Calculating stress in plastics by conventional methods does not even go close to working reliably long term in plastics for several reasons, these being:-
1) Thermoplastic creep. Plastics flow under load. The rate they flow at and variations of that rate during a single test depends on several characteristics that vary by polymer and compound. Level of crystallinity and nature of crystal structure and length and shape of the molecule are key factors. Basically without writing a novel, the flow slows a lot as all the molecules pull into parallel formation.
2) Some plastics, especially if reinforced with fibres are quite anisotropic and this needs consideration.
3) Section thickness when moulded can play an important role as it strongly influences crystal structure and orientation of fiberous fillers.
4) Variations from surface layer effect. The surface molecules may well be amorphous, even in a highly crystalline plastic as the surface is cooled rapidly but the core cools slowly as plastics are good insulators, The surface layer molecules may themselves be oriented, creating oriented linear rather than spherical or random orientation laminar crystals.
5) Surface notches, even microscopic ones from any machining process play a much stronger part in failure than they do in metals.
6) Temperatures within a relatively narrow range within the extremes of some ambient temperatures can have a significant role.
7) Rate of application of load also plays a significant part.
Regards
Pat
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