Structural Analysis of Thermoplastic Components
by: Gerry Trantina, Ron Nimmer
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Topics include: notched polycarbonate, nominal density reduction, polycarbonate beam, puncture disk, maximum hydrostatic stress, load displacement behavior, effective tensile modulus, neck propagation, crosshead displacement, gated plaques, polycarbonate disk, hysteretic heating, ductile thermoplastics, apparent fracture toughness, effective bending modulus, necking process, whitened zone, craze initiation, local modulus, modified polyphenylene ether, orthotropic elasticity, part stiffness, hardening modulus, unfilled thermoplastics, stiffness predictions
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First Sentence:
Engineering design requires both mechanical properties to define material behavior adequately and accurate analysis techniques to predict generic part performance based on those data.
Designfax,
"This comprehensive guide allows readers to improve their engineering design analysis skills. It offers specific analysis techniques, detailed discussions of mechanical behavior and the latest structural design techniques. It Includes a general discussion of finite element analysis with special emphasis on geometric and meterial nonlinearities. In addition, there are numerous examples that illustrate how well thermoplastic behavior can be predicted"
Book Description
How to predict thermoplastics behavior in high-performance structural applications Here's the very first engineering resource with all the data and design/analysis techniques you need to work with even the newest thermoplastics. Structural Analysis of Thermoplastic Components by Gerry Trantina and Ron Nimmer shows you how to predict stiffness, creep and fatigue of polymeric components--PLUS non-homogeneous materials such as structural foams and composites. You'll benefit from detailed comparisons of analytic prediction versus measured behavior and much more: Nonstandard property measurement and analysis; Nonlinearities associated with large deformations; Using structural geometry to offset low material stiffness; Designing thermoplastics to withstand impacts; Important loading variables, component lifetimes, frequency effects, hysteric heating and cyclic crack growth.
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