Measurement Uncertainty of Surface Temperature Distributions for Laser Powder Bed Fusion Processes.

IF 1.3 4区 工程技术 Q3 INSTRUMENTS & INSTRUMENTATION Journal of Research of the National Institute of Standards and Technology Pub Date : 2021-08-10 eCollection Date: 2021-01-01 DOI:10.6028/jres.126.013
David C Deisenroth, Sergey Mekhontsev, Brandon Lane, Leonard Hanssen, Ivan Zhirnov, Vladimir Khromchenko, Steven Grantham, Daniel Cardenas-Garcia, Alkan Donmez
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Abstract

This paper describes advances in measuring the characteristic spatial distribution of surface temperature and emissivity during laser-metal interaction under conditions relevant for laser powder bed fusion (LPBF) additive manufacturing processes. Detailed descriptions of the measurement process, results, and approaches to determining uncertainties are provided. Measurement uncertainties have complex dependencies on multiple process parameters, so the methodology is demonstrated on one set of process parameters and one material. Well-established literature values for high-purity nickel solidification temperature and emissivity at the solidification temperature were used to evaluate the predicted uncertainty of the measurements. The standard temperature measurement uncertainty is found to be approximately 0.9% of the absolute temperature (16 AC), and the standard relative emissivity measurement uncertainty is found to be approximately 8% at the solidification point of high-purity nickel, both of which are satisfactory. This paper also outlines several potential sources of test uncertainties, which may require additional experimental evaluation. The largest of these are the metal vapor and ejecta that are produced as process by-products, which can potentially affect the imaging quality, reflectometry results, and thermal signature of the process, while also affecting the process of laser power delivery. Furthermore, the current paper focuses strictly on the uncertainties of the emissivity and temperature measurement approach and therefore does not detail a variety of uncertainties associated with experimental controls that must be evaluated for future generation of reference data.

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激光粉末床熔融过程表面温度分布的测量不确定性。
本文介绍了在激光粉末床熔融(LPBF)快速成型制造工艺的相关条件下,测量激光与金属相互作用过程中表面温度和发射率空间分布特征的进展。文中详细描述了测量过程、结果以及确定不确定性的方法。测量的不确定性与多个工艺参数有着复杂的关系,因此该方法只针对一组工艺参数和一种材料进行演示。高纯度镍凝固温度和凝固温度下发射率的既定文献值用于评估测量的预测不确定性。结果发现,标准温度测量不确定度约为绝对温度(16 AC)的 0.9%,而高纯度镍凝固点的标准相对发射率测量不确定度约为 8%,两者均令人满意。本文还概述了测试不确定性的几个潜在来源,这可能需要额外的实验评估。其中最大的不确定因素是作为工艺副产品产生的金属蒸气和喷出物,它们可能会影响成像质量、反射测量结果和工艺的热特征,同时也会影响激光功率传输过程。此外,本文严格侧重于发射率和温度测量方法的不确定性,因此没有详细介绍与实验控制相关的各种不确定性,这些不确定性必须在未来生成参考数据时进行评估。
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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来源期刊
自引率
33.30%
发文量
10
审稿时长
>12 weeks
期刊介绍: The Journal of Research of the National Institute of Standards and Technology is the flagship publication of the National Institute of Standards and Technology. It has been published under various titles and forms since 1904, with its roots as Scientific Papers issued as the Bulletin of the Bureau of Standards. In 1928, the Scientific Papers were combined with Technologic Papers, which reported results of investigations of material and methods of testing. This new publication was titled the Bureau of Standards Journal of Research. The Journal of Research of NIST reports NIST research and development in metrology and related fields of physical science, engineering, applied mathematics, statistics, biotechnology, information technology.
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