Textile Basics PDF

Summary

This document provides a general introduction to textiles, including the key methods involved in their production, such as weaving, knitting, crocheting, felting, and bonding. It also explores the various applications of textiles across different industries, like apparel, home, technical, and industrial textiles.

Full Transcript

Introduction to Textiles

Textiles are versatile materials composed of fibers, yarns, or fabrics that are
woven, knitted, crocheted, felted, or bonded together. They have been integral
to human civilization for thousands of years, serving functional, aesthetic, and
symbolic purposes across various cultures. Textiles are used in clothing, home
furnishings, industrial applications, and even in technology. The creation of
textiles involves a wide range of techniques, from traditional methods like
weaving and knitting to modern innovations such as digital printing and smart
textiles. Understanding textiles encompasses not only the technical aspects of
their production but also their historical significance, cultural impact, and
future potential in addressing sustainability and advancing technology.
Textile Production Techniques
Textile production involves a variety of techniques, each contributing to the diversity and functionality
of the materials created. Here are some of the key methods:
1. Weaving
Weaving is the process of interlacing two sets of yarns or threads at right angles to form a fabric. The
lengthwise yarns are called the warp, and the crosswise yarns are the weft. Different weaving patterns,
such as plain weave, twill, and satin, result in fabrics with distinct textures and strengths.
2. Knitting
Knitting involves creating fabric by interlocking loops of yarn with needles. It can be done by hand or by
machine. Knitting produces stretchy, comfortable fabrics that are commonly used in apparel.
Techniques include flat knitting and circular knitting, which can create seamless garments.
3. Crocheting
Crocheting uses a hooked needle to interlock loops of yarn. This technique is often employed to make
intricate patterns and decorative items, such as lace, doilies, and various clothing accessories. It allows
for a high degree of creativity in design.
4. Felting
Felting is the process of matting, condensing, and pressing fibers together to create a non-woven
fabric. This can be achieved through wet felting, which uses water and soap, or needle felting, which
employs barbed needles. Felting produces dense, durable fabrics often used for hats, bags, and
slippers.
5. Bonding
Bonding involves combining fibers or yarns using adhesives, heat, or pressure to create non-woven
fabrics. This method is essential in producing materials for industrial applications, such as interfacings,
disposable products, and geotextiles. Bonded fabrics are characterized by their strength and durability.
Textiles encompass a wide range of applications across various fields. Here’s an overview of some major fields of textiles with
respect to their application:
1. Apparel Textiles
Clothing: Everyday wear, fashion, activewear, undergarments.
Footwear: Socks, shoe linings, laces, and other components.
Accessories: Scarves, ties, hats, gloves.
2. Home Textiles
Bedding: Sheets, pillowcases, blankets, duvets.
Bath: Towels, bathrobes, bath mats.
Upholstery: Sofa covers, cushions, throws.
Window Treatments: Curtains, drapes, blinds.
Floor Coverings: Carpets, rugs, mats.
Kitchen Textiles: Tablecloths, napkins, kitchen towels.
Outdoor: Patio furniture covers, hammocks, swings, outdoor cushions.
3. Technical Textiles
Medical Textiles: Surgical gowns, bandages, implants, hygiene products.
Automotive Textiles: Seat covers, airbags, belts, headliners, carpets.
Construction Textiles: Geotextiles, tarpaulins, roofing membranes.
Agricultural Textiles: Shade nets, crop covers, ground covers.
Protective Textiles: Fire-resistant clothing, bulletproof vests, high-visibility garments.
Sports Textiles: Performance-enhancing clothing, sports equipment covers.
4. Industrial Textiles
Filtration Textiles: Air and water filters, industrial filters.
Transport Textiles: Conveyor belts, safety belts, airbags.
Packaging Textiles: Sacks, bags, wrappings.

Smart Textiles
Wearable Technology: Clothing integrated with sensors, temperature regulation, fitness tracking.
E-Textiles: Fabrics with embedded electronic components like LEDs, batteries, or sensors.
6. Interior Textiles
Wall Coverings: Wallpapers, textile wall coverings.
Ceilings: Acoustic panels, fabric ceilings.
Lamps and Lighting: Textile lampshades, fiber optic textiles for lighting.
7. Environmental Textiles
Eco-Friendly Fabrics: Organic cotton, recycled polyester, biodegradable materials.
Sustainable Textiles: Textiles designed with minimal environmental impact in mind, including products for
circular fashion.
8. Military Textiles
Camouflage Fabrics: Clothing and equipment covers with camouflage patterns.
Ballistic Protection: Kevlar vests, protective helmets.
Tent and Shelter Fabrics: Lightweight, durable, and weather-resistant materials for military use.
9. Transport Textiles
Aerospace Textiles: Lightweight composites, insulation, seat fabrics.
Marine Textiles: Sails, boat covers, ropes.
10. Luxury Textiles
High-End Fashion: Couture fabrics, bespoke tailoring materials.
Luxury Interiors: Designer upholstery, premium bed linens, and rugs.
1. What are textiles, and where do we commonly see them used in everyday life?
What are some ways you think textiles are used outside of clothing?

2.What are the primary differences between weaving, knitting, and
non-woven textile production techniques?

3.What do you think are the different steps involved in making a simple piece of fabric?

4.Looking ahead, which field of textile application do you believe holds
the most potential for growth and innovation? Why

5.What potential do smart textiles have for future
innovations?
Case Study Analysis:
Choose a specific product within your selected field that represents a
significant innovation or application.
Analyze the textile production techniques used in this product, considering
factors such as material choice, manufacturing process, and finishing techniques.
Evaluate the impact of this product on its respective industry, including any
environmental or societal implications.
INTRODUCTION TO FIBERS
Fibers are thin, thread-like materials that can be spun into yarn and then woven or knitted to
create fabrics. They can be natural, derived from plants or animals, or man-made, created
through chemical processes. Here's a simple breakdown:

Natural Fibers
1.Plant-Based Fibers
1. Cotton: Soft, breathable, and absorbent. Used in clothing, towels, and sheets.
2. Linen: Made from flax plants. Strong, absorbent, and dries quickly. Used in summer
clothing and table linens.
3. Hemp: Durable and strong. Used in ropes, clothing, and eco-friendly products.
2.Animal-Based Fibers
1. Wool: Comes from sheep. Warm, insulating, and moisture-wicking. Used in sweaters,
blankets, and suits.
2. Silk: Produced by silkworms. Smooth, soft, and luxurious. Used in fine clothing, scarves,
and ties.
3. Cashmere: Comes from goats. Very soft and warm. Used in high-quality sweaters and
scarves.

Man-Made Fibers
3.Synthetic Fibers
1. Polyester: Durable, resistant to shrinking and stretching, quick-drying, and wrinkle-
resistant. Used in clothing, home furnishings, and industrial fabrics.
2. Nylon: Strong, elastic, and lightweight. Used in hosiery, activewear, outerwear, ropes, and
carpets.
3. Acrylic: Soft, lightweight, and warm. Used in sweaters, blankets, and carpets.
4.Regenerated Fibers
Regenerated fibers, also known as semi-synthetic fibers, are created by chemically processing natural
materials to form a fiber. These fibers are derived from natural sources such as cellulose from plants but
undergo significant chemical transformation during their production. Here are the key points about
regenerated fibers:

Key Types of Regenerated Fibers
1.Rayon (Viscose)
1. Source: Made from wood pulp or other plant materials.
2. Characteristics: Soft, absorbent, and drapes well. Can be made to resemble silk, cotton, or wool.
3. Uses: Apparel, home textiles, medical products, and tire cords.
2.Lyocell (Tencel)
1. Source: Made from cellulose, typically from sustainably harvested wood.
2. Characteristics: Strong, absorbent, breathable, and biodegradable. Has a smooth, silky feel.
3. Uses: Clothing, bed linens, towels, and nonwoven products.
3.Modal
1. Source: Made from beech tree pulp.
2. Characteristics: Soft, smooth, and highly absorbent. More durable and flexible than rayon.
3. Uses: Underwear, activewear, and bedding.
4.Cupro (Cuprammonium Rayon)
1. Source: Made from cotton linter (the short fibers left after ginning cotton).
2. Characteristics: Silky, smooth, and breathable. Often used as a silk substitute.
3. Uses: Lining fabrics, evening wear, and luxury clothing.
Advantages of Regenerated Fibers
1.Comfort:
1. Softness: Regenerated fibers like rayon and modal are known for their softness, making them
comfortable to wear.
2. Breathability: They are breathable and moisture-absorbent, helping to keep the wearer cool and dry.
2.Versatility:
1. Adaptability: These fibers can be engineered to have various textures and properties, allowing them to
mimic natural fibers like silk, wool, or cotton.
2. Wide Range of Uses: Suitable for clothing, home textiles, medical products, and technical applications.
3.Eco-Friendliness:
1. Renewable Sources: Derived from natural, renewable resources such as wood pulp.
2. Biodegradability: Many regenerated fibers are biodegradable, reducing environmental impact.
4.Aesthetic Appeal:
1. Drape and Feel: They drape well and have a luxurious feel, making them ideal for fashion and high-end
products.
2. Dyeability: Regenerated fibers absorb dyes well, resulting in vibrant and long-lasting colors.
Disadvantages of Regenerated Fibers
5.Environmental Concerns:
1. Chemical Processing: The production process involves chemicals, which can be harmful if not
managed properly. This is particularly an issue with traditional viscose production.
2. Resource-Intensive: Manufacturing can be resource-intensive, requiring large amounts of water and
energy.
6.Durability:
1. Strength: Regenerated fibers can be less durable than synthetic fibers, particularly when wet. They may
stretch or lose shape over time.
7.Care Requirements:
1. Maintenance: Some regenerated fibers may require special care, such as hand washing or dry cleaning,
to maintain their appearance and longevity.
 PHYSICAL PROPERTIES OF FIBERS

Fiber length

Staple fibers are short lengths of fiber, typically measured in centimeters or inches, that can be
spun together to create yarn. These fibers can be natural or synthetic. Here's a simple
explanation:

What Are Staple Fibers?
Length: Staple fibers are short, usually ranging from a few millimeters to several inches.
Natural Examples: Cotton, wool, and flax. These fibers naturally come in short lengths.
Synthetic Examples: Polyester and nylon can also be cut into short lengths to create staple
fibers.
Filament fibers are long, continuous fibers that can be many meters or even
kilometers in length. They differ from staple fibers, which are short and need to be
spun together to create yarn. Here’s a simpler explanation of filament fibers:

What Are Filament Fibers?
Length: Filament fibers are very long and continuous.
Natural Examples: Silk is the only natural filament fiber, produced by
silkworms.
Synthetic Examples: Polyester, nylon, and acrylic are common synthetic
filament fibers.
Property Staple Fibers Filament Fibers

Length Short Long and continuous

Texture Fuzzy, soft Smooth, silky

Strength Moderate, prone to pilling High, durable

Processing Requires spinning Can be used directly

Appearance Matte, natural look Glossy, elegant look

Breathability More breathable Less breathable

Absorbency Often highly absorbent Varied

Everyday clothing, home Elegant clothing, technical
Common Uses
textiles uses
Fiber size

Fiber size, often referred to as fiber diameter or fineness, is a measure of the thickness or
width of a fiber. It plays a significant role in determining the properties and performance of
textiles made from these fibers. Here’s a simple explanation:

What is Fiber Size?
Definition: Fiber size is the measurement of the diameter or thickness of a single fiber.
Units: It is usually measured in micrometers (µm) for natural fibers or denier and tex for
synthetic fibers.
Micrometers (µm): Used for natural fibers. For example, cotton fibers are typically
around 12-20 µm in diameter.
Denier: A unit of measure for the linear mass density of fibers, defined as the mass in
grams per 9,000 meters of the fiber. For example, a fiber with a denier of 1 is very fine,
while a fiber with a denier of 10 is thicker.
Thick (Coarse) Fibers
Diameter:
Natural Fibers: Coarse fibers typically have larger diameters, often over 20
micrometers (µm). For example, coarse wool fibers can be 30 µm or more in diameter.
Synthetic Fibers: Coarse synthetic fibers can be made to any thickness but are usually
measured in higher deniers or tex. For example, a coarse synthetic fiber might be 10
denier or higher.

Fine Fibers
Diameter:
Natural Fibers: Fine fibers have smaller diameters, usually below 20 micrometers
(µm). For example, fine Merino wool can be as thin as 17 µm.
Synthetic Fibers: Fine synthetic fibers can be produced with very low deniers, such
as 1 denier or lower, indicating a very thin fiber.
Property Thick (Coarse) Fibers Fine Fibers
Over 20 µm (e.g., 30 µm for Below 20 µm (e.g., 17 µm
Diameter
coarse wool) for fine Merino wool)
Generally strong but can be
Strength and Durability Stronger, more durable
more delicate
Texture and Feel Rougher, stiffer Softer, smoother
Breathability Less breathable More breathable
Good for certain Effective due to fine air
Insulation
applications trapping
Appearance Matte, less smooth Shiny, lustrous
Requires precise handling
Processing Easier to handle
and equipment
Fiber Crimp
Fiber crimp What is Fiber Crimp?
Fiber crimp is the natural waviness or bends in a fiber that significantly affect the properties of
textiles. It enhances elasticity, resilience, bulk, warmth, drape, and comfort, making crimp an
essential factor in textile manufacturing and fabric performance.

Definition: Fiber crimp is the natural waviness or zigzag shape of a fiber.
Appearance: Crimp can be visualized as the natural curls or bends in the fiber.
Measurement: Crimp is usually measured in terms of the number of crimps per unit
length, such as crimps per inch or crimps per centimeter
Formula:
Crimp Percentage=(Crimped LengthTotal Length)×100\text{Crimp Percentage} = \left( \
frac{\text{Crimped Length}}{\text{Total Length}} \right) \times
100Crimp Percentage=(Total LengthCrimped Length​)×100
Example Calculation:
Total Length: Measure a 10 cm (100 mm) length of wool fiber.
Crimped Length: Within this 10 cm length, measure that 20 mm of the fiber exhibits
crimps or waves.
Crimp Percentage=(20 mm100 mm)×100=20%\text{Crimp Percentage} = \left( \
frac{20 \text{ mm}}{100 \text{ mm}} \right) \times 100 =
 Natural Fibers:
Wool: Known for its naturally high crimp, which contributes to its warmth and ability to retain heat. It's
also resilient, making it suitable for various garments and insulation materials.
Cotton: Although it has a slight natural crimp compared to wool, it still impacts the fabric's texture,
making it softer and more absorbent.
Synthetic Fibers:
Polyester: Often texturized to mimic natural fibers like wool, adding crimp to enhance its softness and
bulkiness. This makes polyester suitable for a wide range of applications from clothing to home
furnishings.
Nylon: Texturized nylon fibers have increased durability and elasticity due to crimp, making them
suitable for use in carpets, activewear, and other applications where resilience is crucial.

Formula:
Crimp Percentage=(crimped length / total length ​
)×100
 Assignment 2- Fiber Properties

Fiber 1: Natural Fiber
Type: Discusses a specific natural fiber
Characteristics: Examines the typical length range and measurement methods.
Describes the fiber diameter (size) and its implications on textile properties.
Explores the presence or absence of crimp and its effects on applications.
Examples: Illustrates common uses based on its unique length, size, and crimp properties.

Fiber 2: Synthetic Fiber
Type: Analyzes a synthetic fiber (e.g., polyester, nylon, acrylic) known for specific properties.
Characteristics:
Compares length characteristics with the natural fiber discussed.
Evaluates fiber diameter (size) and contrasts it with natural fibers.
Explores artificial crimp or texturizing methods and their impacts.
Examples: Highlights applications where synthetic fibers excel due to their unique properties.

Comparison and Analysis:
Length: Compares how fiber length influences textile durability, texture, and cost-effectiveness.
Size (Diameter): Analyzes the effects of fiber size on softness, strength, and visual appearance.
Crimp: Discusses the role of crimp in fabric elasticity, insulation, and suitability for different climates.
Fiber Shape
Fiber shape refers to the cross-sectional configuration of a fiber. It is an essential aspect
that influences the performance and aesthetics of textile products. Different fiber shapes
offer unique properties, affecting factors like luster, texture, strength, and the ability to
trap air.

Shape controls
Lustre
Bulk/ thickness
Body
Texture
Hand or feel of the fabric
Cross-sectional fiber shapes refer to the various geometric forms that the cross-section of a fiber can take.
These shapes significantly influence the physical properties and performance characteristics of fibers in different
applications. Here are some common cross-sectional fiber shapes:

1.Round: The most common and simplest shape, providing uniform strength and flexibility.
2.Trilobal: Three-lobed shape, often used to enhance luster and tactile properties.
3.Pentagonal: Five-sided shape that can enhance bulk and reduce shininess.
4.Hexagonal: Six-sided shape, providing unique optical and mechanical properties.
5.Hollow: Fibers with a hollow center to reduce weight and improve insulation.
6.Ribbon: Flat and wide shape, offering unique aesthetic and functional properties.
7.Dog bone: Resembles a dog bone, often used for specific mechanical properties.
8.C-shaped: Offers unique handling and aesthetic properties, often used in special textiles.

Each shape impacts the fiber's properties, such as luster, texture, bulk, strength, and how it interacts with light
and other fibers. This allows for customization of fibers to meet specific needs in textiles, filtration, insulation, and
other applications.
Fiber Surface
The surface characteristics of a fiber play a crucial role in determining its performance,
appearance, and interaction with other materials.

Fibre surface influence
– lustre
– Hand feel
– texture
Mechanical Properties of fiber
Fiber mechanical properties refer to the physical behaviors and characteristics of fibers
under various forces and conditions. These properties are crucial in determining the
performance, durability, and suitability of fibers for specific applications. Here are the key
mechanical properties of fibers:
Tensile Strength:
The maximum stress that a fiber can withstand while being stretched or pulled before breaking. It is a critical indicator
of the fiber's durability and resistance to breakage under tension.
Elongation at Break:
The amount of stretch or extension a fiber undergoes before it breaks, expressed as a percentage of its original
length. High elongation indicates good flexibility and ability to absorb energy.
Elastic Modulus (Young's Modulus):
The ratio of stress to strain in the elastic deformation region of the fiber's stress-strain curve. It measures the fiber's
stiffness or resistance to deformation under an applied force. Higher modulus indicates a stiffer fiber.
Initial Modulus:
The slope of the stress-strain curve in the initial linear region, representing the stiffness of the fiber when it first starts
to deform elastically.
Tenacity:
The ultimate tensile strength of a fiber expressed in terms of force per unit linear density (e.g., grams per denier or
tex). It combines strength and fineness, providing a measure of the fiber's ability to bear loads.
 Stress Strain Diagram

A stress-strain diagram is a graphical representation of a material's response to applied stress,
showing how it deforms under various levels of stress. For fibers, this diagram helps illustrate
their mechanical properties and behavior under tension. Here's a simple explanation of the
key parts of a fiber stress-strain diagram:
Key Parts of a Stress-Strain Diagram
1.Stress (Y-axis):
1. This axis represents the amount of force applied to the fiber per unit area. It is usually
measured in units like Pascals (Pa) or Megapascals (MPa).
2.Strain (X-axis):
1. This axis represents the amount of deformation the fiber undergoes in response to the
applied stress. It is a dimensionless quantity, often expressed as a percentage.
Stress
(cN/tex)
70 aramid
60 fla polypropylene
x polyester staple
50

40
cotton silk
30
viscose acryli
20 c
cellulose
acetate
10 wool

0
0 5 10 15 20 25 30 35 40
Strain
Assignment: Choose a specific industry (e.g., aerospace, textiles, construction) and
research how mechanical properties of fibers influence material selection and design
in that industry. Focus on one or two mechanical properties (e.g., tensile strength and
abrasion resistance) and discuss real-world examples of fiber applications in that field.

Deliverable: Write a case study report detailing the role of fiber mechanical
properties in the chosen industry, providing examples of how different fibers are
selected based on their mechanical characteristics
Polymers And Fiber Surface
 Polymers are like long chains made up of repeating links called monomers. Imagine a polymer as a
long necklace where each bead is a monomer.

Monomers are small, reactive units that join together to form the large, non-reactive polymers. Think of
monomers as individual Lego pieces that can be snapped together to build something much larger.

Macromolecule is another term for a long-chain molecule like a polymer, highlighting its large size.
Types of polymers
Homopolymers
Homopolymers are polymers composed of repeating units of a single type of monomer. In
other words, all the monomer units along the polymer chain are identical. This uniformity
gives homopolymers predictable and consistent properties.

Imagine a long chain made from building blocks that all look exactly the same. That's what
a homopolymer is like. It's a type of plastic where every single building block (or
"monomer") along the chain is identical.
Copolymers
Copolymers, on the other hand, are polymers composed of two or more different
types of monomer units. These monomers can be arranged in different patterns
along the polymer chain, depending on how they are polymerized.

Now, picture a chain made from building blocks where some blocks are one type and
others are a different type, but they're all still connected in one chain. That's what a
copolymer is. It's when you have two or more different kinds of building blocks linked
together in a single chain. This mixing of different blocks can give copolymers special
properties.
 Degree of
polymerization
The degree of polymerization (DP) refers to the number of monomer units (or repeating
units) that are linked together to form a polymer chain. In simpler terms, it measures
how long the polymer chain is by counting the number of monomer units it contains.

Understanding Degree of Polymerization
1.Monomer Units: Polymers are made by linking together small molecules called
monomers. For example, in polyethylene (PE), the monomer unit is ethylene (C2H4).
2.Polymer Chain Length: The degree of polymerization indicates how many of these
monomer units are joined together in a single polymer chain. A higher degree of
polymerization means a longer chain.
3.Importance: The degree of polymerization affects the properties of the polymer.
Longer chains typically result in stronger materials with higher melting points and
greater toughness.
Calculation
To calculate the degree of polymerization, you simply count the number of monomer
units in the polymer chain. For instance, if a polymer chain of polyethylene has 1000
ethylene monomer units linked together, its degree of polymerization is 1000.