2016
DOI: 10.1007/s11249-016-0734-3
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Study of the Sliding Wear and Friction Behavior of WC + NiCrBSi Laser Cladding Coatings as a Function of Actual Concentration of WC Reinforcement Particles in Ball-on-Disk Test

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Cited by 41 publications
(24 citation statements)
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“…Few craters formed due to pull out and fractures of WC particulates are also visible (fatigue wear). Similar worn out morphology has been reported by Garcia et al., 29 Ye et al., 17 and Niranatlumpong and Koiprasert. 30
Figure 15.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 16.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 17.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 18.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 19.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi) + 35% (WC–Co)] coated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 20.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi)+35% (WC–Co)] coated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 21.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi)+35% (WC–Co)] coated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
…”
Section: Resultssupporting
confidence: 89%
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“…Few craters formed due to pull out and fractures of WC particulates are also visible (fatigue wear). Similar worn out morphology has been reported by Garcia et al., 29 Ye et al., 17 and Niranatlumpong and Koiprasert. 30
Figure 15.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 16.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 17.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 18.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the uncoated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 19.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi) + 35% (WC–Co)] coated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 20.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi)+35% (WC–Co)] coated H11 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 50 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
Figure 21.Surface scale morphology and EDS analysis showing elemental composition (%) at selected points for the plasma spray [65% (NiCrBSi)+35% (WC–Co)] coated H13 steels subjected to sliding wear tests on high-temperature tribometer for 50 min and 25 N load run at (a) room temperature, (b) 400 ℃, and (c) 800 ℃.
…”
Section: Resultssupporting
confidence: 89%
“…Few craters formed due to pull out and fractures of WC particulates are also visible (fatigue wear). Similar worn out morphology has been reported by Garcia et al, 29 Ye et al, 17 and Niranatlumpong and Koiprasert. 30 At 400 C, a decrease in COF was observed for both the uncoated and coated AISI H11 and H13 pin specimens.…”
Section: Surface Roughness Bond Strength and Porosity Of The As-sprsupporting
confidence: 89%
“…Standard deviation analysis indicated, at both sliding distances evaluated, approximately 20% lower variation in the remelted to as-deposited condition. Similar results are reported by García et al (2016) and Zhao et al (2018). Although as-deposited samples showed a tendency of inversely proportional relation between microhardness and wear rate, this behavior was more pronounced in the remelted coating.…”
Section: Friction Coefficient Volumetric Loss and K Archard's Coefficientsupporting
confidence: 88%
“…relatively high hardness, reasonable wear resistance and high temperature corrosion [2]. However, numerous studies have been undertaken with the aim of improving the wear resistance of this coating, and these studies have pointed in the direction of adding ''hard'' particles like (WC, NbC, Cr3C2, TiC, SiC, VC, WC-Ni) to the base formed by the secondary material [3]. Among commercial hard coating materials, tungsten carbide (WC) is the most widely used for wear resistance coating for its high hardness.…”
Section: Introductionmentioning
confidence: 99%