Plastics engineering
Plastics engineering encompasses the processing, design, development, and manufacture of plastics products. A plastic is a polymeric material that is in a semi-liquid state, having the property of plasticity and exhibiting flow. Plastics engineering encompasses plastics material and plastic machinery. Plastic Machinery is the general term for all types of machinery and devices used in the plastics processing industry.[1] The nature of plastic materials poses unique challenges to an engineer. Mechanical properties of plastics are often difficult to quantify, and the plastics engineer has to design a product that meets certain specifications while keeping costs to a minimum. Other properties that the plastics engineer has to address include: outdoor weatherability, thermal properties such as upper use temperature, electrical properties, barrier properties, and resistance to chemical attack.
In plastics engineering, as in most engineering disciplines, the economics of a product plays an important role. The cost of plastic materials ranges from the cheapest commodity plastics used in mass-produced consumer products to the very expensive, specialty plastics. The cost of a plastic product is measured in different ways, and the absolute cost of a plastic material is difficult to ascertain. Cost is often measured in price per pound of material, or price per unit volume of material. In many cases however, it is important for a product to meet certain specifications, and cost could then be measured in price per unit of a property. Price with respect to processibility is often important, as some materials need to be processed at very high temperatures, increasing the amount of cooling time a part needs. In a large production run cooling time is very expensive.
Some plastics are manufactured from re-cycled materials but their use in engineering tends to be limited because the consistency of formulation and their physical properties tend to be less consistent. Electrical and electronic equipment and motor vehicle markets together accounted for 58 percent of engineered plastics demand in 2003. Engineered plastics demand in the US was estimated at $9,702 million in 2007.
A big challenge for plastics engineers is the reduction of the ecological footprints of their products. First attempts like the Vinyloop process can guarantee that a product's primary energy demand is 46 percent lower than conventional produced PVC. The global warming potential is 39 percent lower. [2]
Plastics engineering specialties
- Consumer Plastics
- Medical plastics
- Automotive plastics
- Recycled or recyclable plastics
- Biodegradable plastics
- Elastomers / rubber
- Epoxys
- Plastics processing: injection moulding, plastics extrusion, stretch-blow molding, thermoforming, compression molding, calendering, transfer molding, laminating, fiberglass molding, pultrusion, filament winding, vacuum forming, rotational molding
- Ultrasonic welding
See also
- Design of plastic components
- Economics of plastics processing
- Plastic
- Polymer chemistry
- Fields of engineering
- Engineering plastic
- Medical grade silicone
References
- ↑ Introduction of Plastics Engineering. PlASTICEXTRUDERMACHINE.COM
- ↑ http://www.solvayplastics.com/sites/solvayplastics/SiteCollectionDocuments/VinyLoop/The%20VinyLoop%20Eco-Footprint%20Study.pdf
External links
- University of Wisconsin – Stout – Plastics Engineering
- Plastics and Elastomers
- Umass Lowell Plastics Department Website
- Ferris State University Plastics Engineering Technology Department
- Society of Plastics Engineers
- Pittsburg State University Plastics Engineering Technology Website
- Penn State Behrend Plastics Engineering Technology Website
- Pennsylvania College of Technology Plastics and Polymer Engineering Technology Website
- Western Washington University Plastics Engineering Website
- Polymers Center of Excellence, Training and Testing of Polymers Website