Thermal Plasma Spheroidization and Characterization of Stainless Steel Powders Using Direct Current Plasma Technology

Plasma Pub Date : 2024-01-23 DOI:10.3390/plasma7010006

P. Iovane, C. Borriello, Giuseppe Pandolfi, S. Portofino, Gabriella Rametta, Loredana Tammaro, Nicola Fedele, S. Galvagno

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Abstract

The production of spherical powders has recently registered a boost due to the need to fabricate new printing materials for Additive Manufacturing applications, from polymers and resins to metals and ceramics. Among these materials, stainless steels powders play a leading role, since they are widely used in industry and everyday life; indeed, micron-sized spherical stainless steel powders have specific characteristics and are considered as one of the best candidates for Additive Manufacturing systems and for application in a wide range of sectors. In this paper, stainless steel 316 L powders were used to explore and identify the best process parameters of a thermal plasma process able to produce spherical powders for Additive Manufacturing applications. X-ray Diffraction, Scanning Electron Microscopy, Particle Size Distribution and Flowability analysis were performed to characterize reagents and products. Powders with a high circularity (>0.8) and improved flowability (<30 s/50 g) were successfully obtained. The collected results were compared with data available from the literature to identify the potential use of the spherical produced powders.

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利用直流等离子体技术对不锈钢粉末进行热等离子体球化和表征

由于需要为快速成型制造应用制造从聚合物和树脂到金属和陶瓷的新型打印材料，球形粉末的生产最近得到了迅猛发展。在这些材料中，不锈钢粉末起着主导作用，因为它们被广泛应用于工业和日常生活中；事实上，微米大小的球形不锈钢粉末具有特殊的特性，被认为是增材制造系统的最佳候选材料之一，可广泛应用于各个领域。本文使用 316 L 不锈钢粉末来探索和确定热等离子工艺的最佳工艺参数，该工艺能够为快速成型制造应用生产球形粉末。对试剂和产品进行了 X 射线衍射、扫描电子显微镜、粒度分布和流动性分析。成功获得了圆度高（>0.8）、流动性更好（<30 s/50 g）的粉末。收集的结果与文献中的数据进行了比较，以确定球形粉末的潜在用途。

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

Plasma

CiteScore

2.30

自引率

0.00%

发文量