Understanding the breakup behaviors of liquid jet in gas atomization for powder production

IF 8.4 MATERIALS & DESIGN Pub Date : 2023-03-01 DOI:10.1016/j.matdes.2023.111793

Sheng Luo, Yu Ouyang, Qianglong Wei, Shuyue Lai, Yi Wu, Haowei Wang, Hongze Wang

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引用次数: 1

Abstract

Gas atomization (GA) is the main method to produce metal powders for additive manufacturing (AM) because of its low cost and high efficiency. However, the liquid breakup behaviors in high-speed gas flow during GA remains unclear, especially the primary breakup in the near field and the secondary breakup in the far field. Great difficulty exists in in-situ observation of the interactions between high-speed gas and high-temperature molten metal because of the limitations of the enclosed environment. Here, we built a new GA simulation system with a close-coupled atomizer utilizing liquids with low melting temperature, such as water, glycerin, etc. We use a high-speed camera to capture the evolution of liquid behaviors at various parameters. We first reveal that four primary breakup modes and four secondary breakup modes exist in the GA process, and these breakup modes significantly influence the particle size distribution (PSD) and the defects of the powder. Besides, the breakup modes are clarified by the dimensionless analysis. This manuscript provides an effective experimental platform to understand the breakup behaviors of the liquid jet in GA and suggests the optimal breakup mode for powder production.

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了解粉末生产中气体雾化过程中液体射流的破碎行为

气体雾化(GA)因其成本低、效率高而成为增材制造(AM)金属粉末的主要制备方法。然而，在GA过程中，液体在高速气体流动中的破碎行为尚不清楚，特别是近场的一次破碎和远场的二次破碎。由于密闭环境的限制，高速气体与高温熔融金属相互作用的现场观测存在很大困难。本文利用水、甘油等熔融温度较低的液体，构建了一种具有紧密耦合雾化器的新型遗传仿真系统。我们使用高速摄像机捕捉不同参数下液体行为的演变。研究发现，GA过程中存在4种主要破碎模式和4种次要破碎模式，这些破碎模式显著影响粉末的粒径分布(PSD)和缺陷。此外，通过无量纲分析明确了断裂模式。本文提供了一个有效的实验平台来了解GA中液体射流的破碎行为，并提出了最佳的粉末生产破碎模式。

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MATERIALS & DESIGN

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期刊介绍： Materials and Design is a multidisciplinary journal that publishes original research reports, review articles, and express communications. It covers a wide range of topics including the structure and properties of inorganic and organic materials, advancements in synthesis, processing, characterization, and testing, as well as the design of materials and engineering systems, and their applications in technology. The journal aims to integrate various disciplines such as materials science, engineering, physics, and chemistry. By exploring themes from materials to design, it seeks to uncover connections between natural and artificial materials, and between experimental findings and theoretical models. Manuscripts submitted to Materials and Design are expected to offer elements of discovery and surprise, contributing to new insights into the architecture and function of matter.