Tribological study on cast iron based, graphite and CNT enriched hybrid HVOF coating from room temperature to 300°C

IF 1.2 4区材料科学 Q4 ELECTROCHEMISTRY

Transactions of The Institute of Metal Finishing Pub Date : 2023-09-27 DOI:10.1080/00202967.2023.2251756

Sonia Dangi, R. S. Walia, N. M. Suri, Sumit Chaudhary

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引用次数: 0

Abstract

ABSTRACTIn this article, eco-friendly graphite has been produced from the carbonised rice husk, an environmental waste. Graphite, carbon nanotube (CNT) and cast iron powder were blended to produce the hybrid coating material. This hybrid coating material was deposited over the cast iron substrate using HVOF thermal spray. The microhardness of the coated sample increased by 42% as compared to the substrate. The morphological and elemental analysis was carried out using SEM, XRD and raman spectroscopy. The residual stresses developed in the coated sample were measured using an X-ray analyzer and found to be compressive, indicating a stable coating. A tribological investigation was carried out on a Pin-on-disc tribometer at ambient, 150°C, and 300°C temperatures. The coefficient of friction and specific wear rate reduced by ≈ 62% and ≈ 47% respectively. The SEM investigation showed evidence of free graphite as a solid lubricant over the coated samples.KEYWORDS: HVOF thermal spray coatingTribologySEMXRDResidual stressRaman spectroscopy AcknowledgementsThe authors would like to sincerely thank Metallizing Equipments Co. Pvt. Ltd., Jodhpur, for their support in sample preparation. The authors would also like to thank the management and staff of the Precision Manufacturing Laboratory, DTU, Delhi, and Tribology Centre, NIT, Srinagar for providing the tribological testing and material characterisation facilities.Disclosure statementNo potential conflict of interest was reported by the author(s).Author ContributionsSonia Dangi: Conceptualisation, data acquisition, drafting, reviewing, and editing the manuscript (First Author). R S Walia: Conceptualisation, review, and editing the manuscript (Co-Author). N M Suri: Conceptualisation, review, and editing the manuscript (Co-Author). Sumit Chaudhary: Conceptualisation, data acquisition, review, and editing the manuscript (Co-Author and corresponding author).

查看原文本刊更多论文

铸铁基、石墨和富碳纳米管杂化HVOF涂层室温至300℃的摩擦学研究

摘要:本文以环境垃圾稻壳为原料，制备了环保型石墨。将石墨、碳纳米管(CNT)和铸铁粉混合制备复合涂层材料。采用HVOF热喷涂技术将该复合涂层材料沉积在铸铁基体上。涂层样品的显微硬度比衬底提高了42%。采用SEM、XRD和拉曼光谱对材料进行了形貌和元素分析。使用x射线分析仪测量涂层样品中产生的残余应力，发现是压缩的，表明涂层稳定。在环境、150°C和300°C的温度下，在Pin-on-disc摩擦计上进行了摩擦学研究。摩擦系数和比磨损率分别降低≈62%和≈47%。扫描电镜的研究表明，自由石墨作为固体润滑剂在涂层样品的证据。关键词:HVOF热喷涂;摩擦学;emxr;残余应力;拉曼光谱致谢作者衷心感谢焦特布尔Metallizing equipment Co. ppt . Ltd.在样品制备方面的支持。作者还想感谢德里DTU精密制造实验室和斯利那加NIT摩擦学中心的管理人员和工作人员，他们提供了摩擦学测试和材料表征设施。披露声明作者未报告潜在的利益冲突。作者贡献:ssonia Dangi:概念化，数据采集，起草，审查和编辑手稿(第一作者)。R S Walia:构思，审查和编辑手稿(合著者)。N M Suri:概念化，审查和编辑手稿(合著者)。Sumit Chaudhary:概念化，数据获取，审查和编辑手稿(共同作者和通讯作者)。

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来源期刊

Transactions of The Institute of Metal Finishing 工程技术-材料科学：膜

CiteScore

3.40

自引率

10.50%

发文量

审稿时长

3 months

期刊介绍： Transactions of the Institute of Metal Finishing provides international peer-reviewed coverage of all aspects of surface finishing and surface engineering, from fundamental research to in-service applications. The coverage is principally concerned with the application of surface engineering and coating technologies to enhance the properties of engineering components and assemblies. These techniques include electroplating and electroless plating and their pre- and post-treatments, thus embracing all cleaning pickling and chemical conversion processes, and also complementary processes such as anodising. Increasingly, other processes are becoming important particularly regarding surface profile, texture, opacity, contact integrity, etc.