Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose

In this paper, the fabrication method of the BP/C/C composites, and the effect of bamboo charcoal on the wear and friction properties were investigated. The matrix was phenol resin, and reinforcements were Bacterial Cellulose (BC) and Bamboo charcoal particles (BP) as Si additive. The effect of BP w...

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Autores principales: Uugansuren LKHAGVASUREN, Yoshihito OZAWA, Tokio KIKUCHI
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Lenguaje:EN
Publicado: The Japan Society of Mechanical Engineers 2016
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Acceso en línea:https://doaj.org/article/9e71dc51687c4a8aaeb47b3e68ad3ffc
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spelling oai:doaj.org-article:9e71dc51687c4a8aaeb47b3e68ad3ffc2021-11-26T06:51:31ZWear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose2187-974510.1299/mej.15-00743https://doaj.org/article/9e71dc51687c4a8aaeb47b3e68ad3ffc2016-04-01T00:00:00Zhttps://www.jstage.jst.go.jp/article/mej/3/3/3_15-00743/_pdf/-char/enhttps://doaj.org/toc/2187-9745In this paper, the fabrication method of the BP/C/C composites, and the effect of bamboo charcoal on the wear and friction properties were investigated. The matrix was phenol resin, and reinforcements were Bacterial Cellulose (BC) and Bamboo charcoal particles (BP) as Si additive. The effect of BP weight contents on wear and friction performance has been experimentally investigated. Samples were prepared by carbonizing at temperatures of 700°C to 1000°C. The wear tests were carried out by using pin on drum type wear testing apparatus for constant dry sliding conditions. From the experimental results of wear tests, the wear and friction properties of the BP/C/C composites were dependent on the content of BP wt% and carbonizing temperature. The composites with 5wt% BP carbonized at 900°C indicated the lowest friction coefficient of 0.14 among the composites. The composites with 5wt% BP carbonized at 1000°C exhibited the lowest wear rate of 2.25×10-10 [mm2/N]. Compared with the nano-C/C composites with BC and Phenol resin and the BP/C composites, the BP/C/C composites with optimum BP wt% at higher carbonizing temperature showed lower wear rate and friction coefficient. The experimental results indicated that bamboo charcoal can be applied as filler which can provide lower wear rate and friction coefficient.Uugansuren LKHAGVASURENYoshihito OZAWATokio KIKUCHIThe Japan Society of Mechanical Engineersarticlecompositesbacterial cellulosemicrofibril networkbamboo charcoal particletribological propertiesMechanical engineering and machineryTJ1-1570ENMechanical Engineering Journal, Vol 3, Iss 3, Pp 15-00743-15-00743 (2016)
institution DOAJ
collection DOAJ
language EN
topic composites
bacterial cellulose
microfibril network
bamboo charcoal particle
tribological properties
Mechanical engineering and machinery
TJ1-1570
spellingShingle composites
bacterial cellulose
microfibril network
bamboo charcoal particle
tribological properties
Mechanical engineering and machinery
TJ1-1570
Uugansuren LKHAGVASUREN
Yoshihito OZAWA
Tokio KIKUCHI
Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
description In this paper, the fabrication method of the BP/C/C composites, and the effect of bamboo charcoal on the wear and friction properties were investigated. The matrix was phenol resin, and reinforcements were Bacterial Cellulose (BC) and Bamboo charcoal particles (BP) as Si additive. The effect of BP weight contents on wear and friction performance has been experimentally investigated. Samples were prepared by carbonizing at temperatures of 700°C to 1000°C. The wear tests were carried out by using pin on drum type wear testing apparatus for constant dry sliding conditions. From the experimental results of wear tests, the wear and friction properties of the BP/C/C composites were dependent on the content of BP wt% and carbonizing temperature. The composites with 5wt% BP carbonized at 900°C indicated the lowest friction coefficient of 0.14 among the composites. The composites with 5wt% BP carbonized at 1000°C exhibited the lowest wear rate of 2.25×10-10 [mm2/N]. Compared with the nano-C/C composites with BC and Phenol resin and the BP/C composites, the BP/C/C composites with optimum BP wt% at higher carbonizing temperature showed lower wear rate and friction coefficient. The experimental results indicated that bamboo charcoal can be applied as filler which can provide lower wear rate and friction coefficient.
format article
author Uugansuren LKHAGVASUREN
Yoshihito OZAWA
Tokio KIKUCHI
author_facet Uugansuren LKHAGVASUREN
Yoshihito OZAWA
Tokio KIKUCHI
author_sort Uugansuren LKHAGVASUREN
title Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
title_short Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
title_full Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
title_fullStr Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
title_full_unstemmed Wear and friction properties of BP/C/C composites with Bamboo charcoal particles and Bacterial Cellulose
title_sort wear and friction properties of bp/c/c composites with bamboo charcoal particles and bacterial cellulose
publisher The Japan Society of Mechanical Engineers
publishDate 2016
url https://doaj.org/article/9e71dc51687c4a8aaeb47b3e68ad3ffc
work_keys_str_mv AT uugansurenlkhagvasuren wearandfrictionpropertiesofbpcccompositeswithbamboocharcoalparticlesandbacterialcellulose
AT yoshihitoozawa wearandfrictionpropertiesofbpcccompositeswithbamboocharcoalparticlesandbacterialcellulose
AT tokiokikuchi wearandfrictionpropertiesofbpcccompositeswithbamboocharcoalparticlesandbacterialcellulose
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