Does Texturing of UHMWPE Increase Strength and Toughness?: A Pilot Study

Self Cite

A new processing route for producing ultrahigh molecular weight polyethylene (UHMWPE) nanocomposite combining swelling in toluene, microextrusion, and compression-molding was developed. Using this novel method, extruded neat UHMWPE (e-PE), and extruded UHMWPE blended with 0.5 wt % of graphite nanoplatelets (e-PE/g) were processed. UHMWPE was also processed by compression-molding (PE) as reference material. Bulk mechanical behavior of the materials was evaluated by tensile, bending and impact tests, while surface mechanical behavior was assessed by scratch and sliding wear experiments. We found that e-PE/g has a brittle tensile behavior in comparison with the two other grades. Bending and impact toughness increase in this order: PE % e-PE/g < e-PE. Scratch behavior of the materials is quite similar, e-PE has however the lowest friction coefficient, and hence, exhibits antifriction properties. The cumulative sliding energy increases in this Periodicals, Inc. J Appl Polym Sci 125: 4316-4325, 2012

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Impact of microextrusion and addition of graphite nanoplatelets on bulk and surface mechanical properties of UHMWPE

Delgado-Rangel¹,

Addiego²,

Eddoumy³

et al. 2012

Self Cite

“…The stress relief annealing is applied at the end of most of those methods to form the polyethylene structure and properties. It reduces the anisotropy of properties and removing a substantial part of free radicals stabilizes polyethylene from chemical point of view (oxidation resistance) …”

Section: Introductionmentioning

confidence: 99%

The influence of electron beam irradiation, plastic deformation, and re‐irradiation on crystallinity degree, mechanical and sclerometric properties of GUR 1050 used for arthroplasty

Barylski

Maszybrocka

Kupka

et al. 2016

The article describes the influence of an electron beam irradiation (I), plastic deformation (D), and re-irradiation (R) on the properties of ultrahigh molecular weight polyethylene (GUR 1050). It was found that the modification through irradiation entailed a gradual increase in the degree of crystallinity (after irradiation-I). After plastic deformation and re-irradiation (IDR) the degree of crystallinity decreases which had a direct influence on the mechanical properties. The polymer irradiation only (technique I) resulted in an increase in the maximum stress as compared with the material in the initial state. The application of deformation and re-irradiation (technique IDR) allowed increasing the deformation resistance by more than 40%. Moreover, the irradiation with an electron beam resulted in the increase in hardness (H) and Young's modulus (E) proportionally to the applied irradiation dose and in the reduction of total indentation work (W tot ) and its components. After deformation and re-irradiation the polyethylene hardness went down. The application of technique (I) caused an improvement to the material abrasion resistance (reduction of parameter PD-working scratch depth) with the increasing irradiation dose. The introduction of deformation and re-irradiation did not have a material impact on parameter (PD) increasing at the same time elastic properties of UHMWPE (increase in parameter NPS-elastic recovery). Modification IDR has changed the wear mechanism (b) toward ploughing and has increased the abrasionresistance index (W b ) and also significantly reduced the coefficient of friction (l) of GUR 1050. V C 2016 Wiley Periodicals, Inc. J. Appl.Polym. Sci. 2016, 133, 43683.

“…In the majority of methods applied to alter the PE structure and properties, posttreatment annealing is additionally used to stabilize the structure. It reduces the residual stresses and anisotropy of properties and chemically stabilizes PE (in terms of oxidation resistance) by the recombination of a significant fraction of free radicals 10–13. However, such a posttreatment annealing is sometimes omitted 14…”

Section: Introductionmentioning

confidence: 99%

“…In the case of a modified material demonstrating a preferred orientation and anisotropic properties, the location of the sample, especially the orientation of the working surface of the acetabular cup of the endoprosthesis with respect to the direction of that orientation, is of utmost importance. An increase in the resistance to wear by 3–5 times is frequently observed in such systems but only when the plane of the tribological interaction is parallel to the direction of the prior deformation, whereas the direction of movement/sliding is preferentially perpendicular to that deformation direction 11–14. Marrs et al12 suggested, however, that such a significant improvement in the tribological properties can be achieved only in the case of a bidirectional or multidirectional movement during the interaction with a smooth surface of the CoCr counterspecimen.…”

Section: Introductionmentioning

confidence: 99%

Properties of ultra‐high‐molecular‐weight polyethylene with a structure modified by plastic deformation and electron‐beam irradiation

Cybo

Maszybrocka

Duda

et al. 2012

To improve the functional properties of polyethylene in a polymer-metal kinematic system, ultrahigh-molecular-weight polyethylene (UHMWPE) was subjected to light deformation by uniaxial compression [permanent true strain (e f ) ¼ 0.14-0.32] and postdeformation electron-beam irradiation (with a dose of 26-52 kGy). X-ray examinations demonstrated that no significant reorientation of the lamellar structure occurred upon compression. The textures of all of the samples, except for the sample deformed at e f ¼ 0.32, were nearly random. In the exception, a very weak axial texture developed. However, the treatment applied (deformation and electron-beam irradiation) significantly changed the structure of the material. A considerable increase in the crosslinked fraction and the crystalline band absorption in the Fourier transform infrared spectra were observed in the modified samples. This indicated a noticeable increase in the degree of spatial ordering within a structure, although the overall crystallinity increased only slightly. The effect of such restructuring was evidenced by microscopic observations of the near-surface layer of the UHMWPE samples subjected to unidirectional sliding interaction with a CoCr alloy for 100 h (in a block-ring tribological system). It was found that for the predeformed (e f ¼ 0.14-0.21) and electron-irradiated (dose of 52 kGy) samples, the operational load imposed on the system resulted in a considerable reduction in the thickness of the plastically deformed near-surface layer and in a decreasing amount of lamellae oriented flat-on compared to the neat unmodified UHMWPE subjected to the same test. The recorded tribological wear (mass decrement) decreased up to fivefold in comparison to that of the initial material.