螺柱和线弧增材制造--开发用于大规模晶格结构高生产率增材制造的组合工艺

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Advanced Joining Processes Pub Date : 2024-01-18 DOI:10.1016/j.jajp.2024.100189
F. Riegger, D.L. Wenzler, M.F. Zaeh
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引用次数: 0

摘要

金属大尺度自由形态晶格结构可通过线弧快速成型技术(WAAM)制造。这些结构尤其适用于土木工程领域,如轻质结构件和加固结构。通过拉弧螺柱焊接(DASW)扩展 WAAM 是高效增材制造晶格结构的一种可行方法。在这种被称为螺柱和线弧增材制造(SWAAM)的创新组合工艺中,WAAM 用于生产几何形状复杂的晶格段(如节点),DASW 用于生产直线段。本文介绍了概念验证,通过机器人测试装置展示了这种新方法的可行性。使用 WAAM 和 SWAAM 生产了直径为 8 毫米的棒材试样。测量了试样在生产过程中的温度变化及其生产时间。在距离焊接区 10 毫米处,WAAM 第一层的最高温度为 343 °C,而 SWAAM 为 213 °C。与纯 WAAM 工艺相比,混合工艺的特定测试几何形状的生产时间缩短了 57.7%。这证明,通过使用螺柱减少焊接操作可以减少热输入、降低工艺温度并提高生产率。
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Stud and wire arc additive manufacturing—Development of a combined process for the high-productivity additive manufacturing of large-scale lattice structures

Metallic large-scale freeform lattice structures can be manufactured by wire arc additive manufacturing (WAAM). These structures are especially interesting for applications in civil engineering, such as lightweight structural elements and reinforcement structures. One promising approach for the efficient additive manufacturing of lattice structures is extending WAAM through drawn-arc stud welding (DASW). In this innovative combined process, called stud and wire arc additive manufacturing (SWAAM), WAAM is used for producing geometrically complex lattice segments (e.g., nodes) and DASW for straight segments. This paper presents the proof of concept showing the feasibility of this novel approach with a robotic test setup. Specimens consisting of bars with a diameter of 8 mm were produced with WAAM and SWAAM. The temperature development in the samples during manufacturing and their production time were measured. WAAM resulted for the first layer in a maximum temperature of 343 °C at a distance of 10 mm to the weld zone, while SWAAM showed 213 °C. The production time of a given test geometry was reduced by 57.7 % for the hybrid process compared to a pure WAAM manufacturing. This proves that reducing the welding operations by using studs decreases the heat input, lowers the process temperatures, and increases the production rate.

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来源期刊
CiteScore
7.10
自引率
9.80%
发文量
58
审稿时长
44 days
期刊最新文献
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