Tire Life Cycle and Tire Reinforcing Systems - Utires.com

Last Updated on 06.08. by hrushetskyy

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TIRE LIFE CYCLE

An understanding to the role of tires involves an analysis of product life cycles and specifically the tire life cycles.

A product life cycle is a forecast of product growth and length of Life based on an S-curve analysis. It depicts in effect the life of a product in a time frame. Frequently a product life cycle is projected for a new product prior to introduction. It is akin to writing an obituary at birth.

Product life cycle is related to technological forecasting and long-range planning. Life cycle analysis is used to anticipate trends and pinpoint needs. It makes possible incremental analysis (cost of growth).

Some products have life cycles of several months (hula hoops) others have life cycles of decades (autos tires aspirin nylon television etc.).

Product Life Cycle

The life cycle of a product can be generally divided into five categories.

The first stage is experimentation and development. At this point the product is a technical innovation that has been subjected to a market assessment.

Second is the commercialization stage. This is the period of product introduction to the marketplace. Needless to say many products do not survive this stage. The concept of customer orientation for example has been developed to decrease this failure rate.

Stage III is the period of growth. Product demand is increasing. The size of the total market is expanding. Often shortages occur. The presence of competitors accelerates product differentiation. Brand preference makes an appearance.

Next the product reaches maturity (Stage IV). Demand is leveling off and the market is becoming saturated. Sales growth parallels population growth. There are fierce efforts to hold brand preference. Often this stage includes product differentiation to a fine degree; a multitude of product claims; aggressive promotional practices; intensive distribution efforts; sophisticated advertising techniques; ingenious packaging; emphasis on customer service; and sometimes lowering of prices. The maturity stage of a product can be brief in time or may last for many years.

Finally the product reaches a period of decline (Stage V). The product begins to lose consumer appeal. Overcapacity exists and plants are closed. Prices deteriorate.

The demand criteria for each stage are given below:

I)       Experimentation and Development: little growth
II)      Commercialization: > 10-percent growth per year
III)    Growth: 3- to 10-percent growth per year
IV)    Maturity: 0-to 3-percent growth per year
V)      Decline: negative growth

Tire Life Cycle

More than 5 billion tires have been produced in the USA from to . In constructing a tire life cycle the tire demand curve has been adjusted to eliminate the depression and war years to . The tire demand curve has been superimposed over the classical product life cycle curve. As can be seen tires follow the classical curve to a remarkable degree. Analysis of the tire life cycle leads to the following conclusion: Tires are currently at the middle of the growth period (Stage III) of the product life cycle. Demand growth is about 6 percent per year.

It should be noted that a product life cycle for an industry is not necessarily identical to product life cycles for individual companies within the industry.

Product Demand

A forecast of growth trends in the product life cycle requires an analysis of the determinants of demand. The basic factors affecting product demand can be discussed within the following general groupings: product  mission technology fashion and product-market structure. Each of these categories will be discussed relative to tires.

Product Mission:  A product seeking to assume the role of tires would of necessity be required to have load-carrying capacity have cushioning ability transmit driving and braking torque produce cornering force provide flotation provide lateral stability resist abrasion provide steering response have low rolling resistance and be durable and safe. Add to this fact that a sophisticated personal transportation system has been developed around tires and one can conclude that there is not an immediate competitive threat from a substitute product.

Technology: Maintaining a viable product is essential to product growth. The demand trend can be a function of the introduction rate of product improvements. This can be reflected in new uses for the product or modified products to better satisfy current requirements. Thus the history of innovation in a product is significant. Tires are constantly being improved in an evolutionary manner to meet ever-increasing customer demands. Some of these changes appear revolutionary in retrospect. Basic tire advances appear to occur every decade. In the teens carbon black was adopted in rubber compounds. In the ’s layers of parallel cord fabric were introduced. The ’s saw the appearance of balloon tires.

In the war years synthetic tires were born. Tubeless tires were developed in the ’s. Belted tires made a widespread appearance in the sixties.

Analysis of innovations in a product can lead to sub-life cycles within the major product life cycle. Although the tire life cycle is in Stage III sub-cycles can be identified in all stages.

There are three basic types of tires in using today: bias radial and bias/belted. An analysis of bias passenger tires as a sub-cycle indicates that this construction is in Stage V (decline).

Fashion:  Product life cycles affected by fashion are usually characterized by a more rapid growth stage a shorter maturity stage followed by rapid decline. Tires are generally unaffected by fashion. Should a fashion occur it will affect product mix only.

Product-Market Structure: The changing nature of the product market structure will affect product demand. Close attention must be paid to the demand for the primary product (motor vehicles) that uses tires.

Therefore, different tire manufacturers, such as: Milestar, Westlake, Nokian and others, will depend on the demand for the vehicles for which they produce tires.

Tire Demand Forecast

A tire demand forecast from the tire life cycle indicates a continued expansion for tires.

This can be expected since more leisure time has resulted in an increasing mobility of Americans. A study by the U.S. Department of Commerce forecasts an enormous travel expansion in this country between now and the year . The bulk of this travel will be by automobile.

A major factor in this projection is the miles of interstate highway system. The interstate system represents less than 1 percent of the total highways but accounts for nearly 20 percent of the total vehicle mileage traveled.

TIRE REINFORCING SYSTEMS

A tire is a cord/rubber composite. The tire composite is in the form of a network of cord structures arranged in a parallel configuration and imbedded in a rubber matrix. Rubber as used here is defined as an elastomer compounded with carbon black and various chemical ingredients.

The cord reinforces the rubber much as steel strengthens concrete. However tire cords are very unique materials of construction due to their extremely high fatigue resistance. Tire cords give the tire shape size stability bruise resistance fatigue resistance and load-carrying capacity.

The stringent demands of tire service have limited the types of cords suitable for tires to six. The first pneumatic tires were reinforced with cotton cellulose. In the early days the cotton fabric was square-woven. One of the important advances in tire development occurred about when cotton cord replaced square-woven fabric. The use of plies of cord added tremendous durability and resiliency to the tire. Cotton continued to be the only tire fiber in the USA until when rayon regenerated cellulose was introduced. In nylon became available for military tires and in was introduced to the motoring public.

In wire made an appearance in USA-built tires although it had been in use in Europe since . In polyester was introduced. Then in fiberglass joined this select group.

Terminology

Tire cord technology utilizes a special terminology.

Filament: A filament is the smallest continuous element of a tire cord material and is characterized by a high ratio of length to thickness.

Strand: A strand is an assembly of continuous filaments (often called a yarn with textile materials).

Tire Cord: Classically a tire cord is a twisted or formed structure composed of two or more strands; generally the term is applied to the structure whatever form it may be as used in a tire.

Warp: The warp is the cord in a tire fabric that runs lengthwise.

Filling: The filling is the light thread that is placed at right angles to the warp (filling is often called the pick).

Denier: Denier is a unit of measurement for textile cords. Denier is defined as the weight in grams of meters of the material. Therefore denier is a weight-per-unit-length measurement, the higher the denier the larger the cord.

Twist: Twist is the number of turns per unit of length in a cord. A cord has S twist if the spirals turn to the right or clockwise from top to bottom when the cord is held vertically. A cord has Z twist if the spirals are counterclockwise.

Strength: Strength is the ability of a cord to withstand the ultimate tensile load or force required for rupture. Quite frequently tire cord strengths are expressed in terms of grams per denier. This is called the tenacity of the cord.

V Strength (lbs) x 453.6

Tenacity (GPD) = 0)

Filament Forming

Rayon: The advent of the modern synthetic tire begins with rayon. Since cotton is a natural fiber its structure is limited. Being man made however rayon could be engineered for tires. Rayon is an organic fiber and can be described by the following Formula:Basically rayon is regenerated cellulose. It is manufactured as continuous filament by a wet-spinning process.

Sodium hydroxide is added to wood pulp in a steeping press to form alkali cellulose. The cellulose is shredded aged and treated with carbon disulfide to form cellulose xanthate. The xanthate is then treated with diluted caustic soda to form viscose. After ripening the viscose is filtered and goes to the spinning machine. The viscose is extruded through spinnerets into a regenerating bath. The yarn is composed of many tiny filaments. Each filament is approximately .010 mm in diameter. The yarn is then washed and slashed and finish is added. Finally the yarn is beamed for shipment.

A word should be said about the finish (or lubricant) on a tire yarn. The type of finish oil applied to the yarn can determine (to a degree) cord strength fatigue and adhesion properties.

Rayon tire yarn is available today in three deniers:        yarn yarn and yarn. There are three producers of rayon tire yarn in the USA: American Enka Corporation Beau-nit and AVD division of FMC. Rayon has been used in tires for 35 years.

Nylon: Nylon is a synthetic thermoplastic organic fiber derived from petroleum as contrasted with rayon which is a man-made fiber but not a true synthetic. Chemically nylon tire yarn is a continuous filament aliphatic polyamide.

Although there are hundreds of nylon polymers only two are in commercial use in tires: nylon 66 and nylon 6. Both have the same empirical formula (C^Hj JON) n. Nylon 66 is composed of two recurring units with six carbon atoms (derived from adipic-acid and hexamethylenediamine). Nylon 6 is composed of one recurring unit with six carbon atoms (derived from caprolactam). Nylon 66 is manufactured as follows:

Cyclohexane and ammonia are the basic raw materials. Cyclohexane is oxidized in the presence of a catalyst to form adipic acid. Part of the adipic acid is vaporized over a catalyst and sprayed into superheated ammonia. Adiponitrile is formed. The Adiponitrile is hydrogenated over a catalyst and reduced to hexamethylene diamine. Equal molar quantities of adipic and hexamethylene diamine are dissolved in water to give a nylon salt.

This salt is concentrated and then polymerized to a suitable molecular chain length. The molten polymer is then extruded through stainless steel spinnerets to form filaments. This is called spinning. Each filament is approximately .024 mm in diameter. The filaments are cooled finish is applied and they are combined into a yarn. The nylon yarn is then drawn (or stretched) approximately 500 percent. The drawing takes place suddenly at a “neck point.” This drawing operation orients the molecules in the axial direction and regulates the crystalline. An X-ray diagram of an undrawn nylon yarn is shown on the left and a drawn oriented yarn on the right. After drawing the yarn is beamed for shipment.

Nylon 6 is manufactured as follows: The basic raw material is caprolactam which in turn is synthesized from Cyclohexane. The caprolactam is melted and five percent water is added. These react to form aminocaproic acid. The aminocaproic acid polymerizes to form nylon 6. The water is removed as the reaction progresses.

The molten polymer is then extruded to form filaments in much the same manner as in nylon 66. Nylon tire yarn is available in four deniers: 840 yarns yarn yarn and yarn. There are five producers of nylon tire yarn in the USA:        Allied Chemical DuPont Fiber Industries Firestone and Monsanto.

Polyester: Polyester is also a synthetic thermoplastic continuous filament fiber derived from petroleum and is manufactured in a melt process similar to nylon. Polyester is an organic fiber that differs chemically from nylon however in that polyester contains aromatic groups (or ring structures) in the fiber backbone.

As with nylon there are hundreds of polyester polymers. The only polyester used in tires is polyethylene terephthalate.

-O-(CH2) -O-C -C-

The starting raw materials for polyesters are ethylene glycol and dim-ethyl terephthalate (DMT). In some processes terephthalic acid (TPA) is used in lieu of DMT), the DMT is melted with glycol and an ester interchange takes place.

The glycol ester is then polymerized through poly-condensation to polyethylene terephthalate. Molten polymer is extruded through stainless steel spinnerets to form filaments.      Each filament is approximately .024 mm in diameter. The filaments are cooled finish is applied and they are combined into a yarn. The polyester yarn is then drawn to the desired orientation and crystalline. After drawing the yarn is beamed for shipment.

Polyester tire yarn is available in four deniers: yarn yarn yarn and yarn. There are eight polyester tire yarn producers: Allied Chemical Beau-nit DuPont Fiber Industries Firestone Goodyear, IRC Fibers and Monsanto.

Fiberglass: Considerable effort was expended by the tire industry since the thirties to develop fiberglass as a tire cord material. Fiberglass was introduced commercially into tire belts in .

Fiberglass is an inorganic fiber. The fiberglass currently being used for tire cord is E-glass. A typical composition of glass for tire cord is as follows:

Silicon dioxide 53% Calcium oxide 21 Aluminum oxide 15 Boron oxide 9 Magnesium oxide 0.3 other oxides 1.7

Thus fiberglass is a lime-alumina-borosilicate glass consisting of a three-dimensional silica network containing oxides.

Continuous filament fiberglass is manufactured as follows:  Sand clay limestone and borax are fed from raw material hoppers into a blender. After blending the mix moves to a direct gas-fired furnace for melting. The molten glass at deg F is gravity fed through a platinum rhodium bushing where strands of continuous glass filaments are attenuated or drawn. Filament diameters are approximately .009 mm. The filaments are then solidified by a water quench. Next a coupling agent and forming size (binder) is applied to the surface of the glass filaments as the strand passes to a high-speed take-up.

Fiberglass for tires is impregnated by the fiberglass manufacturers before shipment to a fabric mill. Fiberglass is used in tires in the form of a strand with low twist and is not normally twisted into a cord structure.

Fiberglass is produced in three text sizes: 330 strand 460 strands and 660 strands. Tex is a metric system to replace the use of denier. Tex is equal to denier divided by nine. That is text is the number of grams per meters of yarn. There are two producers of fiberglass for tires in the USA. These are Owens Corning Fiberglas and PPG Industries.

Wire: Wire has been used in tires in this country since . The usage has been small but consistent. Recently wire has gained wide interest in all types of tires. Like fiberglass wire is an inorganic material.

Wire manufacture begins with 6.35-mm-diameter high-carbon steel rods. Typical specification for the steel for tire cord is as follows:

Carbon .7% Manganese .5 Silicon .3 Chromium .05 max Copper .02 max Sulfur .03 max Phosphorus .03 max

The rod is cleaned in acid bath rinsed and lime coated. Next the rod is drawn to reduce the diameter from 6.35 mm to 2 mm. The wire is then heat treated (called patenting) to change the grain structure. Further drawing reduces the diameter to .80 mm. The wire is then further heat treated and brass plated. Brass weight is about 7 gm per kg of steel. The brass composition is typically 70 percent copper and 30 percent zinc. The brass plating enhances the adhesion of wire cord to rubber and facilitates drawing to fine diameters. The brass plated wire is drawn to a final diameter in the range of .20 mm. Drawing is accomplished with tungsten carbide and diamond dies. The drawn wire filaments are then combined to form a strand. Several strands are combined to obtain the final wire tire cord.

In some cases an additional filament is spirally wrapped around the entire cord structure. This spiral wrap (a) resists compressive forces when the tire enters the footprint (b) improves cord tension uniformity (c) enhances mechanical adhesion (d) prevents flaring of the strands when cut and (e) reduces cord liveliness for better factory handling.

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The nomenclature for this wire tire cord is described as:

3 + 5 x 7 x .20 + 1 x .20

That is the cord is composed of a core containing one bundle of three filaments of .20 mm gauge. The core is surrounded by five strands each containing seven filaments of .20 mm gauge. The entire structure is surrounded by a wrap of one filament of .20 mm gauge.

The generalized equation (2) is:

Core + intermediate part + outermost part + wrap

SxFxD+SxFxD +SxFxD + FxD (2)

Where

S = number of strands (when S = 1 it may be omitted)
F = number of filaments in each strand
D = diameter of filaments (millimeters)

In general the cord description starts with the innermost section and proceeds outward. Each layer is separated with a plus (+) sign. If the diameter is the same for two or more components the diameter is omitted except for the last component. If a strand is a single filament the numerical designation is omitted.

Quite complex cord structures can be assembled. Wire cords for passenger tire belts generally contain from 3 to 10 filaments. Large tires utilize wire cords with up to 50 filaments. In large earthmover tires one ply of steel can replace up to 40 plies of conventional textile.

The only producer of wire tire cord in the USA is National Standard. Much of the wire tire cord used in the USA is imported. Monsanto has an experimental program underway to spin steel fibers from the molten state using in-viscid technology.

Other Cords: A new tire cord material receiving wide attention is Fiber B. Fiber B is a fully aromatic continuous filament organic fiber produced by DuPont. Fiber B is characterized by extremely high strength and modulus.

Tire Cord Characteristics

Characterization of tire cords has become sophisticated in recent years. Analysis has been undertaken from a mechanical chemical thermal and energy basis.

Tire Cord Usage Pattern

This chart tabulates usage by type of tire (bias radial bias/belted) and application (passenger truck off-the-road farm and aircraft).

An asterisk indicates the predominant fiber used in each line of tire. This table indicates that tire technology is a specific engineering of different textiles for various types of tires. Note that the elastic organic fibers such as nylon are not generally used in belts. On the other hand inorganic fibers such as wire are not used in the carcass of bias or bias/belted tires.

Tire Cord Characteristics

STRENGTH ELASTICITY BIREFRINGENCE ELONGATION ORIENTATION THERMAL ANALYSIS MODULUS SHRINKAGE FORCE MOISTURE REGAIN YIELD POINT IR ANALYSIS HELIX ANGLE DENIER SOLVATION FINISH COMPOSITION TWIST STRESS DECAY ELASTIC MODULUS ADHESION LOOP STRENGTH COEFFICIENT OF IMPACT RESISTANCE COMPRESSIBILITY RETRACTION CREEP CONSTRUCTION STORAGE MODULUS LASE BRITTLE POINT COMPLEX MODULUS (E* COMPLIANCE SPECIFIC HEAT DYNAMIC ADHESION INTRINSIC VISCOSITY STIFFNESS BREAKING LENGTH DIP PICKUP DURABILITY TOUGHNESS RESILIENCE HEAT RESISTANCE FINISH CONTENT GROWTH LOSS TANGENT ABRASION RESISTANCE POISSON’S RATIO STRAIN TENSILE STRENGTH HYSTERESIS FATIGUE MELTING POINT THERMAL WORK-TO-BREAK RESERVOIR CONDUCTIVITY STABILITY DIFFUSION LOSS MODULUS INCH-STRENGTH DYNAMIC MODULUS INTERNAL FRICTION GAUGE DIP PENETRATION RESONANCE FREQUENCY SPECIFIC GRAVITY DAMPING S-O-T TEMPERATURE ELASTIC LIMIT HYDROLYSIS SOUND TRANSMISSION STRESS TEX HEAT GENERATION UNIFORMITY TORSIONAL MODULUS BRUSH CRYSTALLINITY SOFTENING POINT PLATING WET STRENGTH ENTROPY OF FUSION LAY SHRINKAGE STAINING FLARE HOT LOAD TENACITY WILDNESS FLATSPOTTING OXIDATION STRAIGHTNESS SONIC MODULUS CATENARY

USA Tire Cord Usage Pattern

TIRE TYPE BIAS RADIAL BIAS/BELTED Carcass Belt Carcass Belt Passenger Rayon Rayon’ Rayon Rayon Rayon Nylon Polyester Wire* Nylon Fiberglass* Polyester’ Polyester* Wire Truck Nylon* Polyester Wire* Nylon* Fiberglass* Polyester Wire* Polyester Wire Off-the-road Nylon* Wire* Wire* Nylon “ Wire* Polyester Farm Rayon Nylon* Polyester indicates predominant fiber used in USA. Aircraft Nylon*

Additional statistics used in conjunction with Table permit a complete understanding of the tires produced in the USA. The figures are given below:

Tire Cord (All Tires)

Rayon 15% Nylon 42 Polyester 32 Fiberglass 6 Wire 5

Tire Type (All Tires)

Bias 50% Radial 10 Bias/Belted 40 Tire Application 78% Passenger 13 Truck and off-the-road 2 Farm Aircraft <1 Other 6

Projection of Tire Reinforcing Materials

More than one billion pounds of tire cord are used throughout the world each year. About half is used in the USA.

Tire cord consumption can be characterized by individual life cycles. It should be noted that tire cord usage has been characterized by a rising peaking and declining pattern. In only cotton was used in tires. Cotton passed through stages of growth maturity and decline finally phasing out completely. Rayon was introduced in and is in Stage V (decline) today. Nylon was commercialized in and is now in Stage IV (maturity). Polyester is in Stage III (growth). Similar cycles can be constructed for fiberglass and wire cord. Analyzing sub-cycle trends is important. A study of the tire cord sub-cycle indicates that a new fiber will be introduced before .

Share the Knowledge

In the field of textile and industrial materials, nylon (polyamide) and polyester (polyester) are two major representatives of synthetic fibers. Although they have common characteristics such as high strength, wear resistance and easy processing, they have significant differences in molecular structure, hygroscopicity, thermal stability and application scenarios. Nylon has become the first choice for sports equipment and industrial parts due to its excellent elasticity and wear resistance, while polyester dominates the daily clothing and home textile market with its excellent wrinkle resistance and low cost. This article will deeply analyze the chemical composition, physical properties and applicable fields of the two to help readers make accurate judgments when choosing materials.

What is Nylon?

Nylon is a generic nomination for a family of synthetic polymers. It is composed of polyamides i.e., repeating units linked by amide links. It is a thermoplastic and very silky material that can be melt and processed into fibres, films, or shapes. Nylon polymers can frequently be mixed with a broad variety of additives to achieve many different property variations.

What are the types of nylon?

Nylon is divided into several categories according to its chemical structure. The common ones are:

Type Chemical composition Features Typical applications Nylon 6 (PA6) Caprolactam polymerization Good elasticity, easy processing, strong hygroscopicity Textile fibers, fishing nets, packaging films Nylon 66 (PA66) Hexamethylenediamine + adipic acid polymerization  High strength, high temperature resistance, excellent mechanical properties Auto parts, industrial gears, bulletproof vests Nylon 610 (PA610) Hexamethylenediamine + sebacic acid polymerization Oil resistance, chemical corrosion resistance Precision mechanical parts, cable sheaths Nylon (PA) Decanediamine + sebacic acid polymerization  Low hygroscopicity, good dimensional stability High-end engineering plastics, 3D printing materials Aromatic nylon (such as PA6T, PA9T) Contains benzene ring structure  Ultra-high heat resistance (>300℃)  Aerospace, electronic packaging

What are the characteristics of nylon?

The main characteristics of nylon are:

1. High strength: tougher than natural fibers (such as cotton and wool), with excellent tensile resistance.
2. Abrasion resistance: low friction coefficient, suitable for making parts with frequent friction (such as gears and ropes).
3. Good elasticity: can return to its original shape after stretching, not easy to deform.
4. Chemical resistance: has certain resistance to oil, alkali and weak acid, but strong acid will corrode nylon.
5. Hygroscopicity: nylon 6 has a moisture absorption rate of about 4.5%, and nylon 66 has a moisture absorption rate of about 2.5%, which affects dimensional stability.
6. Not resistant to high temperature: the melting point of ordinary nylon is about 215-265℃, and it is easy to age under long-term high temperature.
7. Easy to static electricity: static electricity is easy to accumulate in a dry environment, and antistatic treatment is required.

What are the advantages and disadvantages of nylon?

✔ Advantages

• Lightweight and strong: The specific strength (strength/weight ratio) is higher than that of metal, suitable for replacing some metal parts.
• Good processing performance: It can be formed by various methods such as injection molding, extrusion, spinning, etc.
• Fatigue resistance: It is not easy to break after repeated bending, suitable for sports equipment (such as climbing ropes).
• Good dyeability: It can be dyed with acid dyes and has bright colors.

✖ Disadvantages

• Degradation of performance after moisture absorption: The strength decreases after water absorption, and the size may change.
• Ultraviolet sensitivity: It is easy to turn yellow and brittle after long-term exposure to the sun, and anti-UV agents need to be added.
• High cost: Compared with polyester, nylon raw materials and processing costs are higher.

What are the uses of nylon?

Clothing: Nylon is a common apparel option, especially in sportswear. Nylon is regarded as the best choice for sportswear for its high strength, excellent water resistance, good elasticity and wear resistance.

 Car parts: In automotive parts, nylon is widely used for its excellent strength and good heat resistance. Such as plastic skeleton materials, it is the most basic and the most widely used material for manufacturing automobile parts. Nylon is often applied to the engine cover, fuel pipe, and parts of the dashboard.

 Gear wheels:In gear manufacturing, nylon synthetic materials are widely used because of their low friction coefficient and excellent wear resistance.

Bearings: Nylon bearings are very common in a variety of application scenarios because of their low friction force and excellent wear resistance.

 Fixtures: Nylon fixtures are very common during manufacturing and assembly because of their excellent durability, scratch resistance, and collision resistance.

Engineering plastics: In the field of engineering plastics, nylon, as a synthetic material, is widely used in the manufacturing of engineering plastics because of its excellent strength, flexibility, high temperature resistance and convenience of processing.

What is polyester?

Polyester (polyester fiber, Polyester), chemical name polyethylene terephthalate (PET), is the world's largest synthetic fiber, accounting for more than 70% of the total output of synthetic fibers. It is made by polycondensation of terephthalic acid (PTA) and ethylene glycol (EG), and has the characteristics of high strength, wrinkle resistance, chemical corrosion resistance, etc., and is widely used in clothing, home textiles, industry and other fields.

What are the types of polyester?

Polyester can be divided into many types according to its use and performance characteristics:

Type  Features Typical applications PET (conventional polyester) High strength, low moisture absorption, easy to dye  Clothing, bottle flakes, packaging film PCDT (high elastic polyester) Elasticity is better than PET, good rebound  Sportswear, underwear, stretch fabrics Recycled polyester (rPET)  Made from recycled plastic bottles, environmentally friendly Sustainable clothing, shoes, backpacks Cationic dyeable polyester Can be dyed with cationic dyes, bright colors  High-end fashion, home textile fabrics Flame retardant polyester Add flame retardants, high temperature resistance Fire suits, curtains, car interiors

What are the characteristics of polyester?

The main characteristics of polyester are:

1. High strength: high breaking strength, stretch resistance, not easy to tear.
2. Good wrinkle resistance: strong fiber rigidity, not easy to deform after washing, no ironing required.
3. Chemical corrosion resistance: acid, alkali, solvent resistant, suitable for industrial use.
4. Low moisture absorption: moisture regain is only 0.4%, quick drying, but easy to generate static electricity.
5. Good light resistance: better UV resistance than nylon, suitable for outdoor use.
6. Poor air permeability: low moisture absorption, stuffy wearing, need to be improved by blending.
7. Easy to pilling: the fiber surface is smooth and easy to pilling after friction.

What are the advantages and disadvantages of polyester?

✔ Advantages

• Low cost: cheap raw materials, high economic efficiency of large-scale production.
• Easy care: no deformation after machine washing, fast drying, suitable for fast fashion clothing.
• Strong weather resistance: UV resistance, oxidation resistance, suitable for outdoor textiles.
• Recyclable: recycled polyester (rPET) is environmentally friendly and reduces plastic pollution.

✖ Disadvantages

• Poor comfort: weak moisture absorption and perspiration ability, hot and stuffy in summer.
• Flammable: flame retardants need to be added to be used for fireproof materials.
• Difficult to degrade: traditional polyester takes hundreds of years to degrade naturally, and environmental pressure is high.

What are the uses of polyester?

(1) Clothing industry

• Daily clothing: T-shirts, shirts, jackets (wrinkle-resistant, easy to care for).
• Sportswear: blended with cotton to improve moisture absorption, used in sportswear, yoga pants.

(2) Home textile products

• Bedding: quilt covers, sheets (wrinkle-resistant, durable).
• Curtain & sofa fabrics: sun-resistant, not easy to fade.

(3) Industrial applications

• Tire cord: high-strength polyester is used to strengthen tires.
• Conveyor belts & industrial filter cloths: corrosion-resistant, wear-resistant.

(4) Packaging materials

• PET plastic bottles: beverage bottles, cooking oil bottles (transparent, lightweight).
• Packaging film: food cling film, insulation film.

(5) Environmentally friendly materials

• Recycled polyester (rPET): recycled plastic bottles are made into environmentally friendly shoes, clothing, and backpacks.

Nylon vs. Polyester: Differences and Similarities

In the field of textile and industrial materials, nylon and polyester are the most common synthetic fibers, each occupying an important position. LS will deeply analyze the differences and similarities of the characteristics of these two materials to help you make wise decisions when purchasing materials.

1. Comparison of core differences
(1)Chemical structure and raw materials

• Nylon (polyamide): contains amide bonds (-NH-CO-) in the molecular chain, and is formed by the condensation of diamine and dibasic acid
• Polyester (polyester): contains ester bonds (-CO-O-) in the molecular chain, and is made by the polymerization of terephthalic acid and ethylene glycol

(2)Physical properties

Features  Nylon  Polyester Hygroscopicity 4.5%（high） 0.4%（very low） Strength 4.2-5.8g/d 4.5-6.5g/d Abrasion resistance Excellent ( times)  Good ( times) Elastic recovery rate 98% 90% Melting point 215-265℃ 260℃ Light resistance Poor (easy to yellow) Excellent

(3) Processing characteristics

• Dyeing: Nylon requires acid dyes (100°C), polyester requires disperse dyes (130°C)
• Setting: Polyester requires higher temperatures (180-200°C vs nylon 160°C)
• Antistatic: Polyester is more prone to static electricity and requires special treatment

2. Main similarities

Commonalities of synthetic fibers:

• High strength-to-weight ratio (3-5 times that of natural fibers)
• Resistant to microbial corrosion and not prone to mildew
• Controllable costs for large-scale production

Versatile modification technologies:

All can be achieved through copolymerization, nanocomposites, etc.:

• Antibacterial treatment (silver ions/copper ions)
• Flame retardant modification (phosphorus/nitrogen flame retardants)
• Conductive function (carbon nanotubes/graphene doping)

Recycling methods:

• Mechanical recycling: melt regranulation
• Chemical recycling: depolymerization to monomers and repolymerization

3. Material selection decision guide

Scenarios where nylon is preferred:

• Requires high elasticity (sportswear, swimsuits)
• High wear resistance requirements (climbing ropes, gears)
• Wet environment (quick-drying clothing)

Scenarios where polyester is preferred:

• Large-scale production with limited budget
• Requires wrinkle resistance and ironing resistance (formal shirts)
• Outdoor weather-resistant products (awnings, advertising fabrics)

Mixed application solutions:

• 65% polyester + 35% nylon: balance between cost and performance
• Nylon outer layer + polyester inner layer: common structure of outdoor clothing

5. Comparison of environmental performance

1. Difficulty of recycling: Polyester is easier to recycle
2. Degradability: Both are difficult to degrade naturally
3. Sustainable development:

• Nylon: Develop bio-based nylon
• Polyester: Promote recycled polyester (rPET)

Summary

As the two leaders in the field of synthetic fibers, nylon and polyester each exhibit unique performance advantages: nylon has become the first choice for high-performance applications due to its excellent elasticity, wear resistance and comfort, while polyester dominates the daily consumer goods market with its excellent wrinkle resistance, heat resistance and economy. Both are far superior to natural fibers in terms of strength, durability and easy care, but due to differences in molecular structure, they have their own characteristics in terms of moisture absorption, weather resistance and touch.

In actual applications, there is no absolute distinction between good and bad. The key is to make accurate choices based on specific needs, whether it is the pursuit of high elasticity in sports equipment, high strength in industrial parts, wrinkle resistance and shape retention in daily clothing, or sustainability of environmentally friendly products. With the advancement of material technology, innovative products such as modified nylon and recycled polyester are constantly expanding the application boundaries of both, providing consumers with more choices.