Timed Thermodynamic Process Model Applied to Submerged Arc Welding Modified by Aluminium-Assisted Metal Powder Alloying

IF 2.1 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
JOM Pub Date : 2024-08-08 DOI:10.1007/s11837-024-06804-y
Theresa Coetsee, Frederik Johannes De Bruin
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Abstract

An EERZ (effective equilibrium reaction zone) model was applied to the modified SAW (submerged arc welding) process to simulate the SAW process metallurgy in the gas-slag-metal reaction system. The SAW process was modified by adding Al as a de-oxidizer with alloying metal powders of Cr, Cu, and Ti. The static gas-slag-metal equilibrium model can accurately calculate the weld metal oxygen content (ppm O) for conventional SAW but not for the modified SAW process. The static equilibrium model overpredicts the reaction of Al. EERZ model runs were made for 2000–2500°C because this is the reported temperature range in the SAW arc cavity. The weld metal composition was adequately calculated, especially the weld metal ppm O, at the following effective equilibrium temperatures: 2400°C for Al-Cr additions, 2200°C for Al-Cr-Cu additions, and 2000°C for Al-Cr-Cu-Ti additions. Model results show that Ti metal powder can serve a de-oxidizer role in the presence of Al, resulting in Ti loss to the slag. Ti is also lost to the gas phase as TiF3(g) and TiF2(g) compared to little loss of Cr to the gas phase as Cr(g) and CrO to the slag phase.

Abstract Image

应用于铝辅助金属粉末合金化改性埋弧焊的定时热力学过程模型
将 EERZ(有效平衡反应区)模型应用于改良型 SAW(埋弧焊)工艺,以模拟气体-熔渣-金属反应系统中的 SAW 工艺冶金。通过添加 Al 作为脱氧剂以及 Cr、Cu 和 Ti 等合金金属粉末,对 SAW 工艺进行了改进。静态气-渣-金属平衡模型可以准确计算出传统 SAW 的焊缝金属氧含量(ppm O),但不能准确计算出改良 SAW 工艺的焊缝金属氧含量(ppm O)。静态平衡模型对铝的反应预测过高。EERZ 模型的运行温度为 2000-2500°C,因为这是报告的 SAW 电弧腔的温度范围。在以下有效平衡温度下,对焊接金属成分进行了充分计算,尤其是焊接金属ppm O:添加 Al-Cr 时为 2400°C,添加 Al-Cr-Cu 时为 2200°C,添加 Al-Cr-Cu-Ti 时为 2000°C。模型结果表明,Ti 金属粉末在铝的存在下可以起到脱氧剂的作用,导致 Ti 损失到炉渣中。Ti 也会以 TiF3(g) 和 TiF2(g) 的形式流失到气相中,相比之下,Cr 则以 Cr(g) 的形式流失到气相中,CrO 则流失到渣相中。
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来源期刊
JOM
JOM 工程技术-材料科学:综合
CiteScore
4.50
自引率
3.80%
发文量
540
审稿时长
2.8 months
期刊介绍: JOM is a technical journal devoted to exploring the many aspects of materials science and engineering. JOM reports scholarly work that explores the state-of-the-art processing, fabrication, design, and application of metals, ceramics, plastics, composites, and other materials. In pursuing this goal, JOM strives to balance the interests of the laboratory and the marketplace by reporting academic, industrial, and government-sponsored work from around the world.
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