Tribological behaviour of Cu based materials produced by mechanical milling/alloying and spark plasma sintering

Tribological behaviour of Cu based materials produced by mechanical milling/alloying and spark plasma sintering

Aim of the work is to investigate the tribological behaviour of Cu based materials produced by mechanical milling (MM), mechanical alloying (MA) and finally sintered by Spark Plasma Sintering (SPS). MM causes a significant strain hardening of Cu, while MA by 0.5wt%TiB2 adds a further dispersion hard...

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Veröffentlicht in:Wear 2017-04, Vol.376-377 (PB), p.958-967
Hauptverfasser: Pellizzari, Massimo, Cipolloni, Giulia
Format: Artikel
Sprache:eng
Schlagworte:
Abrasion
Abrasive wear
Adhesion
Adhesive strength
Alloys
Coefficient of friction
Copper
Dispersion hardening
Dispersion hardening steels
Dry sliding
Friction
High speed tool steels
Mechanical alloying
Mechanical milling
Penetration depth
Plasma sintering
Sliding contact
Spark plasma sintering
Strain hardening
Thermal conductivity
Thermal resistance
Titanium diboride
Tribo-oxidation
Tribology
Wear
Wear mechanisms
Wear resistance
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Cipolloni, Giulia
description Aim of the work is to investigate the tribological behaviour of Cu based materials produced by mechanical milling (MM), mechanical alloying (MA) and finally sintered by Spark Plasma Sintering (SPS). MM causes a significant strain hardening of Cu, while MA by 0.5wt%TiB2 adds a further dispersion hardening contribution. During dry sliding contact against high speed steel a close relation has been found between friction coefficient and contact temperature highlighting two regimes. The first one, occurring at an early stage of the process, is characterized by a high friction coefficient (~1), typical of the strong adhesion of Cu–Cu contact. The second one is characterized by a lower steady-state friction (~0.7) related to the change of wear mechanism from adhesive metallic into triboxidative. By increasing the load the friction coefficient decreases, the transition time from the adhesive to triboxidative friction regime decreases and the contact temperature increases. Under abrasive wear conditions the penetration depth of the indenter is progressively reduced by increasing hardness, highlighting the benefits of MM and, even more, of MA. The Cu+0.5wt.%TiB2 composite alloyed for 240min shows the best wear resistance under both wear conditions. The good wear resistance combined to high thermal conductivity represent very attractive properties for many applications. [Display omitted] •PM Cu based material by mechanical milling (MM) or mechanical alloying (MA) with TiB2.•Poor influence of HV during steady state dry sliding, governed by triboxidation.•High sliding loads enhance oxidation leading to lower friction and wear rates.•Strain hardening (MM) and dispersion hardening (MA) improve abrasive wear resistance.•Good combination of wear resistance and thermal conductivity for Cu+0.5%TiB2.
doi_str_mv 10.1016/j.wear.2016.11.050
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MM causes a significant strain hardening of Cu, while MA by 0.5wt%TiB2 adds a further dispersion hardening contribution. During dry sliding contact against high speed steel a close relation has been found between friction coefficient and contact temperature highlighting two regimes. The first one, occurring at an early stage of the process, is characterized by a high friction coefficient (~1), typical of the strong adhesion of Cu–Cu contact. The second one is characterized by a lower steady-state friction (~0.7) related to the change of wear mechanism from adhesive metallic into triboxidative. By increasing the load the friction coefficient decreases, the transition time from the adhesive to triboxidative friction regime decreases and the contact temperature increases. Under abrasive wear conditions the penetration depth of the indenter is progressively reduced by increasing hardness, highlighting the benefits of MM and, even more, of MA. The Cu+0.5wt.%TiB2 composite alloyed for 240min shows the best wear resistance under both wear conditions. The good wear resistance combined to high thermal conductivity represent very attractive properties for many applications. [Display omitted] •PM Cu based material by mechanical milling (MM) or mechanical alloying (MA) with TiB2.•Poor influence of HV during steady state dry sliding, governed by triboxidation.•High sliding loads enhance oxidation leading to lower friction and wear rates.•Strain hardening (MM) and dispersion hardening (MA) improve abrasive wear resistance.•Good combination of wear resistance and thermal conductivity for Cu+0.5%TiB2.</description><identifier>ISSN: 0043-1648</identifier><identifier>EISSN: 1873-2577</identifier><identifier>DOI: 10.1016/j.wear.2016.11.050</identifier><language>eng</language><publisher>Amsterdam: Elsevier B.V</publisher><subject>Abrasion ; Abrasive wear ; Adhesion ; Adhesive strength ; Alloys ; Coefficient of friction ; Copper ; Dispersion hardening ; Dispersion hardening steels ; Dry sliding ; Friction ; High speed tool steels ; Mechanical alloying ; Mechanical milling ; Penetration depth ; Plasma sintering ; Sliding contact ; Spark plasma sintering ; Strain hardening ; Thermal conductivity ; Thermal resistance ; Titanium diboride ; Tribo-oxidation ; Tribology ; Wear ; Wear mechanisms ; Wear resistance</subject><ispartof>Wear, 2017-04, Vol.376-377 (PB), p.958-967</ispartof><rights>2017 Elsevier B.V.</rights><rights>Copyright Elsevier Science Ltd. 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MM causes a significant strain hardening of Cu, while MA by 0.5wt%TiB2 adds a further dispersion hardening contribution. During dry sliding contact against high speed steel a close relation has been found between friction coefficient and contact temperature highlighting two regimes. The first one, occurring at an early stage of the process, is characterized by a high friction coefficient (~1), typical of the strong adhesion of Cu–Cu contact. The second one is characterized by a lower steady-state friction (~0.7) related to the change of wear mechanism from adhesive metallic into triboxidative. By increasing the load the friction coefficient decreases, the transition time from the adhesive to triboxidative friction regime decreases and the contact temperature increases. Under abrasive wear conditions the penetration depth of the indenter is progressively reduced by increasing hardness, highlighting the benefits of MM and, even more, of MA. The Cu+0.5wt.%TiB2 composite alloyed for 240min shows the best wear resistance under both wear conditions. The good wear resistance combined to high thermal conductivity represent very attractive properties for many applications. [Display omitted] •PM Cu based material by mechanical milling (MM) or mechanical alloying (MA) with TiB2.•Poor influence of HV during steady state dry sliding, governed by triboxidation.•High sliding loads enhance oxidation leading to lower friction and wear rates.•Strain hardening (MM) and dispersion hardening (MA) improve abrasive wear resistance.•Good combination of wear resistance and thermal conductivity for Cu+0.5%TiB2.</description><subject>Abrasion</subject><subject>Abrasive wear</subject><subject>Adhesion</subject><subject>Adhesive strength</subject><subject>Alloys</subject><subject>Coefficient of friction</subject><subject>Copper</subject><subject>Dispersion hardening</subject><subject>Dispersion hardening steels</subject><subject>Dry sliding</subject><subject>Friction</subject><subject>High speed tool steels</subject><subject>Mechanical alloying</subject><subject>Mechanical milling</subject><subject>Penetration depth</subject><subject>Plasma sintering</subject><subject>Sliding contact</subject><subject>Spark plasma sintering</subject><subject>Strain hardening</subject><subject>Thermal conductivity</subject><subject>Thermal resistance</subject><subject>Titanium diboride</subject><subject>Tribo-oxidation</subject><subject>Tribology</subject><subject>Wear</subject><subject>Wear mechanisms</subject><subject>Wear resistance</subject><issn>0043-1648</issn><issn>1873-2577</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNp9kM1OwzAQhC0EEqXwApwscU66jh3Hkbigij-pEpdythzHaR2SuNgJqG-PQzlz2tVqZ3b2Q-iWQEqA8FWbfhvl0yz2KSEp5HCGFkQUNMnyojhHCwBGE8KZuERXIbQAQMqcL5Dbelu5zu2sVh2uzF59WTd57Bq8nnClgqlxr0bjreoCPnhXTzqOqiPujd6r4VfW266zw26lus4dY4PVUONwUP4DHzoVeoWDHWaPYXeNLproZG7-6hK9Pz1u1y_J5u35df2wSTTNxJg0TAnOSk6LMoeGAKiS14aIilHIack1axrCoBK8BqEzUdOi4gWnjclKBkbQJbo7-cbIn5MJo2zjW0M8KTMQVABhnMSt7LSlvQvBm0YevO2VP0oCcgYrWzmDlTNYSYiMYKPo_iQyMf-XNV4Gbc0QsVhv9ChrZ_-T_wAp_4Id</recordid><startdate>20170415</startdate><enddate>20170415</enddate><creator>Pellizzari, Massimo</creator><creator>Cipolloni, Giulia</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>20170415</creationdate><title>Tribological behaviour of Cu based materials produced by mechanical milling/alloying and spark plasma sintering</title><author>Pellizzari, Massimo ; 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MM causes a significant strain hardening of Cu, while MA by 0.5wt%TiB2 adds a further dispersion hardening contribution. During dry sliding contact against high speed steel a close relation has been found between friction coefficient and contact temperature highlighting two regimes. The first one, occurring at an early stage of the process, is characterized by a high friction coefficient (~1), typical of the strong adhesion of Cu–Cu contact. The second one is characterized by a lower steady-state friction (~0.7) related to the change of wear mechanism from adhesive metallic into triboxidative. By increasing the load the friction coefficient decreases, the transition time from the adhesive to triboxidative friction regime decreases and the contact temperature increases. Under abrasive wear conditions the penetration depth of the indenter is progressively reduced by increasing hardness, highlighting the benefits of MM and, even more, of MA. The Cu+0.5wt.%TiB2 composite alloyed for 240min shows the best wear resistance under both wear conditions. The good wear resistance combined to high thermal conductivity represent very attractive properties for many applications. [Display omitted] •PM Cu based material by mechanical milling (MM) or mechanical alloying (MA) with TiB2.•Poor influence of HV during steady state dry sliding, governed by triboxidation.•High sliding loads enhance oxidation leading to lower friction and wear rates.•Strain hardening (MM) and dispersion hardening (MA) improve abrasive wear resistance.•Good combination of wear resistance and thermal conductivity for Cu+0.5%TiB2.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.wear.2016.11.050</doi><tpages>10</tpages></addata></record>
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subjects Abrasion
Abrasive wear
Adhesion
Adhesive strength
Alloys
Coefficient of friction
Copper
Dispersion hardening
Dispersion hardening steels
Dry sliding
Friction
High speed tool steels
Mechanical alloying
Mechanical milling
Penetration depth
Plasma sintering
Sliding contact
Spark plasma sintering
Strain hardening
Thermal conductivity
Thermal resistance
Titanium diboride
Tribo-oxidation
Tribology
Wear
Wear mechanisms
Wear resistance
title Tribological behaviour of Cu based materials produced by mechanical milling/alloying and spark plasma sintering
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