Kamil Bochenek, Siegfried Arneitz, Christof Sommitsch, Michał Basista
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引用次数: 0
摘要
室温下镍铝的断裂韧性较低,这是限制其在飞机发动机中应用的关键问题之一。以前的研究表明,添加少量铼和氧化铝可显著提高热压镍铝的断裂韧性。在这项工作中,采用激光粉末床熔融添加剂技术(LPBF)生产了掺有铼和氧化铝的镍铝。目的是比较 LPBF 和热压(HP)生产的 NiAl-Re-Al2O3 材料的断裂韧性、弯曲强度和显微硬度。结果表明,LPBF 材料的断裂韧性和抗弯强度低于热压材料。LPBF 工艺中的热应力产生的微裂缝是造成这种行为的主要原因。为了改善 LPBF 材料,采用了 HP 后处理。然而,(LPBF + HP)材料的断裂韧性仍然只有 HP 材料 KIC 的 50%。这项研究支持将热压作为添加铼和氧化铝的镍铝的合适加工方法。然而,结合 LPBF 和 HP 的混合方法被证明对未加工的镍铝粉非常有效,使最终材料的断裂韧性优于单一 HP 巩固的材料。
Comparison of Mechanical Properties of Bulk NiAl-Re-Al2O3 Intermetallic Material Manufactured by Laser Powder Bed Fusion and Hot Pressing
The low fracture toughness of NiAl at room temperature is one of the critical issues limiting its application in aircraft engines. It has been previously shown that a small addition of rhenium and alumina significantly improves the fracture toughness of hot-pressed NiAl. In this work, NiAl with an admixture of rhenium and alumina was produced by laser powder bed fusion additive technology (LPBF). The purpose was to compare the fracture toughness, bending strength, and microhardness of the NiAl-Re-Al2O3 material produced by LPBF and hot pressing (HP). Our results show that the LPBF material has lower fracture toughness and bending strength compared to its hot-pressed equivalent. Microcracks generated by thermal stresses during the LPBF process were the primary cause of this behavior. To improve the LPBF material, a post-processing by HP was applied. However, the fracture toughness of the (LPBF + HP) material remained at 50% of the KIC of the HP material. This study supports hot pressing as a suitable processing method for NiAl with rhenium and alumina additions. However, a hybrid approach combining LPBF and HP proved to be highly effective on the raw NiAl powder, resulting in superior fracture toughness of the final material compared to that consolidated by singular HP.
期刊介绍:
ASM International''s Journal of Materials Engineering and Performance focuses on solving day-to-day engineering challenges, particularly those involving components for larger systems. The journal presents a clear understanding of relationships between materials selection, processing, applications and performance.
The Journal of Materials Engineering covers all aspects of materials selection, design, processing, characterization and evaluation, including how to improve materials properties through processes and process control of casting, forming, heat treating, surface modification and coating, and fabrication.
Testing and characterization (including mechanical and physical tests, NDE, metallography, failure analysis, corrosion resistance, chemical analysis, surface characterization, and microanalysis of surfaces, features and fractures), and industrial performance measurement are also covered
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