre | Behaviour |
Cotton | Not harmed by alkalis |
Linen | Highly resistant |
Wool | Attacked by weak alkalis, destroyed by strong alkalis |
Silk | Damaged only under high temperature and concentration |
Rayon | Disintegrates in concentrated solutions |
Acetate | Not affected, unless high concentration and temperature is applied |
Tr-acetate | Not affected, unless high concentration and temperature is applied |
Nylon | Little or no effect |
Polyester | Resistant to cold alkalis, slowly decomposed at a boil by strong alkalis |
Spandex | Affected |
Acrylic | Destroyed by strong alkalis at boil, resists weak alkalis |
Glass | Attacked by hot weak alkalis and concentrated alkalis |
Effects of Organic Solvents
Fibre | Behaviour |
Cotton | Oxidises, turning yellow and losing strength on long exposure |
Linen | Resistant than cotton, gradually deteriorate from prolonged exposure |
Wool | Strength loss due to prolonged exposure |
Silk | Continuous exposure weakens |
Rayon | Generally resistant, loses strength after long exposure |
Acetate | Approximately same as rayon |
Tri-acetate | Resistant, loses strength after long exposure |
Nylon | Good resistance |
Polyester | Good resistance |
Spandex | Generally not affected, prolonged exposure weakens |
Acrylic | Little or no effect |
Effects of Sunlight
Fibre | Behaviour |
Cotton | Oxidises, turning yellow and losing strength on long exposure |
Linen | Resistant than cotton, gradually deteriorate from prolonged exposure |
Wool | Strength loss due to prolonged exposure |
Silk | Continuous exposure weakens |
Rayon | Generally resistant, loses strength after long exposure |
Acetate | Approximately same as rayon |
Tri-acetate | Resistant, loses strength after long exposure |
Nylon | Good resistance |
Polyester | Good resistance |
Spandex | Generally not affected, prolonged exposure weakens |
Acrylic | Little or no effect |
Cleanliness and Washability
Fibre | Behaviour and effect |
Cotton | Launders well and gives up dirt easily |
Linen | Launders well and gives up dirt easily |
Wool | Attracts dirt, unless thoroughly cleaned it retains odors |
Silk | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Rayon | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Acetate | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Tri-acetate | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Nylon 6.6 | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Polyester | Prevents dirt from settling. Smooth surface allows stains to be easily washed away |
Spandex | Launders well |
Acrylic | Launders well |
Effects of Perspiration
Fibre | Behaviour |
Cotton | Resistant to alkali perspiration, slight deteriorating effect with acid perspiration |
Linen | Resistant to alkali perspiration, slight deteriorating effect with acid perspiration |
Wool | Weakened by alkali perspiration
Discolouration happens in general with perspiration |
Silk | Deteriorates and Colour is affected causing stains |
Rayon | Fairly resistant to deterioration |
Acetate | Good resistance |
Tri-acetate | Good resistance |
Nylon 6.6 | Resistant, Colour may be affected |
Polyester | Resistant |
Spandex | Good resistance to degradation |
Acrylic | No deterioration |
*Perspiration can be acidic or alkaline, depending on the individual’s metabolism.
Effects of Mildew
Fibre | Behaviour and effect |
Cotton | Affected in a damp condition |
Linen | Affected in a damp condition |
Wool | Not susceptible in ordinary condition, but in damp condition |
Silk | Not susceptible in ordinary condition, but in damp condition |
Rayon | Affected in a damp condition |
Acetate | Highly resistant |
Tri-acetate | Extremely high resistance |
Nylon | No effect |
Polyester | Absolutely resistant |
Spandex | Good to excellent resistance |
Acrylic | May form, but will have no effect
Can be easily wiped off |
Effect of Heat
Fibre | Behaviour and effect |
Cotton | Withstand moderate heat
Will scorch and burn with prolonged exposure to high heat |
Linen | Withstand moderate heat
Will scorch and burn with prolonged exposure to high heat |
Wool | Not easily combustible, becomes harsh at 100°C / 212°F and will scorch at 204°C / 400°F and eventually char |
Silk | Sensitive to heat, decomposes at 165°C / 330°F |
Rayon | Behaves similar to cotton as a cellulosic fibre |
Acetate | Thermoplastic in nature, gets sticky at 176°C / 350°F and becomes stiff later |
Tri-acetate | Thermoplastic in nature, gets sticky at 298°C / 570°F and becomes stiff later |
Nylon | Will melt under high temperature, Nylon 6 melts at 215°C / 420°F and Nylon 6, 6 248°C / 480°F |
Polyester | Will melt under high temperature
Becomes sticky at 226°C / 440°F to 243°C / 470°F and melts and flames at 248°C / 480°F to 290°C / 554°F depending on its type |
Spandex | Yellows and loses elasticity and strength at over 148°C / 300°F, sticks at 175°C / 347°F and melts at 230°C / 446°F |
Acrylic | Becomes sticky at 229°C / 455°F and melts at higher temperature |
Effects of Insects
Fibre | Behaviour and effect |
Cotton | Not damaged |
Linen | Not damaged |
Wool | Vulnerable to moths and carpet beetles |
Silk | May be attacked by larvae of cloth moths or carpet beetles |
Rayon | Not attracted |
Acetate | Not attracted |
Tri-acetate | Not attracted |
Nylon | Unaffected |
Polyester | Unaffected |
Spandex | Unaffected |
Acrylic | Unaffected |