Solid particle erosion of CVD diamond coatings
Solid particle erosion of CVD diamond coatings
This paper reports solid particle erosion studies of 10–47 ?m chemical vapour deposited (CVD) diamond coatings deposited on W and SiC substrates. Two erosion test facilities were used: a water–sand slurry rig and a high-velocity air–sand rig. The erodent used was silica sand with average diameters of 135 ?m, 194 ?m and 235 ?m with the velocities in the range of 16–268 ms?1 and 90° nominal impingement angle. The erosion rates were plotted against particle kinetic energy and compared with those for cemented tungsten carbide and stainless steel. The samples were examined both pre- and post-test by scanning electron microscopy in order to determine the mechanisms of degradation suffered by the coating during the erosion process; the effects of thickness and microstructure were also examined. The time to failure of the coatings at 268 ms?1 was found to increase from 5 to 185 min over the range of coating thickness tested. The erosion mechanism at high-velocity conditions is thought to be a three-stage process consisting of micro-chipping, development of pin-holes and interfacial debonding, followed by catastrophic failure. However, it should be noted that, at particle velocities of 268 ms?1, 46 ?m CVD diamond coatings on tungsten displayed approximately six times the erosion resistance of cemented tungsten carbide.
erosion, diamond, coatings, mechanisms
306-318
Wheeler, D.W.
d276c145-56e0-48d0-ae37-a84dda92a947
Wood, R.J.K.
8824ab38-4508-41d1-a5bb-2fe37931424a
1999
Wheeler, D.W.
d276c145-56e0-48d0-ae37-a84dda92a947
Wood, R.J.K.
8824ab38-4508-41d1-a5bb-2fe37931424a
Abstract
This paper reports solid particle erosion studies of 10–47 ?m chemical vapour deposited (CVD) diamond coatings deposited on W and SiC substrates. Two erosion test facilities were used: a water–sand slurry rig and a high-velocity air–sand rig. The erodent used was silica sand with average diameters of 135 ?m, 194 ?m and 235 ?m with the velocities in the range of 16–268 ms?1 and 90° nominal impingement angle. The erosion rates were plotted against particle kinetic energy and compared with those for cemented tungsten carbide and stainless steel. The samples were examined both pre- and post-test by scanning electron microscopy in order to determine the mechanisms of degradation suffered by the coating during the erosion process; the effects of thickness and microstructure were also examined. The time to failure of the coatings at 268 ms?1 was found to increase from 5 to 185 min over the range of coating thickness tested. The erosion mechanism at high-velocity conditions is thought to be a three-stage process consisting of micro-chipping, development of pin-holes and interfacial debonding, followed by catastrophic failure. However, it should be noted that, at particle velocities of 268 ms?1, 46 ?m CVD diamond coatings on tungsten displayed approximately six times the erosion resistance of cemented tungsten carbide.
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Published date: 1999
Keywords:
erosion, diamond, coatings, mechanisms
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Local EPrints ID: 21307
URI: http://eprints.soton.ac.uk/id/eprint/21307
ISSN: 0043-1648
PURE UUID: 111a5cc5-8430-4826-aacb-34624446dd01
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Date deposited: 22 Nov 2006
Last modified: 15 Mar 2024 06:29
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Author:
D.W. Wheeler
Author:
R.J.K. Wood
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