The plastic deformation of ultra-high molecular weight polyethylene

Hutten, PF van; Koning, CE Cor; Pennings, A. J.

doi:10.1007/bf00555260

Cited by 36 publications

(16 citation statements)

References 27 publications

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“…While some microfibrils are measured as small as 16 nm and greater than 90 nm, over 70 percent of the fibrils measured are between 20 and 40 nm. These dimensions, consistent with similar measurements via SEM in the literature [43], correlate quite well with the crystallite dimensions calculated from WAXD measurements. This suggests that the majority of microfibrils are arrays of single crystals linked in series.…”

Section: Surface Morphology Of Highly Drawn S130supporting

confidence: 87%

Structural hierarchy and surface morphology of highly drawn ultra high molecular weight polyethylene fibers studied by atomic force microscopy and wide angle X-ray diffraction

McDaniel

Deitzel

Gillespie

2015

Polymer

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Section: Surface Morphology Of Highly Drawn S130supporting

confidence: 87%

Structural hierarchy and surface morphology of highly drawn ultra high molecular weight polyethylene fibers studied by atomic force microscopy and wide angle X-ray diffraction

McDaniel

Deitzel

Gillespie

2015

Polymer

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“…melt-spinning or fibres prepared from semi-dilute polymer solutions) and the process variables, as extensively described in the literature [27,29,[30][31][32][33][34][35]. During cold-drawing the lamellar structures are transformed into fibrillar structures by rotation/translation of (parts of) lamellae and/or by local melting of the lamellae due to local high stress concentrations.…”

Section: Resultsmentioning

confidence: 99%

Gel-spun polyethylene fibres

et al. 1988

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In addition to spinning temperature, spinline stretching and spinning speed, the properties of gel-spun polyethylene fibres hot-drawn to the maximum draw ratio also depend on the polymer concentration, molecular weight and molecular weight distribution. Reducing the polymer concentration reduces the number of entanglements, and fibres with better properties are obtained. However, a minimum number of entanglements is necessary to ensure sufficient coherence of the entanglement network and avoid premature breakage of the spinline. Therefore, an optimal concentration exists which is shown to shift to a lower value for polyethylene with a smaller molecular weight distribution. Fibres with a tensile strength exceeding 6 GPa and a modulus of about 160GPa can be prepared as long as spinline stretching is avoided. A smaller molecular weight distribution enhances the deteriorating effect of spinline stretching. The difference in morphologies for as-spun fibres prepared from different gel compositions and under different spinning conditions also strongly affects the cold-drawing behaviour of the extracted as-spun fibres.

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“…Hot-drawing was possible up to a maximum hot-draw ratio of 80 and this resulted in a fiber with a tensile strength of 3.55 GPa. SEM and SAXS studies of the hot-drawing process of these gel-spun fibers revealed that for high hot-draw ratios the lamellar structure was transformed into a fibrillar structure [32,33]. Hot-drawing to lowdraw ratios resulted in a decrease of the crystallinity and a shift of the peak melting temperature Tm to somewhat lower temperatures due to a recrystallization of the lamellar material into less perfect crystals, due to fast cooling of the thin hot-drawn fibers.…”

Section: Melting Behavior Of Extracted Gel-~pun Polyethylene Fibersmentioning

confidence: 98%

DSC experiments on gel-spun polyethylene fibers

Hoogsteen

Pennings

Brinke

1988

Colloid & Polymer Sci

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The tensile strength of gel-spun polyethylene fibers obtained after hot-drawing depends on spinning conditions such as spinning speed, spinning temperature, spinline stretching, polymer concentration, and molecular weight/molecular weight distribution. High deformation rates in the spinline result in shish-kebab structures which after hotdrawing lead to fibers with poor properties. This is in contrast to hot-drawn fibers obtained from gel-spun fibers with a lamellar structure. Lamellar or shish-kebab structures in the gel-spun fibers can be distinguished by means of DSC experiments on strained fibers. On the basis of these experiments a qualitative prediction of the final tensile properties can be made. DSC experiments on (un)strained hot-drawn fibers show that in the case of shish-kebab structures an incomplete transformation into a fibrillar structure takes place which partly explains the low tensile strength. Chain slippage which becomes possible after the orthorhombic-hexagonal phase transition is involved in the fracture mechanism. The shift of the orthorhombic-hexagonal phase transition to higher temperatures with increasing tensile strength indicates that the increase in strength corresponds to an increase in length of the crystal blocks. Consequently, creep failure also occurs at higher stresses. The melting behavior of cold-drawn and hot-drawn fibers is qualitatively similar, but the transformation into a fibrillar structure is more complete in the latter case.

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The plastic deformation of ultra-high molecular weight polyethylene

Cited by 36 publications

References 27 publications

Structural hierarchy and surface morphology of highly drawn ultra high molecular weight polyethylene fibers studied by atomic force microscopy and wide angle X-ray diffraction

Structural hierarchy and surface morphology of highly drawn ultra high molecular weight polyethylene fibers studied by atomic force microscopy and wide angle X-ray diffraction

Gel-spun polyethylene fibres

DSC experiments on gel-spun polyethylene fibers

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