CFD Investigation of a Co-Flow Nozzle for Cold Spray Additive Manufacturing Applications

IF 3.2 3区材料科学 Q2 MATERIALS SCIENCE, COATINGS & FILMS

Journal of Thermal Spray Technology Pub Date : 2024-04-22 DOI:10.1007/s11666-024-01764-w

Amit Kumar Sharma, Ashish Vashishtha, Dean Callaghan, Srinivasan Rao Bakshi, M. Kamaraj, Ramesh Raghavendra

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Abstract

This current work evaluates the efficacy of a co-flow nozzle for cold spray applications with the aim of mitigating nozzle clogging issues, which can occur during long-duration operations, by replacing the solid wall of a divergent nozzle section with an annular co-flow fluid boundary. Simulations were conducted on high-pressure nitrogen flowing through convergent–divergent (C–D) axisymmetric nozzles, with a stagnation pressure of 6 MPa and a stagnation temperature of 1273 K. In these simulations, Inconel 718 particles of varying sizes (15 µm to 35 µm) were modeled using a 2-way Lagrangian technique, and the model’s accuracy was confirmed through validation against experimental results. An annular co-flow nozzle with a circular cross section and straight passage covering the primary C–D nozzle has been designed and modeled for cold spray application. Co-flow was introduced to the reduced nozzle length to compensate for particle velocity loss at higher operating conditions. It was found that co-flow facilitates momentum preservation for primary flow by providing an annular gas boundary, resulting in increased particle speed for a longer axial distance beyond the nozzle exit of the reduced divergent length nozzle. The particle acceleration performance of the reduced divergent section nozzle, when combined with co-flow, is comparable to the original length nozzle.

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用于冷喷增材制造应用的同流喷嘴的 CFD 研究

本研究评估了冷喷雾应用中同流喷嘴的功效，目的是用环形同流流体边界取代发散喷嘴部分的实心壁，从而缓解长时间运行过程中可能出现的喷嘴堵塞问题。在这些模拟中，使用双向拉格朗日技术对不同尺寸（15 微米至 35 微米）的 Inconel 718 粒子进行了建模，并通过与实验结果的对比验证确认了模型的准确性。为冷喷雾应用设计并模拟了一个环形同流喷嘴，其横截面为圆形，直通道覆盖主 C-D 喷嘴。在缩短的喷嘴长度上引入了同流，以补偿较高工作条件下的颗粒速度损失。研究发现，通过提供环形气体边界，同向流有利于保持主流的动量，从而在缩短发散长度喷嘴出口以外的更长轴向距离上提高粒子速度。缩小发散段喷嘴的粒子加速性能在与共流相结合时与原始长度喷嘴相当。

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

Journal of Thermal Spray Technology 工程技术-材料科学：膜

CiteScore

5.20

自引率

25.80%

发文量

198

审稿时长

2.6 months

期刊介绍： From the scientific to the practical, stay on top of advances in this fast-growing coating technology with ASM International''s Journal of Thermal Spray Technology. Critically reviewed scientific papers and engineering articles combine the best of new research with the latest applications and problem solving. A service of the ASM Thermal Spray Society (TSS), the Journal of Thermal Spray Technology covers all fundamental and practical aspects of thermal spray science, including processes, feedstock manufacture, and testing and characterization. The journal contains worldwide coverage of the latest research, products, equipment and process developments, and includes technical note case studies from real-time applications and in-depth topical reviews.