Abstract
In the last decades the necessity of implant devices is continuously increasing. The researchers have thus focused their attentions on the development of new biocompatible materials, in particular polymers. Among them, polyetheretherketone (PEEK) has gained wide interest in load-bearing applications such as spinal cages due to its yielding behavior and its superior corrosion resistance. Since such applications are characterized by notches and other stress concentrators weakening the implant resistance, a design tool for assessing their tensile and fatigue behavior in the presence of such discontinuities is highly claimed. To this aim, tensile and fatigue data available in literature of neat and differently notched PEEK samples (circumferentially cracked and U-notched specimens with different notch radii) experimentally tested in a phosphate-buffered saline (PBS) at 37 °C have been analyzed using the strain energy density (SED) approach. The method is shown to provide accurate results regardless of the different notch geometries, both for tensile and fatigue data. Concerning the former, the tensile strength was in fact estimated with an error lower than ±10%, regardless of the strain rate, while for the latter the SED approach was able to summarize the fatigue data with a single narrow scatter band independently from the notch geometry
Highlights
I n recent years, the need of surgical procedures, and the necessity of implant devices, have continuously increased [1]
Concerning the tensile assessment, the notch stress intensity factors (NSIFs) approach predict the failure of a component comparing the NSIF at which the implant is subjected with a reference strength value obtained by testing samples weakened by the same notch geometry
The strain energy density (SED) approach has revealed in the past to greatly predict both the tensile and fatigue behavior of metals, weakened by different notch geometries
Summary
I n recent years, the need of surgical procedures, and the necessity of implant devices, have continuously increased [1]. Concerning the tensile assessment, the NSIF approach predict the failure of a component comparing the NSIF at which the implant is subjected with a reference strength value obtained by testing samples weakened by the same notch geometry.
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