Additive manufacturing processes have been developed to a stage where they can now be routinely used to manufacture net-shape high-value components. Selective Laser Melting (SLM) comprises of either a single or multiple deflected high energy fibre laser source(s) to raster scan, melt and fuse layers of metallic powdered feedstock. However this deflected laser raster scanning methodology is high cost, energy inefficient and encounters significant limitations on output productivity due to the rate of feedstock melting.ududThis work details the development of a new additive manufacturing process known as Diode Area Melting (DAM). This process utilises customised architectural arrays of low power laser diode emitters for high speed parallel processing of metallic feedstock. Individually addressable diode emitters are used to selectively melt feedstock from a pre-laid powder bed. The laser diodes operate at shorter laser wavelengths (808 nm) than conventional SLM fibre lasers (1064 nm) theoretically enabling more efficient energy absorption for specific materials. The melting capabilities of the DAM process were tested for low melting point eutectic BiZn2.7 elemental powders and higher temperature pre-alloyed 17-4 stainless steel powder. The process was shown to be capable of fabricating controllable geometric features with evidence of complete melting and fusion between multiple powder layers.
展开▼
机译:增材制造工艺已经发展到一个阶段,现在可以将其常规用于制造网状高价值组件。选择性激光熔化(SLM)由单个或多个偏转的高能光纤激光源组成,以光栅扫描,熔化和融合金属粉末原料层。但是,这种偏转的激光光栅扫描方法成本高,能源效率低,并且由于原料熔化的速率而在输出生产率上受到严重限制。 ud ud这项工作详细介绍了一种新的增材制造工艺的开发,该工艺称为二极管面积熔化(DAM) 。该工艺利用低功率激光二极管发射器的定制建筑阵列来对金属原料进行高速并行处理。可单独寻址的二极管发射器用于选择性地熔化预铺粉末床中的原料。与传统的SLM光纤激光器(1064 nm)相比,激光二极管在更短的激光波长(808 nm)下工作,理论上可以对特定材料进行更有效的能量吸收。针对低熔点共晶BiZn2.7元素粉末和高温预合金17-4不锈钢粉末,测试了DAM工艺的熔化能力。事实证明,该工艺能够制造出可控的几何特征,并具有多个粉末层之间完全熔化和融合的证据。
展开▼
