DIRECT MEASUREMENTS OF LASER ABSORPTIVITY DURING METAL MELT POOL FORMATION ASSOCIATED WITH POWDER BED FUSION ADDITIVE MANUFACTURING PROCESSES

机译：与粉床融合添加剂制造工艺相关的金属熔融池形成期间激光吸收率的直接测量

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Direct calorimetric measurements are used to study the effective optical absorptivity at 1070 nm laser wavelength for bulk and powder coated discs of industrially-relevant metals. Effective absorptivity is plotted as a function of nominal laser power from 30 up to 600 W for scanning velocities of 100, 500 and 1500 mm/s. The absorptivity versus power curves of the bulk materials typically show a reduction in effective absorptivity until the beginning of the formation of a keyhole-type surface depression that is associated with an increased absorption of the laser light in the growing keyhole until a saturation value is reached. For powders, an additional plateau of higher absorptivity can be observed for low laser power, until the curves qualitatively collapse when full melting of the powder tracks is achieved. It is shown that, under conditions associated with laser powder bed fusion additive manufacturing, absorptivity values can vary greatly, and differ from both room temperature powder layer measurements and liquid metal estimates from the literature.

机译：直接量热测量用于研究1070nm激光波长的有效光吸收率，用于工业相关金属的散装和粉末涂层盘。作为扫描速度为100,500和1500mm / s的扫描速度，作为标称激光功率的函数绘制有效吸收率。散装材料的吸收率与功率曲线通常显示出有效吸收率的降低，直到形成键合孔型表面凹陷的开始，该抑郁与生长锁孔中的激光的吸收增加相关，直到达到饱和值。对于粉末，可以观察到额外的更高吸收率的高度吸收性，以便低激光功率，直到达到粉末轨道的全部熔化时曲线定性崩溃。结果表明，在与激光粉末融合添加剂制造相关的条件下，吸收性值可以大大变化，与文献中的室温粉末层测量和液态金属估计不同。

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《International Congress on Applications of Lasers Electro-Optics》|2017年|1(CD-ROM)|共5页
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Manyalibo Matthews; Johannes Trapp; Gabe Guss; Alexander Rubenchik;
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中图分类 TN244-53;
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1. 金属钽添加对激光粉床熔化制备钛合金微观组织和力学性能的影响 [J] . 周立波, 舒京国, 孙金山, 中南大学学报（英文版） . 2021,第004期
2. Direct measurements of laser absorptivity during metal melt pool formation associated with powder bed fusion additive manufacturing processes [J] . Matthews Manyalibo, Trapp Johannes, Guss Gabe, Journal of Laser Applications . 2018,第3期

机译：直接测量与粉末床熔合添加剂制造工艺相关的金属熔池形成过程中的激光吸收率
3. Formation processes for large ejecta and interactions with melt pool formation in powder bed fusion additive manufacturing [J] . Abdalla R. Nassar, Molly A. Gundermann, Edward W. Reutzel, Scientific reports. . 2019,第1期

机译：粉床融合添加剂制造中大型喷射物和熔融池地层相互作用的形成过程
4. Hybrid Modeling Approach for Melt-Pool Prediction in Laser Powder Bed Fusion Additive Manufacturing [J] . Tesfaye Moges, Zhuo Yang, Kevontrez Jones, Journal of Computing and Information Science in Engineering . 2021,第5期

机译：激光粉末融合添加剂制造中熔融池预测的混合模拟方法
5. DIRECT MEASUREMENTS OF LASER ABSORPTIVITY DURING METAL MELT POOL FORMATION ASSOCIATED WITH POWDER BED FUSION ADDITIVE MANUFACTURING PROCESSES [C] . Manyalibo Matthews, Johannes Trapp, Gabe Guss, International Congress on Applications of Lasers Electro-Optics . 2017

机译：与粉床融合添加剂制造工艺相关的金属熔融池形成期间激光吸收率的直接测量
6. Quantifying and Reducing Uncertainty in Metal-Based Additive Manufacturing Laser Powder-Bed Fusion Processes [D] . Tapia Imbaquingo, Gustavo Andres. 2018

机译：量化和减少金属基添加剂制造激光粉床融合工艺的不确定性
7. Formation processes for large ejecta and interactions with melt pool formation in powder bed fusion additive manufacturing [O] . Abdalla R. Nassar, Molly A. Gundermann, Edward W. Reutzel, -1

机译：粉末床熔合增材制造中大型喷射的形成过程以及与熔池形成的相互作用
8. Laser powder-bed fusion additive manufacturing: physics of complex melt flow and formation mechanisms of pores, spatter and denudation zones [O] . Khairallah, Saad A., Anderson, Andrew T., Rubenchik, Alexander, 2016

机译：激光粉末床熔融添加剂制造：复杂熔体物理孔隙，飞溅和剥蚀区域的流动和形成机制

DIRECT MEASUREMENTS OF LASER ABSORPTIVITY DURING METAL MELT POOL FORMATION ASSOCIATED WITH POWDER BED FUSION ADDITIVE MANUFACTURING PROCESSES

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