Dry sliding wear behaviour of HVOF thermal sprayed WC-Co-Cr and WC-CrxCy-Ni coatings

High velocity oxy-fuel (HVOF) thermal spray process has shown obvious advantages over other surface hardening techniques when depositing WC-based layers, such as the laser cladding, electrodeposition and chemical/physical vapour deposition (CVD/PVD) methods, due to its versatility, survivability of...

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Veröffentlicht in:	Wear 2020-02, Vol.442-443, p.203114, Article 203114
Hauptverfasser:	Song, Bo, Murray, James W., Wellman, Richard G., Pala, Zdenek, Hussain, Tanvir
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Sprache:	eng
Schlagworte:	Abrasion resistant coatings Cemented carbides Chemical vapor deposition Cobalt Decarburization Decarburizing Erosion resistance Frictional wear Hardness High temperature Laser beam cladding Loads (forces) Nickel coatings Organic chemistry Oxidation resistance Oxy-fuel Physical vapor deposition Protective coatings Room temperature Sliding friction Surface hardening Survivability Temperature Thermal spray Thermal spraying Tribology Tungsten carbide WC- CrxCy-Ni WC-Co-Cr Wear Wear resistance
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description	High velocity oxy-fuel (HVOF) thermal spray process has shown obvious advantages over other surface hardening techniques when depositing WC-based layers, such as the laser cladding, electrodeposition and chemical/physical vapour deposition (CVD/PVD) methods, due to its versatility, survivability of hardening phase and low cost. HVOF thermal sprayed WC-based coatings are widely used in components that operate in harsh environments needing excellent sliding, fretting, abrasion and erosion resistance. WC-CrxCy-Ni coating shows better wear performance than the WC-Co-Cr coating at high temperature but inferior wear performance at room temperature at lower loads according to literature; however, the wear performance and relevant mechanisms of these two coatings under higher loads has not been reported. To fill this knowledge gap, wear testing of HVOF thermal sprayed WC-CrxCy-Ni and WC-Co-Cr coatings under high loads (96, 240 and 318 N) against a sintered WC-Co (6 mm diameter ball) counter-body was studied in this paper. For WC-CrxCy-Ni coating, decarburization of CrxCy rather than WC, took place during spraying. While the decarburization of WC to W2C occurred in the WC-Co-Cr coating. The major hardening phase (WC) dominated the wear performance of the coatings given its high hardness and small size, and Co also appeared to be a superior binder phase than Ni. At the maximum load, the specific wear rate of WC-CrxCy-Ni coating against WC-Co counter body was 17.92 × 10-7 mm3 N-1m-1, which is two times that of WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1). The wear mechanisms for WC-CrxCy-Ni coatings included abrasion of the matrix, cracking of the secondary carbide phase and pulling out of WC particles. For WC-Co-Cr coatings, abrasion of the matrix was marginal, and cracking of the secondary carbide was not observed. The presence of CrxCy of lower hardness than the WC decreased the wear resistance of entire WC-based coating at room temperature, and improved oxidation resistance of WC at high temperatures due to the higher affinity of Cr to O. Hence, the secondary carbide hardening phase may be detrimental when considering the wear applications of HVOF thermal sprayed WC-based coatings. •In WC-CrxCy-Ni coating, the presence of CrC retards the decarburization of WC during coating deposition; while WC decarburises to W2C in WC-Co-Cr .•The wear performance of the WC-Co-Cr coating is better than that of the WC-CrxCy-Ni coating under all loads in this study.•At the maximum lo
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HVOF thermal sprayed WC-based coatings are widely used in components that operate in harsh environments needing excellent sliding, fretting, abrasion and erosion resistance. WC-CrxCy-Ni coating shows better wear performance than the WC-Co-Cr coating at high temperature but inferior wear performance at room temperature at lower loads according to literature; however, the wear performance and relevant mechanisms of these two coatings under higher loads has not been reported. To fill this knowledge gap, wear testing of HVOF thermal sprayed WC-CrxCy-Ni and WC-Co-Cr coatings under high loads (96, 240 and 318 N) against a sintered WC-Co (6 mm diameter ball) counter-body was studied in this paper. For WC-CrxCy-Ni coating, decarburization of CrxCy rather than WC, took place during spraying. While the decarburization of WC to W2C occurred in the WC-Co-Cr coating. The major hardening phase (WC) dominated the wear performance of the coatings given its high hardness and small size, and Co also appeared to be a superior binder phase than Ni. At the maximum load, the specific wear rate of WC-CrxCy-Ni coating against WC-Co counter body was 17.92 × 10-7 mm3 N-1m-1, which is two times that of WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1). The wear mechanisms for WC-CrxCy-Ni coatings included abrasion of the matrix, cracking of the secondary carbide phase and pulling out of WC particles. For WC-Co-Cr coatings, abrasion of the matrix was marginal, and cracking of the secondary carbide was not observed. The presence of CrxCy of lower hardness than the WC decreased the wear resistance of entire WC-based coating at room temperature, and improved oxidation resistance of WC at high temperatures due to the higher affinity of Cr to O. Hence, the secondary carbide hardening phase may be detrimental when considering the wear applications of HVOF thermal sprayed WC-based coatings. •In WC-CrxCy-Ni coating, the presence of CrC retards the decarburization of WC during coating deposition; while WC decarburises to W2C in WC-Co-Cr .•The wear performance of the WC-Co-Cr coating is better than that of the WC-CrxCy-Ni coating under all loads in this study.•At the maximum load, the specific wear of WC-CrxCy-Ni coating is 17.92 × 10-7 mm3 N-1m-1, which is two times of the WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1).•Phase composition,fraction of hardening carbides and binder properties determine the wear resistance.•Abrasion of the matrix, cracking of the secondary carbide and pulling out of primary carbide contributed to the wear mechanisms.</description><identifier>ISSN: 0043-1648</identifier><identifier>EISSN: 1873-2577</identifier><identifier>DOI: 10.1016/j.wear.2019.203114</identifier><language>eng</language><publisher>Amsterdam: Elsevier B.V</publisher><subject>Abrasion resistant coatings ; Cemented carbides ; Chemical vapor deposition ; Cobalt ; Decarburization ; Decarburizing ; Erosion resistance ; Frictional wear ; Hardness ; High temperature ; Laser beam cladding ; Loads (forces) ; Nickel coatings ; Organic chemistry ; Oxidation resistance ; Oxy-fuel ; Physical vapor deposition ; Protective coatings ; Room temperature ; Sliding friction ; Surface hardening ; Survivability ; Temperature ; Thermal spray ; Thermal spraying ; Tribology ; Tungsten carbide ; WC- CrxCy-Ni ; WC-Co-Cr ; Wear ; Wear resistance</subject><ispartof>Wear, 2020-02, Vol.442-443, p.203114, Article 203114</ispartof><rights>2019 Elsevier B.V.</rights><rights>Copyright Elsevier Science Ltd. Feb 15, 2020</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c328t-610a8ac095b9346a27d9bc891ee2eafdb7361a157ae514794a9e4036e46b303</citedby><cites>FETCH-LOGICAL-c328t-610a8ac095b9346a27d9bc891ee2eafdb7361a157ae514794a9e4036e46b303</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://dx.doi.org/10.1016/j.wear.2019.203114$$EHTML$$P50$$Gelsevier$$H</linktohtml><link.rule.ids>314,780,784,3550,27924,27925,45995</link.rule.ids></links><search><creatorcontrib>Song, Bo</creatorcontrib><creatorcontrib>Murray, James W.</creatorcontrib><creatorcontrib>Wellman, Richard G.</creatorcontrib><creatorcontrib>Pala, Zdenek</creatorcontrib><creatorcontrib>Hussain, Tanvir</creatorcontrib><title>Dry sliding wear behaviour of HVOF thermal sprayed WC-Co-Cr and WC-CrxCy-Ni coatings</title><title>Wear</title><description>High velocity oxy-fuel (HVOF) thermal spray process has shown obvious advantages over other surface hardening techniques when depositing WC-based layers, such as the laser cladding, electrodeposition and chemical/physical vapour deposition (CVD/PVD) methods, due to its versatility, survivability of hardening phase and low cost. HVOF thermal sprayed WC-based coatings are widely used in components that operate in harsh environments needing excellent sliding, fretting, abrasion and erosion resistance. WC-CrxCy-Ni coating shows better wear performance than the WC-Co-Cr coating at high temperature but inferior wear performance at room temperature at lower loads according to literature; however, the wear performance and relevant mechanisms of these two coatings under higher loads has not been reported. To fill this knowledge gap, wear testing of HVOF thermal sprayed WC-CrxCy-Ni and WC-Co-Cr coatings under high loads (96, 240 and 318 N) against a sintered WC-Co (6 mm diameter ball) counter-body was studied in this paper. For WC-CrxCy-Ni coating, decarburization of CrxCy rather than WC, took place during spraying. While the decarburization of WC to W2C occurred in the WC-Co-Cr coating. The major hardening phase (WC) dominated the wear performance of the coatings given its high hardness and small size, and Co also appeared to be a superior binder phase than Ni. At the maximum load, the specific wear rate of WC-CrxCy-Ni coating against WC-Co counter body was 17.92 × 10-7 mm3 N-1m-1, which is two times that of WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1). The wear mechanisms for WC-CrxCy-Ni coatings included abrasion of the matrix, cracking of the secondary carbide phase and pulling out of WC particles. For WC-Co-Cr coatings, abrasion of the matrix was marginal, and cracking of the secondary carbide was not observed. The presence of CrxCy of lower hardness than the WC decreased the wear resistance of entire WC-based coating at room temperature, and improved oxidation resistance of WC at high temperatures due to the higher affinity of Cr to O. Hence, the secondary carbide hardening phase may be detrimental when considering the wear applications of HVOF thermal sprayed WC-based coatings. •In WC-CrxCy-Ni coating, the presence of CrC retards the decarburization of WC during coating deposition; while WC decarburises to W2C in WC-Co-Cr .•The wear performance of the WC-Co-Cr coating is better than that of the WC-CrxCy-Ni coating under all loads in this study.•At the maximum load, the specific wear of WC-CrxCy-Ni coating is 17.92 × 10-7 mm3 N-1m-1, which is two times of the WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1).•Phase composition,fraction of hardening carbides and binder properties determine the wear resistance.•Abrasion of the matrix, cracking of the secondary carbide and pulling out of primary carbide contributed to the wear mechanisms.</description><subject>Abrasion resistant coatings</subject><subject>Cemented carbides</subject><subject>Chemical vapor deposition</subject><subject>Cobalt</subject><subject>Decarburization</subject><subject>Decarburizing</subject><subject>Erosion resistance</subject><subject>Frictional wear</subject><subject>Hardness</subject><subject>High temperature</subject><subject>Laser beam cladding</subject><subject>Loads (forces)</subject><subject>Nickel coatings</subject><subject>Organic chemistry</subject><subject>Oxidation resistance</subject><subject>Oxy-fuel</subject><subject>Physical vapor deposition</subject><subject>Protective coatings</subject><subject>Room temperature</subject><subject>Sliding friction</subject><subject>Surface hardening</subject><subject>Survivability</subject><subject>Temperature</subject><subject>Thermal spray</subject><subject>Thermal spraying</subject><subject>Tribology</subject><subject>Tungsten carbide</subject><subject>WC- CrxCy-Ni</subject><subject>WC-Co-Cr</subject><subject>Wear</subject><subject>Wear resistance</subject><issn>0043-1648</issn><issn>1873-2577</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><recordid>eNp9UMtOwzAQtBBIlMIPcLLEOcWvOLHEBQVKkRA9UMHRcpwNddQ2xU4L-XschTOXXa00MzszCF1TMqOEyttm9g3GzxihKg5OqThBE5pnPGFplp2iCSGCJ1SK_BxdhNAQEpGpnKDVg-9x2LjK7T7xoIFLWJujaw8etzVevC_nuFuD35oNDntveqjwR5EUbVJ4bHbj4X-KPnl12LamizrhEp3VZhPg6m9P0dv8cVUskpfl03Nx_5JYzvIukZSY3Fii0lJxIQ3LKlXaXFEABqauyoxLamiaGUipyJQwCgThEoQsOeFTdDOq7n37dYDQ6Sa63sWHmvFU5CzNuYooNqKsb0PwUOu9d1vje02JHrrTjR5y66E7PXYXSXcjCaL7owOvg3Wws1A5D7bTVev-o_8ClpR1eA</recordid><startdate>20200215</startdate><enddate>20200215</enddate><creator>Song, Bo</creator><creator>Murray, James W.</creator><creator>Wellman, Richard G.</creator><creator>Pala, Zdenek</creator><creator>Hussain, Tanvir</creator><general>Elsevier B.V</general><general>Elsevier Science Ltd</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>7TB</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>FR3</scope><scope>JG9</scope><scope>L7M</scope></search><sort><creationdate>20200215</creationdate><title>Dry sliding wear behaviour of HVOF thermal sprayed WC-Co-Cr and WC-CrxCy-Ni coatings</title><author>Song, Bo ; Murray, James W. ; Wellman, Richard G. ; Pala, Zdenek ; Hussain, Tanvir</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c328t-610a8ac095b9346a27d9bc891ee2eafdb7361a157ae514794a9e4036e46b303</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2020</creationdate><topic>Abrasion resistant coatings</topic><topic>Cemented carbides</topic><topic>Chemical vapor deposition</topic><topic>Cobalt</topic><topic>Decarburization</topic><topic>Decarburizing</topic><topic>Erosion resistance</topic><topic>Frictional wear</topic><topic>Hardness</topic><topic>High temperature</topic><topic>Laser beam cladding</topic><topic>Loads (forces)</topic><topic>Nickel coatings</topic><topic>Organic chemistry</topic><topic>Oxidation resistance</topic><topic>Oxy-fuel</topic><topic>Physical vapor deposition</topic><topic>Protective coatings</topic><topic>Room temperature</topic><topic>Sliding friction</topic><topic>Surface hardening</topic><topic>Survivability</topic><topic>Temperature</topic><topic>Thermal spray</topic><topic>Thermal spraying</topic><topic>Tribology</topic><topic>Tungsten carbide</topic><topic>WC- CrxCy-Ni</topic><topic>WC-Co-Cr</topic><topic>Wear</topic><topic>Wear resistance</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Song, Bo</creatorcontrib><creatorcontrib>Murray, James W.</creatorcontrib><creatorcontrib>Wellman, Richard G.</creatorcontrib><creatorcontrib>Pala, Zdenek</creatorcontrib><creatorcontrib>Hussain, Tanvir</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Mechanical & Transportation Engineering Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Materials Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Wear</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Song, Bo</au><au>Murray, James W.</au><au>Wellman, Richard G.</au><au>Pala, Zdenek</au><au>Hussain, Tanvir</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Dry sliding wear behaviour of HVOF thermal sprayed WC-Co-Cr and WC-CrxCy-Ni coatings</atitle><jtitle>Wear</jtitle><date>2020-02-15</date><risdate>2020</risdate><volume>442-443</volume><spage>203114</spage><pages>203114-</pages><artnum>203114</artnum><issn>0043-1648</issn><eissn>1873-2577</eissn><abstract>High velocity oxy-fuel (HVOF) thermal spray process has shown obvious advantages over other surface hardening techniques when depositing WC-based layers, such as the laser cladding, electrodeposition and chemical/physical vapour deposition (CVD/PVD) methods, due to its versatility, survivability of hardening phase and low cost. HVOF thermal sprayed WC-based coatings are widely used in components that operate in harsh environments needing excellent sliding, fretting, abrasion and erosion resistance. WC-CrxCy-Ni coating shows better wear performance than the WC-Co-Cr coating at high temperature but inferior wear performance at room temperature at lower loads according to literature; however, the wear performance and relevant mechanisms of these two coatings under higher loads has not been reported. To fill this knowledge gap, wear testing of HVOF thermal sprayed WC-CrxCy-Ni and WC-Co-Cr coatings under high loads (96, 240 and 318 N) against a sintered WC-Co (6 mm diameter ball) counter-body was studied in this paper. For WC-CrxCy-Ni coating, decarburization of CrxCy rather than WC, took place during spraying. While the decarburization of WC to W2C occurred in the WC-Co-Cr coating. The major hardening phase (WC) dominated the wear performance of the coatings given its high hardness and small size, and Co also appeared to be a superior binder phase than Ni. At the maximum load, the specific wear rate of WC-CrxCy-Ni coating against WC-Co counter body was 17.92 × 10-7 mm3 N-1m-1, which is two times that of WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1). The wear mechanisms for WC-CrxCy-Ni coatings included abrasion of the matrix, cracking of the secondary carbide phase and pulling out of WC particles. For WC-Co-Cr coatings, abrasion of the matrix was marginal, and cracking of the secondary carbide was not observed. The presence of CrxCy of lower hardness than the WC decreased the wear resistance of entire WC-based coating at room temperature, and improved oxidation resistance of WC at high temperatures due to the higher affinity of Cr to O. Hence, the secondary carbide hardening phase may be detrimental when considering the wear applications of HVOF thermal sprayed WC-based coatings. •In WC-CrxCy-Ni coating, the presence of CrC retards the decarburization of WC during coating deposition; while WC decarburises to W2C in WC-Co-Cr .•The wear performance of the WC-Co-Cr coating is better than that of the WC-CrxCy-Ni coating under all loads in this study.•At the maximum load, the specific wear of WC-CrxCy-Ni coating is 17.92 × 10-7 mm3 N-1m-1, which is two times of the WC-Co-Cr coating (9.81 × 10-7 mm3 N-1m-1).•Phase composition,fraction of hardening carbides and binder properties determine the wear resistance.•Abrasion of the matrix, cracking of the secondary carbide and pulling out of primary carbide contributed to the wear mechanisms.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.wear.2019.203114</doi></addata></record>
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subjects	Abrasion resistant coatings Cemented carbides Chemical vapor deposition Cobalt Decarburization Decarburizing Erosion resistance Frictional wear Hardness High temperature Laser beam cladding Loads (forces) Nickel coatings Organic chemistry Oxidation resistance Oxy-fuel Physical vapor deposition Protective coatings Room temperature Sliding friction Surface hardening Survivability Temperature Thermal spray Thermal spraying Tribology Tungsten carbide WC- CrxCy-Ni WC-Co-Cr Wear Wear resistance
title	Dry sliding wear behaviour of HVOF thermal sprayed WC-Co-Cr and WC-CrxCy-Ni coatings
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