Mechanical Properties and Fracture Morphology of In-situ TiB<sub>2</sub> Particle Reinforced Aluminum Matrix Composites

Le Yongkang~1; Chen Dong~1; Zhang Yijie~1; Ma Naiheng~1; Wang Haowei~1; Mao Jianwei~1; Zhang Wenjing~2

Views : 0 下载量: 811 CSCD: 13

Export
Share
Collection
Album

Mechanical Properties and Fracture Morphology of In-situ TiB₂ Particle Reinforced Aluminum Matrix Composites
Issue 8, Pages: 518-520(2006)
Published： 2006 ，
DOI：

扫描看全文

[1]乐永康,陈东,张亦杰,马乃恒,王浩伟,毛建伟,张文静.原位TiB_2颗粒增强铝基复合材料及其力学性能[J].特种铸造及有色合金,2006(08):518-520+463.

Le Yongkang~1, Chen Dong~1, Zhang Yijie~1, et al. Mechanical Properties and Fracture Morphology of In-situ TiB₂ Particle Reinforced Aluminum Matrix Composites. [J]. Special Casting & Nonferrous Alloys (8):518-520(2006)
[1]乐永康,陈东,张亦杰,马乃恒,王浩伟,毛建伟,张文静.原位TiB_2颗粒增强铝基复合材料及其力学性能[J].特种铸造及有色合金,2006(08):518-520+463. DOI：

Le Yongkang~1, Chen Dong~1, Zhang Yijie~1, et al. Mechanical Properties and Fracture Morphology of In-situ TiB₂ Particle Reinforced Aluminum Matrix Composites. [J]. Special Casting & Nonferrous Alloys (8):518-520(2006) DOI：

摘要

对原位反应合成TiB2/A356铝基复合材料微观组织和力学拉伸性能进行了研究。结果表明

原位反应生成的颗粒增强相在复合材料基体中分布均匀

基体与颗粒间的界面洁净。复合材料强度随着颗粒含量的增加显著提高

与基体合金相比

TiB2质量分数为8%的TiB2/A356复合材料强度和弹性模量的提高幅度约为28%

TiB2质量分数为16%的TiB2/A356复合材料强度和弹性模量的提高幅度约为35%。复合材料的断裂主要是由于基体与颗粒界面脱粘

在拉伸应力作用下由此萌生微裂纹并扩展

导致界面处的基体撕裂

从而降低复合材料塑性。

Abstract

Microstructure and mechanical properties of the in-situ synthesized A356/TiB

composites have been investigated. It was revealed that in-situ reinforced particle can be uniformly distributed into the matrix without interfacial reaction

and the strength of the composites is increased with increasing in reinforced particle content. Compared with that of the matrix alloy

the tensile strength and elastic modulus of the composites with 6% and 8% volume fraction are improved by about 28% and 35%

respectively. The fragile fracture occurs in reinforcement clusters and debonding of the interface between particle and matrix are responsible for the initiating and propagating micro-crack

resulting in fracture of matrix in the vicinity of interfaces and decrease of ductility of the composites.