Polymers have an important role in manufacturing and their engineering properties form an important part of any course in engineering. This revised and updated second edition develops the principles of polymer engineering from the underlying materials science, and is aimed at undergraduate and postgraduate students in engineering and materials science. The opening chapters explain why plastics and rubbers have such distinctive properties and how these are affected by temperature, strainrate, and other factors. The book then explores how these properties can be exploited within these property constraints to produce functional components. Major changes for this second edition include an introductory chapter on the environmental impact of polymers, emphasizing the important issues, and substantially revised sections on fracture testing for toughened polymers, yield, processing, heat transfer, and polymer forming.700 600 500 Energy lthanl 31.. o 1:: As 200 lOC 0 0.7 Energy requirements to produce metal alloys and plastics. ... as much as 27 kg of crude oil equivalent, taking into account the significant stamping waste that has to be recycled. The same bonnet in polymer composite requires 16 kg of crude oil equivalent because of its lower mass, negligible trimming waste, energy-conserving forming process andanbsp;...
|Title||:||Principles of Polymer Engineering|
|Author||:||N. G. McCrum, C. P. Buckley, C. B. Bucknall|
|Publisher||:||Oxford University Press, USA - 1997-01-01|