Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite

Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite

B4C ceramic particulate–reinforced Al 5083 matrix composite with various B4C content was fabricated successfully via hot-press sintering under Argon atmosphere. B4C particles presented relative high wettability, bonding strength and symmetrical distribution in the Al 5083 matrix. The hardness value,...

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Main Authors: Qian Zhao, Yunhong Liang, Zhihui Zhang, Xiujuan Li, Luquan Ren
Format: Article
Language:English
Published: MDPI AG 2016-09-01
Series:Metals
Subjects:
aluminum matrix composite
hot pressed sintering
ceramic
wear
Online Access:http://www.mdpi.com/2075-4701/6/9/227
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spelling doaj-554e5f096af341dca47d606cbf0ba4152020-11-24T21:05:57ZengMDPI AGMetals2075-47012016-09-016922710.3390/met6090227met6090227Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix CompositeQian Zhao0Yunhong Liang1Zhihui Zhang2Xiujuan Li3Luquan Ren4The Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130025, ChinaThe Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130025, ChinaThe Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130025, ChinaThe Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130025, ChinaThe Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130025, ChinaB4C ceramic particulate–reinforced Al 5083 matrix composite with various B4C content was fabricated successfully via hot-press sintering under Argon atmosphere. B4C particles presented relative high wettability, bonding strength and symmetrical distribution in the Al 5083 matrix. The hardness value, friction coefficient and wear resistance of the composite were higher than those of the Al 5083 matrix. The augment of the B4C content resulted in the increase of the friction coefficient and decrease of the wear mass loss, respectively. The 30 wt % B4C/Al 5083 composite exhibited the highest wear resistance. At a low load of 50 N, the dominant wear mechanisms of the B4C/Al 5083 composite were micro-cutting and abrasive wear. At a high load of 200 N, the dominant wear mechanisms were micro-cutting and adhesion wear associated with the formation of the delamination layer which protected the composite from further wear and enhanced the wear resistance under the condition of high load.http://www.mdpi.com/2075-4701/6/9/227aluminum matrix compositehot pressed sinteringceramicwear
collection DOAJ
language English
format Article
sources DOAJ
author Qian Zhao
Yunhong Liang
Zhihui Zhang
Xiujuan Li
Luquan Ren
spellingShingle Qian Zhao
Yunhong Liang
Zhihui Zhang
Xiujuan Li
Luquan Ren
Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
Metals
aluminum matrix composite
hot pressed sintering
ceramic
wear
author_facet Qian Zhao
Yunhong Liang
Zhihui Zhang
Xiujuan Li
Luquan Ren
author_sort Qian Zhao
title Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
title_short Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
title_full Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
title_fullStr Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
title_full_unstemmed Microstructure and Dry-Sliding Wear Behavior of B4C Ceramic Particulate Reinforced Al 5083 Matrix Composite
title_sort microstructure and dry-sliding wear behavior of b4c ceramic particulate reinforced al 5083 matrix composite
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2016-09-01
description B4C ceramic particulate–reinforced Al 5083 matrix composite with various B4C content was fabricated successfully via hot-press sintering under Argon atmosphere. B4C particles presented relative high wettability, bonding strength and symmetrical distribution in the Al 5083 matrix. The hardness value, friction coefficient and wear resistance of the composite were higher than those of the Al 5083 matrix. The augment of the B4C content resulted in the increase of the friction coefficient and decrease of the wear mass loss, respectively. The 30 wt % B4C/Al 5083 composite exhibited the highest wear resistance. At a low load of 50 N, the dominant wear mechanisms of the B4C/Al 5083 composite were micro-cutting and abrasive wear. At a high load of 200 N, the dominant wear mechanisms were micro-cutting and adhesion wear associated with the formation of the delamination layer which protected the composite from further wear and enhanced the wear resistance under the condition of high load.
topic aluminum matrix composite
hot pressed sintering
ceramic
wear
url http://www.mdpi.com/2075-4701/6/9/227
work_keys_str_mv AT qianzhao microstructureanddryslidingwearbehaviorofb4cceramicparticulatereinforcedal5083matrixcomposite
AT yunhongliang microstructureanddryslidingwearbehaviorofb4cceramicparticulatereinforcedal5083matrixcomposite
AT zhihuizhang microstructureanddryslidingwearbehaviorofb4cceramicparticulatereinforcedal5083matrixcomposite
AT xiujuanli microstructureanddryslidingwearbehaviorofb4cceramicparticulatereinforcedal5083matrixcomposite
AT luquanren microstructureanddryslidingwearbehaviorofb4cceramicparticulatereinforcedal5083matrixcomposite
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