Hardness and Texture of Electrolytic Copper Processed by ECAP at Ambient and Warm Temperature

VETOR - Revista de Ciências Exatas e Engenharias Pub Date : 2021-12-17 DOI:10.14295/vetor.v31i2.13743

Hiron Akira Yamada Magalhães, T. Souza, R. Cardoso, Bruno Rangel Silva, L. Brandão

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Abstract

Among several severe plastic deformation (SPD) methods, the Equal Channel Angular Pressing (ECAP) process is one of the most popular. This process's main characteristic is producing materials with ultra-fine or nanometric grains. Due to these microstructural changes, it is possible to improve mechanical properties such as strength and ductility. In this perspective, the aim of the present work was to evaluate the variations of the mechanical hardness property associated with microstructural and textural changes of pure copper as a function of its processing by SPD via ECAP. For this, the material was submitted to four passes through routes A (the sample is repetitively pressed without any rotation between each pass) and Bc (the sample is rotated in the same sense by 90° between each pass) at cold and warm temperatures. Through the obtained result, it was verified that the ambient temperature of the Bc route was the one that promoted greater homogeneity in the microstructure and weakening of the texture after the fourth pass. On the other hand, warm processing of copper by ECAP promoted a softening of the samples and a homogeneous distribution of hardness in both routes.

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常温和常温下ECAP处理电解铜的硬度和织构

在几种严重塑性变形(SPD)方法中，等通道角挤压(ECAP)工艺是最受欢迎的方法之一。该工艺的主要特点是生产具有超细或纳米颗粒的材料。由于这些微观结构的变化，有可能提高机械性能，如强度和延展性。从这个角度来看，本工作的目的是评估纯铜的机械硬度性能的变化与微观组织和织构变化有关，这是通过ECAP进行SPD加工的函数。为此，材料在冷热温度下通过路线A(样品在每次通过之间重复按压而不旋转)和Bc(样品在每次通过之间以相同的意义旋转90°)进行四次传递。通过得到的结果，验证了Bc路线的环境温度是促进四道次后组织均匀性增强和织构弱化的温度。另一方面，通过ECAP对铜进行温加工，促进了样品的软化和两种路径的硬度分布均匀。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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VETOR - Revista de Ciências Exatas e Engenharias

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