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添加0.20%铍(Be)的CuAlNiFe合金在铸后热处理和锻造工艺后的摩擦学行为及微观结构性能影响

Effect of 0.20% Beryllium (Be)-Added CuAlNiFe Alloy on Tribological Behavior and Microstructural Properties After Post-Casting Heat Treatment and Forging Process.

作者信息

Babay Khaled A A, Esen Ismail, Sagiroglu Selami, Ahlatci Hayrettin, Keskin Esma

机构信息

Mechanical Engineering Department, Karabuk University, 78050 Karabuk, Turkey.

Metallurgical and Materials Engineering Department, Karabuk University, 78050 Karabuk, Turkey.

出版信息

Materials (Basel). 2024 Nov 25;17(23):5757. doi: 10.3390/ma17235757.

DOI:10.3390/ma17235757
PMID:39685193
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11642135/
Abstract

This study explored how post-casting heat treatment and forging affected the tribological and microstructural characteristics of 0.20% beryllium (Be)-added CuAlNiFe alloys. The heat-treated CuAlNiFe microstructure exhibits a copper-rich α (alpha)-solid-solution phase, a martensitic β (beta)-phase, and diverse intermetallic κ (kappa)-phases, such as leaf-shaped κ, thin κ, and black globs. Adding 0.20% beryllium to CuAlNiFe alloys enhanced the dendritic arm thickness, needle-like shape, and κ-phase quantities. Significant κ- and κ-phase precipitation was observed in the tempered β-phase. Beryllium improves the aluminum matrix's microstructure. Forging greatly reduced the microstructural thickness of CuAlNiFe and CuAlNiFe-0.20% Be alloys. The forging process also developed new κ-phases. Wear resistance and hardness improved with beryllium. The CuAlNiFe-0.20% Be alloy had the highest hardness values (235.29 and 255.08 HB) after solution treatment (ST) and tempering (T) after casting and forging (F). The CuAlNiFe-0.20% alloy with Be added had the best wear after solution treatment, tempering, and forging. The CuAlNiFe-0.20% Be alloy demonstrated a 0.00272 g weight loss, a 1.36 × 10 g/N*m wear rate, and a 0.059 friction coefficient at 10,000 m after forging (F).

摘要

本研究探讨了铸造后热处理和锻造如何影响添加0.20%铍(Be)的CuAlNiFe合金的摩擦学和微观结构特征。热处理后的CuAlNiFe微观结构呈现出富铜的α(阿尔法)固溶体相、马氏体β(贝塔)相以及多种金属间κ(卡帕)相,如叶状κ相、薄κ相和黑色球状相。向CuAlNiFe合金中添加0.20%的铍可增加枝晶臂厚度、针状形状以及κ相数量。在回火β相中观察到大量κ相和κ相析出。铍改善了铝基体的微观结构。锻造极大地减小了CuAlNiFe和CuAlNiFe-0.20%Be合金的微观结构厚度。锻造过程还产生了新的κ相。添加铍后耐磨性和硬度提高。添加0.20%Be的CuAlNiFe合金在铸造和锻造后进行固溶处理(ST)和回火(T)后具有最高硬度值(235.29和255.08 HB)。添加铍的CuAlNiFe-0.20%合金在固溶处理、回火和锻造后具有最佳耐磨性。锻造后(F),添加0.20%Be的CuAlNiFe合金在10000 m时失重0.00272 g,磨损率为1.36×10 g/N*m,摩擦系数为0.059。

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