Estimation of the friction coefficient in turning process of metals through model experiment

An in-procedure tribometer is analyzed to assess the friction during orthogonal turning process at cutting rates of up to 300 m/min to determine genuine cutting procedure conditions. The examined tribometer consists of a spring preloaded tungsten carbide with (5% to 8%) cobalt pin with the rounded t...

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Veröffentlicht in:	Proceedings of the Institution of Mechanical Engineers. Part J, Journal of engineering tribology Journal of engineering tribology, 2018-06, Vol.232 (6), p.685-692
Hauptverfasser:	Chowdhury, Mohammad A, Das, Suman, Debnath, Uttam K
Format:	Artikel
Sprache:	eng
Schlagworte:	Amalgams Axial forces Coefficient of friction Cutting speed Friction Graphite Mechanical engineering Particulate composites Tungsten carbide Turning (machining) Wear rate
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container_title	Proceedings of the Institution of Mechanical Engineers. Part J, Journal of engineering tribology
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creator	Chowdhury, Mohammad A Das, Suman Debnath, Uttam K
description	An in-procedure tribometer is analyzed to assess the friction during orthogonal turning process at cutting rates of up to 300 m/min to determine genuine cutting procedure conditions. The examined tribometer consists of a spring preloaded tungsten carbide with (5% to 8%) cobalt pin with the rounded tip mounted behind the bleeding edge and in contact with the naturally produced workpiece plane. The pin preload is fitted by feed power or force. A 3D-feed force measuring gadget in the obsession of the pin facilitates the assessment of the friction coefficient from tangential and typical strengths. Tests indicate considerably diverse results while reaching new and oxidized planes as well as diminishing friction coefficients as the cutting velocity increases. In general, greater graphite content decreases the friction coefficient and the temperature inclines in the wear pin. A uniform scattering of graphite particles in steel composites enhance their irritating resistance. Moreover, the wear rates for these amalgams are lower than those for similar combinations without graphite. Plane or surface equality is the key predictor of roughness. Plane inequality decreases as cutting speed increases and vice versa.
doi_str_mv	10.1177/1350650117726463
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The examined tribometer consists of a spring preloaded tungsten carbide with (5% to 8%) cobalt pin with the rounded tip mounted behind the bleeding edge and in contact with the naturally produced workpiece plane. The pin preload is fitted by feed power or force. A 3D-feed force measuring gadget in the obsession of the pin facilitates the assessment of the friction coefficient from tangential and typical strengths. Tests indicate considerably diverse results while reaching new and oxidized planes as well as diminishing friction coefficients as the cutting velocity increases. In general, greater graphite content decreases the friction coefficient and the temperature inclines in the wear pin. A uniform scattering of graphite particles in steel composites enhance their irritating resistance. Moreover, the wear rates for these amalgams are lower than those for similar combinations without graphite. Plane or surface equality is the key predictor of roughness. 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Part J, Journal of engineering tribology</title><description>An in-procedure tribometer is analyzed to assess the friction during orthogonal turning process at cutting rates of up to 300 m/min to determine genuine cutting procedure conditions. The examined tribometer consists of a spring preloaded tungsten carbide with (5% to 8%) cobalt pin with the rounded tip mounted behind the bleeding edge and in contact with the naturally produced workpiece plane. The pin preload is fitted by feed power or force. A 3D-feed force measuring gadget in the obsession of the pin facilitates the assessment of the friction coefficient from tangential and typical strengths. Tests indicate considerably diverse results while reaching new and oxidized planes as well as diminishing friction coefficients as the cutting velocity increases. In general, greater graphite content decreases the friction coefficient and the temperature inclines in the wear pin. 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The examined tribometer consists of a spring preloaded tungsten carbide with (5% to 8%) cobalt pin with the rounded tip mounted behind the bleeding edge and in contact with the naturally produced workpiece plane. The pin preload is fitted by feed power or force. A 3D-feed force measuring gadget in the obsession of the pin facilitates the assessment of the friction coefficient from tangential and typical strengths. Tests indicate considerably diverse results while reaching new and oxidized planes as well as diminishing friction coefficients as the cutting velocity increases. In general, greater graphite content decreases the friction coefficient and the temperature inclines in the wear pin. A uniform scattering of graphite particles in steel composites enhance their irritating resistance. Moreover, the wear rates for these amalgams are lower than those for similar combinations without graphite. Plane or surface equality is the key predictor of roughness. Plane inequality decreases as cutting speed increases and vice versa.</abstract><cop>London, England</cop><pub>SAGE Publications</pub><doi>10.1177/1350650117726463</doi><tpages>8</tpages></addata></record>
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subjects	Amalgams Axial forces Coefficient of friction Cutting speed Friction Graphite Mechanical engineering Particulate composites Tungsten carbide Turning (machining) Wear rate
title	Estimation of the friction coefficient in turning process of metals through model experiment
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