Finite element modeling and experimental validation of single-asperity sliding friction of diamond against reinforced and non-filled polycarbonate

S. Krop, H.E.H. Meijer, L.C.A. van Breemen

Onderzoeksoutput: Bijdrage aan tijdschriftTijdschriftartikelAcademicpeer review

9 Citaties (Scopus)

Uittreksel

Polymer composites used as protective coatings are important, tribology-critical applications. In this study, hard or soft particle-filled model systems with a polycarbonate matrix are tested in single asperity sliding friction tests against diamond tips. A numerical approach developed to simulate scratching on unfilled polycarbonate was adapted by computing the effective material parameters for the hard and soft particle filled systems using representative volume elements. Combining this proper constitutive framework with a rate-independent friction model correlated quantitatively with the results of the current scratching experiments.
TaalEngels
Pagina's77-85
TijdschriftWear
Volume356-357
DOI's
StatusGepubliceerd - 15 jun 2016

Vingerafdruk

polycarbonate
sliding friction
Diamond
polycarbonates
Polycarbonates
Diamonds
diamonds
Friction
tribology
protective coatings
Tribology
Protective coatings
Polymers
friction
composite materials
Composite materials
polymers
matrices
Experiments

Citeer dit

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abstract = "Polymer composites used as protective coatings are important, tribology-critical applications. In this study, hard or soft particle-filled model systems with a polycarbonate matrix are tested in single asperity sliding friction tests against diamond tips. A numerical approach developed to simulate scratching on unfilled polycarbonate was adapted by computing the effective material parameters for the hard and soft particle filled systems using representative volume elements. Combining this proper constitutive framework with a rate-independent friction model correlated quantitatively with the results of the current scratching experiments.",
author = "S. Krop and H.E.H. Meijer and {van Breemen}, L.C.A.",
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Finite element modeling and experimental validation of single-asperity sliding friction of diamond against reinforced and non-filled polycarbonate. / Krop, S.; Meijer, H.E.H.; van Breemen, L.C.A.

In: Wear, Vol. 356-357, 15.06.2016, blz. 77-85.

Onderzoeksoutput: Bijdrage aan tijdschriftTijdschriftartikelAcademicpeer review

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AU - Krop,S.

AU - Meijer,H.E.H.

AU - van Breemen,L.C.A.

PY - 2016/6/15

Y1 - 2016/6/15

N2 - Polymer composites used as protective coatings are important, tribology-critical applications. In this study, hard or soft particle-filled model systems with a polycarbonate matrix are tested in single asperity sliding friction tests against diamond tips. A numerical approach developed to simulate scratching on unfilled polycarbonate was adapted by computing the effective material parameters for the hard and soft particle filled systems using representative volume elements. Combining this proper constitutive framework with a rate-independent friction model correlated quantitatively with the results of the current scratching experiments.

AB - Polymer composites used as protective coatings are important, tribology-critical applications. In this study, hard or soft particle-filled model systems with a polycarbonate matrix are tested in single asperity sliding friction tests against diamond tips. A numerical approach developed to simulate scratching on unfilled polycarbonate was adapted by computing the effective material parameters for the hard and soft particle filled systems using representative volume elements. Combining this proper constitutive framework with a rate-independent friction model correlated quantitatively with the results of the current scratching experiments.

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M3 - Article

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