混合快速成型技术制造的镍基合金双材料试样的疲劳和断裂情况

Ashok Bhadeliya, Birgit Rehmer, Bernard Fedelich, Torsten Jokisch, Birgit Skrotzki, Jürgen Olbricht
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引用次数: 0

摘要

增材制造与传统工艺的整合,即混合增材制造,扩大了其应用领域,特别是在燃气轮机叶尖的修复方面。然而,增材制造材料中与工艺相关的缺陷、界面形成以及双材料结构中的材料属性不匹配会严重影响部件的疲劳性能。本研究考察了镍基合金双材料试样在高温下的低循环疲劳和疲劳裂纹生长行为,特别是添加剂制造的 STAL15 和铸造合金 247DS。低循环疲劳试验是在 950 ℃ 和 1000 ℃ 的温度条件下,在一系列应变水平(0.3%-0.8%)下进行的,疲劳裂纹生长试验是在 950 ℃、应力比为 0.1 和 -1 的条件下进行的。为了解双材料结构中的疲劳裂纹起始和裂纹生长机制,进行了断面和显微分析。结果一致表明,在加成制造的 STAL15 材料中存在裂纹起始和疲劳断裂现象。值得注意的是,当裂纹从加成制造的 STAL15 材料延伸到垂直定位的界面时,在界面附近观察到了疲劳裂纹生长延迟。这项研究强调了在解释界面疲劳裂纹生长行为时考虑屈服强度不匹配以及残余应力和晶粒结构差异的潜在影响的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fatigue and fracture in dual-material specimens of nickel-based alloys fabricated by hybrid additive manufacturing
The integration of additive manufacturing with traditional processes, termed hybrid additive manufacturing, has expanded its application domain, particularly in the repair of gas turbine blade tips. However, process-related defects in additively manufactured materials, interface formation, and material property mismatches in dual-material structures can significantly impact the fatigue performance of components. This investigation examines the low cycle fatigue and fatigue crack growth behaviors in dual-material specimens of nickel-based alloys, specifically the additively manufactured STAL15 and the cast alloy 247DS, at elevated temperatures. Low cycle fatigue experiments were conducted at temperatures of 950 °C and 1000 °C under a range of strain levels (0.3%–0.8%) and fatigue crack growth tests were conducted at 950 °C with stress ratios of 0.1 and −1. Fractographic and microscopic analyses were performed to comprehend fatigue crack initiation and crack growth mechanisms in the dual-material structure. The results consistently indicated crack initiation and fatigue fracture in the additively manufactured STAL15 material. Notably, fatigue crack growth retardation was observed near the interface when the crack extended from the additively manufactured STAL15 material to the perpendicularly positioned interface. This study highlights the importance of considering yield strength mismatch, as well as the potential effects of residual stresses and grain structure differences, in the interpretation of fatigue crack growth behavior at the interface.
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