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多步致密化法制备的Al-TiC复合带材的微观结构与摩擦学行为

Microstructure and tribological behavior of Al-TiC composite strips fabricated by a multi-step densification method.

作者信息

Habba Mohamed I A, Barakat Waheed S, Elnekhaily Sarah A, Hamid F S

机构信息

Mechanical Department, Faculty of Technology and Education, Suez University, Suez, 43221, Egypt.

Metallurgical and Materials Engineering Department, Faculty of Petroleum and Mining Engineering, Suez University, Suez, 43221, Egypt.

出版信息

Sci Rep. 2024 Sep 5;14(1):20767. doi: 10.1038/s41598-024-70560-x.

DOI:10.1038/s41598-024-70560-x
PMID:39237537
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11377578/
Abstract

This study aims to enhance the tribological properties of automotive applications by examining the effects of TiC content on the microstructure, mechanical properties, and wear behavior. This study investigates the production of Al-TiC composite strips using a novel multi-step densification process combining mechanical alloying and hot rolling with TiC concentrations ranging from 0 to 12 vol%. The novelty of this work lies in its comprehensive approach to developing and analyzing Al-TiC composite strips using a multistep densification method. This study integrates microstructural analysis, mechanical property evaluation, and detailed tribological behavior assessment under different wear loads (5-25 N). A key innovation is the application of the Abbott Firestone method to analyze worn surfaces, providing insights into optimal wear conditions. The study reveals that increasing the TiC content to 12 vol% significantly improves densification, hardness (up to 268.8% increase), and wear resistance (up to 95% improvement at a 5N load). Dry ball-on-flat sliding wear tests at loads of 5-25N demonstrate that TiC particles hindered complete delamination wear in the composite strips. The Abbott Firestone method analysis of worn surfaces indicated an optimal exploitation zone in the Al-6 vol% TiC composite at both low and high wear loads. This comprehensive approach provides valuable insights into optimizing Al-TiC composites for enhanced performance in automotive components that require improved wear resistance.

摘要

本研究旨在通过研究TiC含量对微观结构、力学性能和磨损行为的影响,提高汽车应用中的摩擦学性能。本研究采用一种新颖的多步致密化工艺来研究Al-TiC复合带材的生产,该工艺将机械合金化和热轧相结合,TiC浓度范围为0至12体积%。这项工作的新颖之处在于其采用多步致密化方法开发和分析Al-TiC复合带材的综合方法。本研究整合了微观结构分析、力学性能评估以及在不同磨损载荷(5-25 N)下详细的摩擦学行为评估。一个关键创新是应用阿伯特-费尔斯通方法来分析磨损表面,从而深入了解最佳磨损条件。研究表明,将TiC含量提高到12体积%可显著改善致密化、硬度(提高高达268.8%)和耐磨性(在5 N载荷下提高高达95%)。在5-25 N载荷下进行的干态球-平面滑动磨损试验表明,TiC颗粒阻碍了复合带材中的完全分层磨损。对磨损表面的阿伯特-费尔斯通方法分析表明,在低磨损载荷和高磨损载荷下,Al-6体积% TiC复合材料中均存在一个最佳利用区域。这种综合方法为优化Al-TiC复合材料以提高需要改善耐磨性的汽车零部件性能提供了有价值的见解。

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