Engineering Plastics

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Engineering plastics

Engineering plastics are a group of plastic materials that have better mechanical and/or thermal properties than the more widely used commodity plastics (such as polystyrene, PVC, polypropylene and polyethylene).  Being more expensive, engineering plastics are produced in lower quantities and tend to be used for smaller objects or low-volume applications (such as mechanical parts), rather than for bulk and high-volume ends (like containers and packaging).  

The term usually refers to thermoplastic materials rather than thermosetting ones. Examples of engineering plastics include acrylonitrile butadiene styrene (ABS), used for car bumpers, dashboard trim and Lego bricks; polycarbonates, used in motorcycle helmets; and polyamides (nylons), used for skis and ski boots.  Engineering plastics have gradually replaced traditional engineering materials such as wood or Metal in many applications. Besides equalling or surpassing them in weight/strength and other properties, engineering plastics are much easier to manufacture, especially in complicated shapes.

Acrylonitrile butadiene styrene

Acrylonitrile Butadiene Styrene (ABS) is an opaque thermoplastic and amorphous polymer. “Thermoplastic” (as opposed to “thermoset”) has to do with the way the material responds to heat. Thermoplastics become liquid (i.e. have a “glass transition”) at a certain temperature (221 degrees Fahrenheit in the case of ABS plastic). They can be heated to their melting point, cooled, and re-heated again without significant degradation. Instead of burning, thermoplastics like ABS liquefy which allows them to be easily injection molded and then subsequently recycled. By contrast, thermoset plastics can only be heated once (typically during the injection molding process). The first heating causes thermoset materials to set (similar to a 2-part epoxy), resulting in a chemical change that cannot be reversed. If you tried to heat a thermoset plastic to a high temperature a second time it would simply burn. This characteristic makes thermoset materials poor candidates for recycling. ABS is also an amorphous material meaning that it does not exhibit the ordered characteristics of crystalline solids.

ABS is most commonly polymerized through the process of emulsion (the mixture of multiple products that don’t typically combine into a single product). A well known example of an emulsified product is milk. ABS is also created, albeit less commonly, by a patented process known as continuous mass polymerization. Globally, the most common methodology to create ABS is the emulsion process.

ABS has a strong resistance to corrosive chemicals and/or physical impacts. It is very easy to machine and has a low melting temperature making it particularly simple to use in injection molding manufacturing processes or 3D printing on an FDM machine. ABS is also relatively inexpensive (prices, currently around $1.50 per pound, typically fall somewhere between those of Polypropylene  (“PP”) and Polycarbonate (“PC”). ABS plastic is not typically used in high heat situations due to its low melting point.  All of these characteristics lead to ABS being used in a large number of applications across a wide range of industries.

Polycarbonates

Polycarbonate is a dimensionally stable, transparent thermoplastic with a structure that allows for outstanding impact resistance. With high-performance properties, Polycarbonate is the leading plastic material for various applications that demand high functioning temperatures and safety features. Because of its durable make-up, polycarbonate is often the preferred thermoplastic over materials like PMMA and Acrylic. Polycarbonates are unique in its working temperatures and ability to experience minimal degradation between heating and cooling points. Polycarbonate features a high working temperature of 266 degrees Fahrenheit and cooling temperatures at -40 degrees Fahrenheit.

Features of polycarbonate

PC is a good material of choice in Industry due to its versatile characteristics, eco-friendly processing and recyclability. They have the unique set of chemical and physical properties making them suitable over glass, PMMA, PE, etc.  

 

Toughness and High Impact Strength

Polycarbonate has high strength that makes it resistant to impact and fracture and hence provides safety and comfort in application demanding high reliability & performance. They are virtually unbreakable.  

Transmittance

PC is an extremely clear plastic and can transmit over 90% of Light as good as glass. PC sheets are available in a wide range of shades which can be customized depending on the end-user application.

Lightweight

The benefits allows provides OEMs virtually unlimited possibilities for design compared with glass. The property allows increased efficiency, makes installation process easier and reduces overall transportation costs.  

Protection from UV Radiations

Polycarbonates can be designed to block ultraviolet radiation and provide 100% protection from the sun’s harmful UV rays.   Optical Nature – Thanks to its amorphous structure, PC offers excellent optical properties. Refractive index of clear polycarbonate is 1.584.  

Chemical Resistance

Polycarbonate exhibits good chemical resistance against diluted acids, aliphatic hydrocarbons and alcohols; moderate chemical resistance against oils and greases. PC is readily attacked by diluted alkalis, aromatic and halogenated hydrocarbons. Manufacturers recommend to clean PC sheets with certain cleaning agents which do not affect its chemical nature. It is sensitive to abrasive alkaline cleaners.  

 

 

Heat Resistance

Polycarbonates offers good heat resistance and are thermally stable upto 135°C. Further heat resistance can be improved by adding flame retardants without impacting material properties.

Applications of polycarbonates

Popular uses of polycarbonate can include aircraft parts, data storage devices, dome lights, eye protection, multiwall sheets, electronic components and more. Due to polycarbonates ability to withstand extreme temperatures for prolonged periods of time, it is often used in components for various industries, including:

  • Aircrafts and Aerospace Components
  • Greenhouses and agriculture
  • Industrial Lighting
  • Electronic Components
  • Automotive Components
  • Machinery Guards

 


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Engineering plastics are a class of polymers that are used in a wide variety of applications, from consumer goods to industrial equipment. They are characterized by their strength, durability, and resistance to heat and chemicals.

There are many different types of engineering plastics, each with its own unique properties. Some of the most common types include:

  • Acrylonitrile Butadiene Styrene (ABS): ABS is a strong, tough plastic that is often used in automotive parts, appliances, and toys.
  • Acetal: Acetal is a rigid, high-performance plastic that is used in bearings, gears, and other applications where strength and durability are important.
  • Acrylic: Acrylic is a clear, lightweight plastic that is used in windows, lenses, and other applications where transparency is important.
  • Cellulose Acetate: Cellulose acetate is a strong, lightweight plastic that is used in furniture, packaging, and other applications where durability and low weight are important.
  • Epoxy: Epoxy is a strong, durable plastic that is used in adhesives, coatings, and other applications where strength and resistance to chemicals are important.
  • Fluoropolymers: Fluoropolymers are a family of plastics that are characterized by their resistance to heat, chemicals, and wear. They are used in a wide variety of applications, including gaskets, seals, and bearings.
  • High-Density Polyethylene (HDPE): HDPE is a strong, durable plastic that is used in bottles, pipes, and other applications where strength and resistance to chemicals are important.
  • Low-Density Polyethylene (LDPE): LDPE is a lightweight, flexible plastic that is used in bags, films, and other applications where low weight and flexibility are important.
  • Nylon: Nylon is a strong, tough plastic that is used in gears, bearings, and other applications where strength and durability are important.
  • Polycarbonate: Polycarbonate is a strong, transparent plastic that is used in windows, lenses, and other applications where strength and transparency are important.
  • Polyethylene Terephthalate (PET): PET is a strong, lightweight plastic that is used in bottles, food packaging, and other applications where strength and low weight are important.
  • Polypropylene: Polypropylene is a strong, lightweight plastic that is used in bottles, films, and other applications where strength and low weight are important.
  • Polystyrene: Polystyrene is a lightweight, rigid plastic that is used in packaging, insulation, and other applications where low weight and rigidity are important.
  • Polyurethane: Polyurethane is a strong, flexible plastic that is used in foams, elastomers, and other applications where strength and flexibility are important.
  • PVC: PVC is a strong, durable plastic that is used in pipes, fittings, and other applications where strength and resistance to chemicals are important.
  • Silicone: Silicone is a strong, flexible plastic that is used in gaskets, seals, and other applications where strength and resistance to heat and chemicals are important.
  • Thermoplastic Elastomers (TPEs): TPEs are a family of plastics that combine the properties of rubber and plastic. They are used in a wide variety of applications, including footwear, automotive parts, and medical devices.
  • Thermosetting Plastics: Thermosetting plastics are a family of plastics that cure and harden when heated. They are used in a wide variety of applications, including electrical components, cookware, and furniture.

Engineering plastics are an essential part of our modern world. They are used in everything from cars and computers to toys and appliances. Their strength, durability, and resistance to heat and chemicals make them ideal for a wide variety of applications.

What is the difference between engineering plastics and commodity plastics?

Engineering plastics are a type of plastic that is designed to withstand high temperatures, chemicals, and other environmental stresses. They are often used in applications where traditional plastics would not be suitable, such as in the aerospace, automotive, and medical industries. Commodity plastics, on the other hand, are less expensive and less durable than engineering plastics. They are often used in applications where cost is a primary concern, such as in packaging and disposable products.

What are the most common types of engineering plastics?

The most common types of engineering plastics include:

  • Acrylonitrile butadiene styrene (ABS)
  • Polyamide (PA)
  • Polycarbonate (PC)
  • Polyethylene terephthalate (PET)
  • Polypropylene (PP)
  • Polystyrene (PS)
  • Polytetrafluoroethylene (PTFE)

What are the advantages of using engineering plastics?

Engineering plastics offer a number of advantages over traditional plastics, including:

  • Increased strength and durability
  • Resistance to high temperatures, chemicals, and other environmental stresses
  • Ability to be molded into complex shapes
  • Low weight
  • Low cost

What are the disadvantages of using engineering plastics?

Engineering plastics also have some disadvantages, including:

  • They can be more difficult to machine than traditional plastics
  • They can be more expensive than traditional plastics
  • They can be more difficult to recycle than traditional plastics

What are some applications for engineering plastics?

Engineering plastics are used in a wide variety of applications, including:

  • Aerospace
  • Automotive
  • Medical
  • Electronics
  • Packaging
  • Consumer goods

What is the future of engineering plastics?

The future of engineering plastics is bright. The demand for engineering plastics is expected to grow significantly in the coming years, driven by the increasing demand for lightweight, durable, and recyclable materials. New developments in engineering plastics technology are also expected to lead to the development of new and innovative applications for these materials.

  1. Which of the following is not a type of engineering plastic?
    (A) Polyethylene
    (B) Polypropylene
    (C) Polystyrene
    (D) Polycarbonate

  2. Which of the following is the most common type of engineering plastic?
    (A) Polyethylene
    (B) Polypropylene
    (C) Polystyrene
    (D) Polycarbonate

  3. Engineering plastics are used in a variety of applications, including:
    (A) Cars
    (B) Computers
    (C) Electronics
    (D) All of the above

  4. Engineering plastics are typically stronger and more durable than traditional plastics.
    (A) True
    (B) False

  5. Engineering plastics are typically more expensive than traditional plastics.
    (A) True
    (B) False

  6. Engineering plastics are typically more difficult to recycle than traditional plastics.
    (A) True
    (B) False

  7. Which of the following is a property of engineering plastics that makes them ideal for use in cars?
    (A) Strength
    (B) Durability
    (C) Heat resistance
    (D) All of the above

  8. Which of the following is a property of engineering plastics that makes them ideal for use in computers?
    (A) Strength
    (B) Durability
    (C) Electrical insulation
    (D) All of the above

  9. Which of the following is a property of engineering plastics that makes them ideal for use in electronics?
    (A) Strength
    (B) Durability
    (C) Electrical insulation
    (D) All of the above

  10. Which of the following is a disadvantage of engineering plastics?
    (A) They are more expensive than traditional plastics.
    (B) They are more difficult to recycle than traditional plastics.
    (C) They are not as biodegradable as traditional plastics.
    (D) All of the above