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Di Methyl Terephthalate (DMT)
Di Methyl Terephthalate (DMT)

ThermoPlastic Elastomer

Thermoplastic elastomers (TPE) are a unique combination of properties of both plastics and rubber. These materials have both the flexibility and elasticity of rubber and the thermal processability of plastics. This unique combination has made TPEs one of the most popular materials in various industries.

TPE are typically composed of two or more polymers linked together in a block or branched structure. This structure allows them to have both elastomeric and thermoplastic properties.

Applications of TPEs

TPEs are used in a variety of industries due to their unique properties, including:

Automotive industry: Interior parts of cars such as gear levers, seat covers, and under-hood parts.

Medical industry: Medical gloves, medical tubing, and other medical equipment.

Sports industry: Athletic shoes, balls, and other sports equipment.

Packaging: Flexible packaging, airbags, and protective packaging.

Home use: Home appliances, toys, and other consumer products.

Electronic industry: Protective coverings for cables and electronic components.

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ThermoPlastic Elastomer

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درجه بطری

Bottle Grade

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Polyethylene Terephthalate (PET) is a versatile thermoplastic polymer widely used in the packaging industry, particularly for bottle manufacturing. PET bottle-grade resin is a specialized type of PET formulated to meet the requirements of beverage, food, and pharmaceutical packaging. One of the key advantages of PET bottle-grade material is its food-safe quality, ensuring compliance with global regulatory standards like those set by the FDA (Food and Drug Administration) and EFSA (European Food Safety Authority). With growing concerns about sustainability, PET bottle-grade materials are evolving to incorporate higher percentages of recycled content while maintaining their structural integrity and safety. 
1.Structure
PET (Polyethylene Terephthalate) is a semi-crystalline thermoplastic polymer belonging to the polyester family. The structure of PET bottle-grade material is based on long-chain polymer molecules formed through polycondensation of terephthalic acid (TPA) and ethylene glycol (EG). The repeating unit in PET is: {-O-CH_2-CH_2-O-CO-C_6H_4-CO-} This structure consists of:
  • Ester groups (-COO-) → Provide flexibility and durability
  • Benzene rings (C₆H₄) → Contribute to rigidity and strength
  • Ether bonds (-O-) → Help in processability and thermal stability
2.Properties
PET (Polyethylene Terephthalate) bottle-grade resin possesses a unique combination of physical, mechanical, thermal, chemical, and barrier properties, making it the preferred material for beverage and food packaging. It is highly transparent, lightweight, and has a smooth surface, providing an attractive and glossy finish for bottles. Mechanically, PET is strong, tough, and resistant to impact and stress-cracking, ensuring durability during handling and transportation. Its flexibility allows easy molding into various bottle shapes while maintaining high stiffness for structural integrity. Thermally, PET has a glass transition temperature of approximately 75–80°C and a melting point of around 250–265°C, making it stable under moderate heat conditions. Chemically, it exhibits excellent resistance to acids, oils, and solvents while maintaining hydrolytic stability in humid environments. Additionally, PET is non-toxic and food-safe, meeting regulatory standards such as those set by the FDA and EFSA. Its superior barrier properties help preserve the quality of packaged products by limiting oxygen and carbon dioxide permeability and preventing moisture absorption.A key advantage of PET bottle-grade material is its recyclability, as it is 100% recyclable and can be processed into recycled PET (rPET), promoting sustainability and reducing environmental impact. These properties collectively make PET an ideal choice for water bottles, soft drink containers, juice packaging, and other consumer goods that require clarity, strength, and food safety. 
3. Applications of Bottle Grade PET
Bottle-grade PET is used across multiple industries due to its versatility and safety.

1. Food & Beverage Industry

Soft Drink & Water Bottles – Carbonated and non-carbonated beverages Dairy & Juice Containers – Milk, yogurt drinks, and fresh juices Edible Oil & Condiment Packaging – Cooking oils, sauces, and vinegar

2 Pharmaceutical & Healthcare

Medicine Bottles – Liquid syrups and vitamin supplements Personal Care Packaging – Shampoo, lotion, and cosmetic containers

3 Industrial & Chemical Applications

Household & Industrial Chemicals – Detergents, cleaning agents, and solvents Laboratory Containers – Sterile packaging for chemicals and reagents

4 Sustainable Packaging & Recycled PET Products

Recycled PET Bottles – Used in textiles, automotive parts, and reusable packaging Eco-Friendly Packaging – Biodegradable and sustainable bottle solutions 
4. Advantages of Bottle Grade PET
Bottle-grade PET offers multiple benefits, making it the preferred material for packaging. Cost-Effective: Lower production costs compared to glass and metal Shatterproof & Durable: Reduces breakage risks in transportation and usage Lightweight: Decreases shipping weight and carbon footprint Versatile & Moldable: Easily shaped into different bottle designs Safe for Food Contact: Approved by FDA and EFSA for direct food and beverage use Eco-Friendly: Supports recycling and sustainable initiatives 
5. Disadvantages of Bottle Grade PET
Despite its benefits, bottle-grade PET has some drawbacks: Environmental Concerns: Improper disposal leads to plastic pollution Heat Sensitivity: Deforms at high temperatures, limiting hot-fill applications Gas Permeability: Less effective than glass in preventing oxygen ingress Chemical Leaching (Low Risk): May release trace amounts of antimony oxide under extreme conditions Recycling Challenges: Requires advanced sorting and processing to maintain quality
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Injection Molding

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In injection molding, polymer granules are compressed by a ram or screw, heated until molten and squirted into a cold, split mold under pressure (Figure 26.3(b)). The molded polymer is cooled below TG, the mold opens and the product is ejected. Excess polymer is injected to compensate for contraction in the mold. The molecules are oriented parallel to the flow direction during injection, giving useful strengthening, but properties that are anisotropic. The process gives high-precision moldings, because the polymer cools with the pressure still on but is slow (the cycle time is between 1 and 5 min), and the molds are expensive. Typically, molding temperatures for thermoplastics are between 150 and 350 °C (1.3 and 1.6 TG) and the pressures needed to give good detail are high—typically 30–120 MN m−2. 
Types of injection molding
Gas-Assisted Injection Molding This process involves injecting gas (commonly nitrogen) into the molten polymer during molding. The gas pushes the molten plastic against the mold walls, creating hollow sections or reducing the amount of material used. Thin-Wall Injection Molding This method Focuses on producing parts with very thin walls, typically less than 1 mm. This requires specialized molds and machines capable of handling high pressures and fast cycle times. Liquid Silicone Rubber (LSR) Injection Molding This method is Used exclusively for liquid silicone rubber (LSR), a thermosetting material that cures when heated. LSR is injected into a heated mold, where it solidifies into a flexible and durable part. Structural Foam Molding A process where a foaming agent or gas is added to the polymer to create parts with a cellular core and solid outer skin. This reduces density and weight while maintaining strength. Metal Injection Molding (MIM) A process that combines metal powders with a polymer binder to create a feedstock. The feedstock is injected into a mold, then the binder is removed, and the part is sintered to achieve a dense metal component. 
Advantages of injection molding
  • Injection molding is incredibly cost-effective, especially in high-volume applications where thousands to tens of thousands of parts are printed in a workday.
  • Injection molding offers many different materials, both general use, and specialty.
  • Injection molding provides immense design freedom to product developers and is only held back by mold design, material specifications, and cost.
  • Injection-molded parts can be as small as a grain of rice (or smaller) or can be as large as a car dashboard, depending upon the specific type of injection molding being used.
  • Injection molding can produce highly complex parts that would otherwise be too time-consuming or difficult to produce with traditional subtractive manufacturing methods.
  • Injection molding is a low/no waste manufacturing method, and waste can typically be 100% recycled and reground into stock material for a new injection mold.
Disadvantages of injection molding
  • High initial tooling and equipment costs.
  • Long lead times for mold design and production.
  • Material limitations and risk of defects.
  • Environmental and sustainability concerns.
  • Design constraints requiring engineering expertise.
  • Best suited for high-volume production.
Applications of injection molding
Plastic injection molding is used throughout industry as a means of manufacturing plastic parts in high volumes. Its applications are theoretically endless given the various types of injection molding available combined with its popularity. Still, there are some core usages for which the injection molding process particularly excels. Examples of injection molding applications include (but are not limited to):
  • Automotive components
  • Food and Beverage packaging
  • Stock materials (spools, bar, tube, etc.)
  • Toys and figurines
  • Furniture components
  • Fixtures and fasteners
  • Mechanical components (gears, valves, pumps, linkages, etc.)
  • Electronic hardware and housings
  • Medical device components
  • General plastic parts
 
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پلی اتیلن با چگالی کم خطی

Linear Low Density Polyethylene (LLDPE)

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LLDPE stands for Linear Low-Density Polyethylene. It is a type of polyethylene (a polymer made from ethylene monomers) that has short, linear branches in its molecular structure. This structure gives LLDPE unique properties compared to LDPE (Low-Density Polyethylene) and HDPE (High-Density Polyethylene). 
Structure
LLDPE has a unique linear molecular structure with short, controlled branches. This structure is different from LDPE (Low-Density Polyethylene), which has long and irregular branches. LLDPE consists of ethylene monomers (–CH₂–CH₂–) linked in a linear fashion. It has short, uniform side branches created by copolymerizing ethylene with α-olefins (like butene, hexene, or octene).These branches prevent the polymer chains from packing too tightly, giving LLDPE low density and flexibility. 
Properties
LLDPE (Linear Low-Density Polyethylene) is a versatile thermoplastic polymer known for its excellent flexibility, high impact resistance, and good tensile strength. it is slightly denser than LDPE but less rigid than HDPE, making it ideal for applications requiring toughness and stretchability. It has a high elongation at break (>500%), allowing it to withstand significant stretching without tearing. LLDPE exhibits excellent chemical resistance against acids, bases, and alcohols while maintaining low water absorption, making it suitable for moisture-sensitive applications. Thermally, it has a melting point of approximately 110–125°C and remains functional between -50°C and 60°C. Though it lacks inherent UV resistance, stabilizers can be added to improve durability under sunlight. Its ease of processing through extrusion, blow molding, and film manufacturing makes it widely used in plastic films, flexible tubing, cable insulation, and various molded products. While lldpe is non-biodegradable, it is recyclable, contributing to sustainable material management. 
Applications of Linear Low-Density Polyethylene (LLDPE)
  • Packaging Industry:
    • Stretch films and shrink wraps
    • Plastic bags (grocery, trash, and industrial)
    • Food packaging films (cling wraps, pouches)
  • Agricultural Sector:
    • Greenhouse films and mulch films
    • Drip irrigation tubing and water storage tanks
  • Industrial Applications:
    • Pipes and fittings (flexible and durable)
    • Cable insulation and protective coatings
    • Industrial liners (chemical and water-resistant)
  • Automotive Industry:
    • Fuel tanks and hoses
    • Interior soft components and protective covers
  • Consumer & Household Products:
    • Toys, containers, and household items
    • Soft-touch grips and molded parts
  • Medical & Pharmaceutical:
    • Medical tubing and IV bags
    • Sterile packaging films
Advantages of LLDPE
  • Higher Flexibility and Toughness:
    • More impact-resistant than LDPE
    • Maintains durability even at low temperatures
  • Excellent Chemical and Moisture Resistance:
    • Resistant to acids, bases, and solvents
    • Waterproof and corrosion-resistant
  • Good Processability
  • Lightweight and Cost-Effective
  • Better Puncture and Tear Resistance:
    • Ideal for thin film applications like stretch wraps
Disadvantages of LLDPE 
  • Lower Heat Resistance:
    • Softens and deforms at high temperatures
    • Not suitable for high-temperature applications
  • Poor UV Stability:
    • Requires UV stabilizers for outdoor use, or it degrades over time
  • Lower Stiffness Compared to HDPE:
    • Less rigid, making it unsuitable for structural applications
  • Limited Gas Barrier Properties:
    • Not ideal for gas-tight packaging applications
  • Difficult to Process in Some Applications:
    • Requires higher processing temperatures compared to LDPE
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پلی اتیلن با چگالی کم

Low Density PolyEthylene (LDPE)

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LDPE film LDPE film grade is divided into several types, including general-purpose film, high-transparency film, heavy-duty film, shrink film, and cast film. These materials possess superior physical and mechanical properties, along with high chemical stability and excellent electrical insulation. They also feature low water vapor permeability and outstanding processability, making them ideal for various applications. Films made from these resins provide exceptional clarity and strong resistance to aging, ensuring durability and long-lasting performance. 
Structure
LDPE (Low-Density Polyethylene) film grade is a thermoplastic polymer made from ethylene monomers (C₂H₄) through a high-pressure polymerization process. Its molecular structure is characterized by high branching, which gives it its unique properties. Key Structural Features: Highly Branched Polymer:
  • LDPE has short-chain and long-chain branches, preventing tight packing of polymer chains.
Amorphous & Semi-Crystalline Structure:
  • Due to branching, LDPE has low crystallinity (~40–50%), making it soft and transparent.
  • It is more flexible and stretchable than HDPE (High-Density Polyethylene).
Low Molecular Weight Distribution:
  • LDPE has a broad molecular weight distribution, contributing to good melt strength and processability in film extrusion.
Properties
Low-Density Polyethylene (LDPE) film grade is a highly flexible and lightweight material known for its excellent elongation, impact resistance, and transparency. With a density ranging from 0.915 to 0.930 g/cm³, it offers good clarity but can appear slightly hazy. It has a relatively low melting point of around 105–115°C and remains flexible even at sub-zero temperatures, making it suitable for various applications. LDPE exhibits moderate tensile strength (8–17 MPa) and exceptional elongation at break (100–600%), ensuring durability and resilience. While it provides a good moisture barrier, its gas barrier properties are poor, allowing oxygen and CO₂ to pass through. Chemically, LDPE resists acids, bases, and alcohols but is vulnerable to hydrocarbons. Its excellent heat-sealing properties make it ideal for packaging applications, including food wrap, shrink films, and shopping bags. Additionally, it is widely used in agricultural films, protective industrial films, and medical applications such as IV bags and tubing. LDPE is typically processed through blown or cast film extrusion, operating within a temperature range of 160–220°C. However, due to its susceptibility to UV degradation, stabilizers are often added for outdoor applications. Overall, LDPE film grade is a versatile and cost-effective material, valued for its flexibility, sealability, and ease of processing. 
Applications
  • Packaging
    • Used for manufacturing flexible packaging films (e.g., shopping bags, wraps, and pouches).
    • Food packaging, including wraps, freezer bags, and shrink films.
    • Industrial packaging for wrapping materials, products, and protective covers.
  • Agricultural Use
    • Greenhouse films for agricultural purposes, creating protective environments for plants.
    • Mulch films for soil coverage and weed control.
  • Consumer Products
    • Plastic bags for grocery stores, retail packaging, and garbage bags.
    • Cling films for food preservation and covering items.
    • Disposable liners for various containers.
  • Construction
    • Vapor barriers in buildings, preventing moisture from seeping into structures.
    • Covers for construction materials during storage or transportation.
  • Medical Use
    • Sterile packaging for medical devices, equipment, and pharmaceuticals.
    • Medical drapes and covers.
Advantages
  • Flexibility
    • LDPE film is highly flexible and can be stretched without breaking.
  • Transparency
    • Offers high clarity and transparency, making it ideal for packaging.
  • Chemical Resistance
    • Good resistance to chemicals, oils, and greases.
  • Low Cost
    • Relatively affordable material, making it a cost-effective solution for many applications.
  • Ease of Processing
    • Easy to process with methods like extrusion, injection molding, and blow molding.
  • Lightweight
    • Lightweight material, reducing transportation and handling costs.
  • Moisture Resistance
    • Water-resistant properties, providing good moisture protection in packaging.
Disadvantages
  • Low Strength
    • Low tensile strength and can tear easily under stress or load.
  • Limited Heat Resistance
    • Has a low melting point, which limits its use in high-temperature environments.
  • Environmental Impact
    • Non-biodegradable and contributes to plastic pollution if not recycled properly.
  • Poor UV Resistance
    • Can degrade when exposed to UV light, leading to brittleness and color fading over time.
  • Low Barrier Properties
    • Not ideal for barrier applications like gas or vapor resistance compared to other materials like BOPP or PET.
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پلی آریل اتر کتون (PAEK)

PolyArylEtherKetone (PAEK)

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PolyArylEtherKetone (PAEK) is a family of high-performance, semi-crystalline thermoplastics known for their excellent mechanical properties, thermal stability, and chemical resistance. These polymers contain aromatic rings connected by ether (-O-) and ketone (-CO-) linkages, which contribute to their strength and durability. 
Structure
The structure of PolyArylEtherKetone (PAEK) consists of a repeating backbone of aromatic rings (aryl groups) connected by ether (-O-) and ketone (-CO-) linkages. These alternating ether and ketone groups provide a unique combination of flexibility and rigidity, contributing to the polymer's high thermal stability, chemical resistance, and mechanical strength. The presence of aromatic rings enhances structural integrity, making the polymer highly resistant to degradation under extreme conditions. The ether linkages add flexibility to the molecular chain, improving processability, while the ketone groups increase the polymer’s resistance to heat and oxidation. The semi-crystalline nature of PAEK arises from the ability of the polymer chains to pack efficiently in an ordered manner, leading to excellent wear resistance and high mechanical performance. Different types of PAEK, such as PEEK, PEK, and PEKK, vary in the arrangement and proportion of these functional groups, influencing their thermal and mechanical properties. This unique molecular structure makes PAEK an ideal choice for high-performance applications in aerospace, medical, automotive, and industrial sectors. 
Properties
PolyArylEtherKetone (PAEK) is a high-performance, semi-crystalline thermoplastic known for its exceptional mechanical, thermal, and chemical properties. It exhibits excellent strength, stiffness, and wear resistance, making it ideal for demanding applications in aerospace, automotive, medical, and oil and gas industries. PAEK has outstanding thermal stability, withstanding continuous use temperatures of up to 250°C, while also demonstrating remarkable resistance to chemicals, including acids, bases, and organic solvents. It possesses low moisture absorption, ensuring dimensional stability even in humid environments. Furthermore, PAEK offers excellent fatigue resistance, making it suitable for long-term load-bearing applications. Its inherent flame retardancy and low smoke emission enhance safety in high-temperature environments. Additionally, PAEK maintains excellent electrical insulation properties, making it valuable for electronic and electrical applications. These unique characteristics make PAEK an advanced material choice for extreme engineering conditions. 
Applications of PolyArylEtherKetone (PAEK):
  • Aerospace & Automotive: Used in structural components, bearings, and bushings due to its lightweight, high strength, and temperature resistance.
  • Medical Devices: Ideal for implants, surgical instruments, and dental components due to biocompatibility and sterilization resistance.
  • Oil & Gas Industry: Used in seals, valves, and insulators for its excellent chemical and high-temperature resistance.
  • Electronics & Electrical: Utilized in connectors, insulators, and semiconductor manufacturing for its electrical insulation and heat resistance.
  • Industrial & Manufacturing: Used in gears, pumps, and wear-resistant parts due to its high mechanical strength and low friction.
Advantages of PolyArylEtherKetone (PAEK):
  • High Thermal Stability: Can withstand continuous temperatures up to 250°C.
  • Excellent Mechanical Properties: High strength, stiffness, and impact resistance.
  • Chemical Resistance: Withstands harsh chemicals, acids, and solvents.
  • Low Moisture Absorption: Ensures dimensional stability in humid environments.
  • Good Wear & Fatigue Resistance: Ideal for long-term, high-load applications.
  • Flame Retardant & Low Smoke Emission: Enhances safety in high-temperature applications.
  • Biocompatibility: Suitable for medical implants and surgical devices.
Disadvantages of PolyArylEtherKetone (PAEK):
  • High Cost: More expensive than conventional plastics and some high-performance polymers.
  • Difficult Processing: Requires high temperatures and specialized equipment for manufacturing.
  • Limited Availability: Not as widely produced as other engineering plastics, leading to supply constraints.
  • Brittleness at Low Temperatures: Can become less impact-resistant in extreme cold conditions.
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کوپلیمرهای بلوک استایرنیک (TPS)
کوپلیمرهای بلوک استایرنیک (TPS)

Styrenic Block Copolymers (TPS)

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Styrenic Block Copolymers (TPS) are a class of thermoplastic elastomers (TPEs) composed of alternating hard and soft polymer segments. The hard segments are made of polystyrene (PS), while the soft segments consist of rubber-like elastomers such as polybutadiene (PB) or polyisoprene (PI). This structure gives TPS materials the elasticity of rubber while maintaining the easy processability of thermoplastics. 
Structure
Styrenic block copolymers (TPS) have a phase-separated structure composed of alternating hard and soft polymer segments. The hard segments consist of polystyrene (PS) domains, which provide strength, rigidity, and thermal stability, while the soft segments are made of elastomeric materials such as polybutadiene (PB), polyisoprene (PI), or ethylene-butylene (EB), contributing to flexibility and elasticity. These block copolymers form a physical crosslinking network where the polystyrene blocks aggregate into discrete domains, acting as physical anchors that hold the material together, while the rubbery segments remain continuous and provide elasticity. This unique morphology allows TPS materials to behave like thermoset elastomers at room temperature but soften and flow when heated, making them fully thermoplastic and easily reprocessable. The phase separation between the polystyrene and elastomeric segments gives TPS its characteristic combination of strength, flexibility, and processability, making it widely used in applications requiring both durability and soft-touch properties. 
Properties
Styrenic block copolymers (TPS) exhibit a unique combination of elasticity, strength, and processability due to their phase-separated structure. They have excellent flexibility and rubber-like elasticity, allowing them to stretch and recover their shape without permanent deformation. Their mechanical properties include good tensile strength and impact resistance, making them durable for various applications. TPS materials have moderate heat resistance, generally performing well below 100°C, and are resistant to many oils, greases, and chemicals, enhancing their stability in demanding environments. They also have good adhesion properties, making them suitable for overmolding onto other plastics. Unlike thermoset rubbers, TPS materials are thermoplastic, meaning they can be melted, reshaped, and recycled multiple times, improving manufacturing efficiency and sustainability. They also provide a soft-touch feel, making them ideal for grips, handles, and other ergonomic applications. Additionally, TPS offers good weather resistance, especially in formulations like SEBS, which enhance UV and oxidation stability. These combined properties make TPS widely used in automotive, medical, consumer goods, and adhesive applications. 
Application
  • Automotive Industry:
    • Soft-touch interior components (dashboards, door panels)
    • Seals, gaskets, and vibration dampeners
    • Grip pads and protective coatings
  • Consumer Goods:
    • Handles and grips for tools, toothbrushes, and razors
    • Sports equipment, shoe soles, and protective gear
    • Flexible packaging and stretchable films
  • Medical Applications:
    • Medical tubing and syringe plungers
    • Overmolded soft-touch medical devices
    • Flexible, biocompatible components
  • Adhesives and Sealants:
    • Pressure-sensitive adhesives (PSAs)
    • Hot-melt adhesives for packaging and footwear
  • Electronics & Electrical:
    • Protective casings for devices
    • Wire and cable insulation
Advantages
High Elasticity and Flexibility – Provides rubber-like stretch and softness Good Impact and Tensile Strength – Enhances durability and wear resistance Thermoplastic Nature – Can be easily melted, reshaped, and recycled Soft-Touch Feel – Ideal for ergonomic grips and overmolding Good Adhesion to Various Materials – Suitable for multi-material applications Resistant to Oils, Greases, and Chemicals – Performs well in harsh environments Lightweight – Reduces material costs and improves energy efficiency Good Weather and UV Resistance – Certain formulations (e.g., SEBS) have enhanced outdoor durability Easy Processing – Compatible with injection molding, extrusion, and blow molding 
Disadvantages
Lower Heat Resistance – Limited performance above 100°C Lower Stiffness Compared to Some Plastics – May require reinforcement for structural applications Can Become Sticky in Hot Conditions – Some grades may soften and lose shape retention Higher Cost Than Standard Plastics – More expensive than traditional polyolefins like PP and PE Limited Load-Bearing Capacity – Not suitable for heavy-duty mechanical applications
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Suspension

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Polyvinyl Chloride (PVC) Suspension Grade is one of the most widely used thermoplastic polymers, produced through the suspension polymerization process. This method results in free-flowing, fine particles that can be processed into various products. Suspension PVC (S-PVC) is known for its versatility, chemical resistance, durability, and cost-effectiveness, making it a popular choice in multiple industries. 
Structure
Polyvinyl Chloride (PVC) suspension grade is a thermoplastic polymer produced through the suspension polymerization process. In this method, vinyl chloride monomer (VCM) is dispersed in water with the help of suspending agents and polymerized using free radical initiators. The resulting PVC resin consists of fine, porous, and free-flowing particles with a relatively high molecular weight, making it suitable for a wide range of applications. The polymer structure is primarily composed of repeating vinyl chloride units (–CH₂–CHCl–), forming a linear polymer chain with varying degrees of polymerization. PVC suspension grade is widely used in the manufacturing of pipes, fittings, films, sheets, and rigid as well as flexible products due to its excellent mechanical strength, durability, and chemical resistance. The properties of the resin, such as particle size, porosity, and bulk density, can be adjusted by controlling the polymerization conditions, making it versatile for different industrial applications. 
Properties
PVC suspension grade exhibits a combination of excellent physical, mechanical, and chemical properties, making it highly versatile for industrial applications. It appears as a white, free-flowing powder with a bulk density ranging from 0.45 to 0.65 g/cm³ and a particle size typically between 50-250 microns. Its high porosity allows for better plasticizer absorption, making it suitable for both rigid and flexible products. Mechanically, it offers good tensile strength, typically between 40-60 MPa, and moderate to high impact resistance, which can be enhanced with additives. Chemically, PVC suspension grade is highly resistant to acids, bases, and many chemicals, ensuring durability in harsh environments. It also has low water absorption, which provides excellent dimensional stability. However, it is susceptible to UV degradation, requiring stabilizers for outdoor applications. These properties make PVC suspension grade ideal for manufacturing pipes, profiles, films, and various other rigid and flexible products. 
Applications
  • Construction Industry: Pipes, fittings, window profiles, doors, roofing sheets
  • Packaging Industry: Films, sheets, bottles
  • Automotive Industry: Interior trims, dashboards, wire insulation
  • Medical Sector: Tubing, blood bags, IV containers
  • Electrical Applications: Cable insulation, coatings
Advantages
  • High durability and strength – Ideal for long-term use
  • Excellent chemical resistance – Withstands acids, bases, and oils
  • Cost-effective – Affordable compared to other polymers
  • Low water absorption – Ensures dimensional stability
  • Easily processable – Can be molded, extruded, and shaped easily
  • Customizable – Properties can be modified with additives
Disadvantages
  • UV degradation – Becomes brittle under prolonged sunlight exposure
  • Toxic gas release – Emits harmful gases (HCl) when burned
  • Health concerns – Some plasticizers used in flexible PVC may have risks
  • Not biodegradable – Raises environmental concerns regarding disposal
Limited high-temperature resistance – Can deform under extreme heat
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Thermoplastic Copolyesters (COPE)/(TPEE)

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Thermoplastic Copolyesters (COPE), also known as Thermoplastic Polyester Elastomers (TPEE), are a class of thermoplastic elastomers (TPEs) that combine the mechanical properties of engineering plastics with the elasticity of rubber. They are composed of hard polyester crystalline segments and soft amorphous segments, providing a balance of strength, flexibility, and chemical resistance. 
Properties
Thermoplastic Copolyesters (COPE), also known as Thermoplastic Polyester Elastomers (TPEE), combine the mechanical strength of engineering plastics with the flexibility and resilience of elastomers. They exhibit excellent elasticity, allowing them to return to their original shape after deformation, while also providing high tensile strength and durability. COPE materials offer outstanding chemical and solvent resistance, making them suitable for harsh environments. Their thermal stability enables them to maintain performance across a wide temperature range, with good low-temperature flexibility and resistance to heat aging. Additionally, they possess excellent abrasion resistance, impact strength, and fatigue resistance, ensuring longevity in demanding applications. With easy processability through injection molding, extrusion, and blow molding, COPE is widely used in automotive, industrial, consumer, and medical applications where a balance of toughness, flexibility, and chemical resistance is required. 
Structure
Thermoplastic Copolyesters (COPE), also known as Thermoplastic Polyester Elastomers (TPEE), are a class of high-performance elastomers that combine the characteristics of both thermoplastics and rubbers. Their structure consists of alternating soft and hard segments, where the soft segments are typically made of aliphatic polyether or polyester, providing flexibility and elasticity, while the hard segments are composed of polyester blocks, offering strength, thermal resistance, and durability. This segmented block copolymer structure enables TPEEs to exhibit excellent mechanical properties, such as high tensile strength, impact resistance, and superior fatigue endurance. The presence of ester linkages in the hard phase contributes to chemical resistance and heat stability, while the soft phase ensures flexibility even at low temperatures. Due to this unique molecular architecture, COPEs find applications in various industries, including automotive, consumer goods, electrical components, and medical devices, where both resilience and processability are essential. 
Applications
  • Automotive: Used in air ducts, CVJ boots, bellows, gaskets, and wire coatings due to high heat and chemical resistance.
  • Industrial & Mechanical: Employed in conveyor belts, hoses, seals, and grommets for durability and flexibility.
  • Consumer Goods: Found in footwear soles, sports equipment, and flexible smartphone components for comfort and toughness.
  • Electrical & Electronics: Used in cable insulation, connectors, and protective coatings due to excellent dielectric properties.
  • Medical Devices: Applied in tubing, catheters, and soft-touch grips because of biocompatibility and sterilization resistance.
Advantages
  • High Elasticity & Flexibility: Maintains shape and flexibility even under stress.
  • Excellent Heat Resistance: Performs well at elevated temperatures compared to other TPEs.
  • Superior Mechanical Strength: Offers high tensile strength, impact resistance, and fatigue endurance.
  • Good Chemical Resistance: Resistant to oils, solvents, and many industrial chemicals.
  • Wide Processing Window: Easily processed through injection molding, extrusion, and blow molding.
  • Recyclable: More environmentally friendly than thermoset elastomers.
Disadvantages
  • Higher Cost: More expensive than other thermoplastic elastomers (TPEs).
  • Limited Low-Temperature Flexibility: Can become less flexible at extremely low temperatures compared to TPU.
  • Absorbs Moisture: May require drying before processing to prevent defects.
  • Processing Challenges: Requires precise temperature control during molding and extrusion
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