Investigation into Stress Relaxation and Creep Rate of C47200 Copper Alloy

S. Akande, Tuoyo Ikomi, T. Azeez, O. Ikumapayi
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Abstract

Copper alloys have high thermal conductivity, relatively high mechanical strength, and toughness over a wide range of temperature; hence they are highly sorted for complex structural applications that required extreme heat flux under load. Creep of materials is classically associated with time-dependent plasticity under a constant stress/load at an elevated temperature, often greater than the absolute melting temperature. This research is aimed to study the evaluation of stress and creep rate in copper, identifying the mechanisms at which copper can easily be exposed to stress and creep deformations in structures. A 12 mm diameter copper rod with the composition of 52.05 % CuO and 30.26 % SnO2 was procured locally. Samples from the procured rod were heat treated to 650°C for 30 minutes and cooled in the still air as well as inside the furnace. Creep test was carried out at 760uC with a constant load corresponding to an initial stress (between 1.5 MPa and 350 MPa) and stress relation was carried out on a 98 kN capacity stress relaxation frame (from 350 MPa to 300 MPa). Rockwell hardness test and metallographic analysis (at 200 mm) were also conducted on the heat treated and unheated control samples. It was established that heat treatment reduced the hardness property of stress relaxed copper, accelerated the stress relaxation process up to 60 %, speed up both primary creep rate and the tertiary creep rate as well altered the linear creep pattern and behaviour.
C47200 铜合金的应力松弛和蠕变率研究
铜合金具有较高的热导率、相对较高的机械强度以及在较宽温度范围内的韧性,因此非常适用于在负载下需要极高热流量的复杂结构应用。材料蠕变通常是指在温度升高(通常高于绝对熔化温度)的恒定应力/载荷作用下产生的随时间变化的塑性。本研究旨在研究铜的应力和蠕变率评估,确定铜在结构上容易受到应力和蠕变变形的机理。研究人员从当地采购了一根直径为 12 毫米的铜棒,其成分为 52.05 % 的氧化铜和 30.26 % 的二氧化锡。将铜棒样品在 650°C 的温度下热处理 30 分钟,然后在静止空气和炉内冷却。蠕变试验在 760uC 温度下进行,恒定载荷对应初始应力(1.5 兆帕至 350 兆帕),应力关系在 98 kN 容量的应力松弛框架上进行(从 350 兆帕至 300 兆帕)。此外,还对热处理和未加热的对照样品进行了洛氏硬度测试和金相分析(200 毫米)。结果表明,热处理降低了应力松弛铜的硬度特性,加速了应力松弛过程达 60%,加快了一级蠕变速率和三级蠕变速率,并改变了线性蠕变模式和行为。
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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CiteScore
1.20
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