The Effects of ArC Voltage and Shielding Gas Type on the Microstructure of Wire ArC Additively Manufactured 2209 Duplex Stainless Steel

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Advances in Materials Science Pub Date : 2023-12-01 DOI:10.2478/adms-2023-0023

D. Kemény, Bence Sándor, B. Varbai, L. Katula

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Abstract

Abstract Duplex stainless steels (DSSs) are widely used due to their corrosion resistance. Austenite and ferrite determine the excellent properties. Ferrite provides strength and good corrosion resistance, while austenite provides toughness and weldability. During our research, samples were produced with ER 2209 duplex steel wire using wire arc additive manufacturing (WAAM). Two different 17 V and 19 V arc voltages were used during the production. Two shielding gases were used for each voltage: M12-ArC-2.5 and M12-ArHeC-20/2. The research aimed to determine the ferrite ratio as a function of the welding parameters. The ferrite (or austenite) content must be between 30% and 70% for duplex stainless steel welds, according to the ISO 17781 standard. Based on our research, it can be stated that the austenite ratio increases as the voltage increases, thus failing to fulfill the standard's requirements. The helium content reduced the ferrite ratio even when the 17 V voltage was used due to the gas's higher ionization potential. During the metallographic examination, our welded samples met the standard requirements for the austenite content for 17 V arc voltage and M12-ArC-2.5 shielding gas. The ferrite content in the entire sample cross-section fell between 30-42% during feritscope and image analysis measurements. These welding parameters can be recommended for industrial applications.

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氩弧焊电压和屏蔽气体类型对线材氩弧焊加成制造 2209 双相不锈钢微观结构的影响

摘要双相不锈钢（DSS）因其耐腐蚀性能而被广泛使用。奥氏体和铁素体决定了其优异的性能。铁素体提供强度和良好的耐腐蚀性，而奥氏体则提供韧性和可焊性。在研究过程中，我们使用线弧快速成型技术（WAAM）用 ER 2209 双相钢线制作了样品。生产过程中使用了两种不同的 17 V 和 19 V 电弧电压。每种电压使用两种屏蔽气体：研究旨在确定铁素体比率与焊接参数的函数关系。根据 ISO 17781 标准，双相不锈钢焊缝的铁素体（或奥氏体）含量必须在 30% 至 70% 之间。根据我们的研究，奥氏体比率会随着电压的增加而增加，因此达不到标准要求。由于氦气的电离电位较高，即使使用 17 V 电压，氦气含量也会降低铁素体比率。在金相检查中，我们的焊接样品在 17 V 电弧电压和 M12-ArC-2.5 保护气体条件下的奥氏体含量符合标准要求。在铁素体显微镜和图像分析测量中，整个样品横截面的铁素体含量在 30-42% 之间。这些焊接参数可推荐用于工业应用。

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

Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-

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7.70%

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