Experimental and analytical investigations of the removal of spatters by various process gases during the powder bed fusion of metals using a laser beam
IF 4.4
Q2 ENGINEERING, MANUFACTURING
引用次数: 0
Abstract
Abstract The powder bed fusion of metals using a laser beam (PBF-LB/M) is increasingly being utilized in industrial applications. This is due to several advantages over conventional manufacturing processes when it comes to the fabrication of complex part designs. However, the process still poses various challenges that have to be overcome. One of these challenges is the formation of a significant amount of spatters and fumes. These could attenuate the laser beam or decrease the powder reusability. To lower their negative impact on the process and the mechanical properties of the parts, a process gas flow is used in PBF-LB/M to remove these by-products from the processing zone. This study was, therefore, dedicated to investigating the potential of various gases on the removal of spatters. The focus was placed on argon, helium, and their mixtures. After theoretical considerations determining the range of applicable gas flow velocities, the experimental results unveiled the real spread of spatters over the powder bed and their characteristics. Whilst the removal of spatters was found to be worse for an argon–helium gas mixture at comparable gas flow velocities, increasing the velocity turned out to be a proper measure to enhance the removal for low-density gases. At this flow condition, the use of the argon–helium gas mixture led to a similar removal of spatters and the creation of a lower spatter mass in total (reduced to 40%) compared to argon.用激光束对金属粉末床熔合过程中不同工艺气体去除飞溅物的实验和分析研究
摘要激光粉末床熔融技术在工业上的应用越来越广泛。当涉及到复杂零件设计的制造时,这是由于与传统制造工艺相比的几个优点。然而,这一进程仍然提出了必须克服的各种挑战。其中一个挑战是形成大量的飞溅物和烟雾。这些会使激光束衰减或降低粉末的可重复使用性。为了降低它们对工艺和零件机械性能的负面影响,在PBF-LB/M中使用工艺气流将这些副产物从加工区域中去除。因此,本研究致力于调查各种气体在清除飞溅物方面的潜力。重点放在氩、氦和它们的混合物上。在理论考虑确定了适用的气流速度范围后,实验结果揭示了飞溅物在粉末床上的真实扩散及其特征。虽然在相当的气体流速下,氩气-氦气混合物对飞溅物的去除效果较差,但增加流速是提高低密度气体去除效果的适当措施。在这种流动条件下,与氩气相比,使用氩气-氦气混合物可以消除类似的飞溅物,并产生更低的飞溅物质量(减少到40%)。
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来源期刊
Progress in Additive Manufacturing
Engineering-Industrial and Manufacturing Engineering
CiteScore
7.20
自引率
0.00%
发文量
113
期刊介绍:
Progress in Additive Manufacturing promotes highly scored scientific investigations from academia, government and industry R&D activities. The journal publishes the advances in the processing of different kinds of materials by well-established and new Additive Manufacturing (AM) technologies. Manuscripts showing the progress in the processing and development of multi-materials by hybrid additive manufacturing or by the combination of additive and subtractive manufacturing technologies are also welcome. Progress in Additive Manufacturing serves as a platform for scientists to contribute full papers as well as review articles and short communications analyzing aspects ranging from data processing (new design tools, data formats), simulation, materials (ceramic, metals, polymers, composites, biomaterials and multi-materials), microstructure development, new AM processes or combination of processes (e.g. additive and subtractive, hybrid, multi-steps), parameter and process optimization, new testing methods for AM parts and process monitoring. The journal welcomes manuscripts in several AM topics, including: • Design tools and data format • Material aspects and new developments • Multi-material and composites • Microstructure evolution of AM parts • Optimization of existing processes • Development of new techniques and processing strategies (combination subtractive and additive methods, hybrid processes) • Integration with conventional manufacturing techniques • Innovative applications of AM parts (for tooling, high temperature or high performance applications) • Process monitoring and non-destructive testing of AM parts • Speed-up strategies for AM processes • New test methods and special features of AM parts
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