Abstract
Although the concept of additive manufacturing has been proposed for several decades, momentum in the area of selective laser melting (SLM) is finally starting to build. In SLM, density and surface roughness, as the important quality indexes of SLMed parts, are dependent on the processing parameters. However, there are few studies on their collaborative optimization during SLM to obtain high relative density and low surface roughness simultaneously in the literature. In this work, the response surface method was adopted to study the influences of different processing parameters (laser power, scanning speed and hatch space) on density and surface roughness of 316L stainless steel parts fabricated by SLM. A statistical relationship model between processing parameters and manufacturing quality is established. A multi-objective collaborative optimization strategy considering both density and surface roughness is proposed. The experimental results show that the main effects of processing parameters on the density and surface roughness are similar. We observed that the laser power and scanning speed significantly affected the above objective quality, but the influence of the hatch spacing was comparatively low. Based on the above optimization, 316L stainless steel parts with excellent surface roughness and relative density can be obtained by SLM with optimized processing parameters.
Highlights
Selective Laser Melting (SLM) is an additive manufacturing (AM) technology based on use of a high-power laser beam, and is the most widely used metal 3D printing technology [1]
It can be seen that the optimal values of the density and the surface roughness in these samples can be obtained respectively when using the processing parameter sets (P, V, S) of NO.11 (225 W, 700 mm/s, 90 μm) and NO.19 (225 W, 1000 mm/s, 90 μm)
As for two-factor interaction effects, there are some differences between the relative density density (RD) and the surface roughness roughness (SR)
Summary
Selective Laser Melting (SLM) is an additive manufacturing (AM) technology based on use of a high-power laser beam, and is the most widely used metal 3D printing technology [1]. SLM manufacturing is a rapid prototyping process, in which metal powder is melted layer by layer and solidified to form parts. There are more than 130 parameters [3] of SLM which may have impacts on the forming properties (such as density, surface roughness (defined as SR) and thermal properties [4]) of the parts, including the diameter of the laser beam, laser power (defined as P), scanning speed (defined as V), hatch spacing (defined as S), scanning strategy, layer thickness and so on [5,6,7,8]. Han et al [12] studied the factors influencing the surface roughness in SLMed
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
