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使用正电子湮没技术对经冲击喷丸处理的镍合金元素表面特性进行分析。

Analysis of Surface Properties of Nickel Alloy Elements Exposed to Impulse Shot Peening with the Use of Positron Annihilation.

作者信息

Skoczylas Agnieszka, Zaleski Kazimierz, Zaleski Radosław, Gorgol Marek

机构信息

Department of Production Engineering, Faculty of Mechanical Engineering, Lublin University of Technology, 36 Nadbystrzycka, 20-618 Lublin, Poland.

Physics and Computer Science, Institute of Physics, Department of Materials Physics, Faculty of Mathematics, Maria Curie-Sklodowska University, Maria Curie-Sklodowskiej Sq. 1, 20-031 Lublin, Poland.

出版信息

Materials (Basel). 2021 Nov 30;14(23):7328. doi: 10.3390/ma14237328.

DOI:10.3390/ma14237328
PMID:34885482
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8658380/
Abstract

The paper presents the results of experimental studies on the impact of impulse shot peening parameters on surface roughness (Sa, Sz, Sp, Sv), surface layer microhardness, and the mean positron lifetime (τ). In the study, samples made of the Inconel 718 nickel alloy were subjected to impulse shot peening on an originally designed stand. The variable factors of the experiment included the impact energy, the diameter of the peening element, and the number of impacts per unit area. The impulse shot peening resulted in changes in the surface structure and an increase in surface layer microhardness. After the application of impulse shot peening, the analyzed roughness parameters increased in relation to post-milling values. An increase in microhardness was obtained, i.e., from 27 HV 0.05 to 108 HV 0.05 at the surface, while the maximum increase the microhardness occur at the depth from 0.04 mm to 0.08 mm. The changes in the physical properties of the surface layer were accompanied by an increase in the mean positron lifetime τ. This is probably related to the increased positron annihilation in point defects. In the case of small surface deformations, the increase in microhardness was accompanied by a much lower increase in τ, which may indicate a different course of changes in the defect structure consisting mainly in modification of the dislocation system. The dependent variables were subjected to ANOVA analysis of variance (it was one-factor analysis), and the effect of independent variables was evaluated using post-hoc tests (Tukey test)

摘要

本文介绍了关于脉冲喷丸参数对表面粗糙度(Sa、Sz、Sp、Sv)、表面层显微硬度和平均正电子寿命(τ)影响的实验研究结果。在该研究中,由因科镍合金718制成的样品在最初设计的试验台上进行脉冲喷丸处理。实验的可变因素包括冲击能量、喷丸元件的直径以及单位面积的冲击次数。脉冲喷丸导致表面结构发生变化,并使表面层显微硬度增加。在进行脉冲喷丸处理后,所分析的粗糙度参数相对于铣削后的值有所增加。获得了显微硬度的增加,即表面处从27 HV 0.05增加到108 HV 0.05,而显微硬度的最大增加出现在深度为0.04 mm至0.08 mm处。表面层物理性能的变化伴随着平均正电子寿命τ的增加。这可能与点缺陷中正电子湮灭的增加有关。在表面变形较小的情况下,显微硬度的增加伴随着τ的增加要低得多,这可能表明缺陷结构的变化过程不同,主要在于位错系统的改变。对因变量进行了方差分析(单因素分析),并使用事后检验(Tukey检验)评估自变量的影响

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