This study investigates the manufacturability of laser powder bed fusion (LPBF) for fabricating SS316L powder into components with rectangular micropillar arrays on their surface. The rectangular micropillars with different width sizes from 200 to 800 μm were fabricated with various LPBF volumetric laser energy densities and building directions. Scanning Electron Microscope, Optical Microscope, and Vickers hardness test were used to observe the effect of micropillar sizes, the volumetric laser energy densities, and build directions on the morphologies, structural densification, geometrical accuracies, and hardness properties of the fabricated micropillars. In this work, the experimental results present that the optimum volumetric laser energy density to fabricate rectangular micropillars with a minor defect was 105 J/mm3. The micropillars fabricated with built direction on 0° and 45° planes had stable morphologies and geometrical accuracies. The fabricated micropillar had larger width and pitch, but smaller gap sizes than their computer aided design designs. The hardness property of fabricated micropillars was affected by the size of micropillars, volumetric laser energy density, and build directions during the LPBF process. In conclusion, the rectangular micropillars with width sizes of 200–800 μm were successfully fabricated on the component's surface created at 0° and 45° planes by LPBF technique using 105 J/mm3 volumetric laser energy density.
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References
1.
ChangJ, HeX, YangZ, et al.Surface topography effects on the wettability and antifouling performance of nano-ZnO epoxy composite coatings. Surf Coatings Technol, 2022; 433:128145; doi: 10.1016/j.surfcoat.2022.128145
2.
CzerwiecT, TsarevaS, AndrieuxA, et al.Effects of surface topography at different scales on the dispersion of the wetting data for sessile water droplets on nitrided austenitic stainless steels. Surf Coatings Technol, 2022; 441:128510; doi: 10.1016/j.surfcoat.2022.128510
3.
MengY, DengJ, ZhangZ, et al.Enhanced wear resistance of AlTiN coatings by ultrasonic rolling substrate texturing. Surf Coatings Technol, 2022; 447:128841; doi: 10.1016/j.surfcoat.2022.128841
4.
DuM, DongW, LiX, et al.Effect of surface topography on injection joining Ti alloy for improved bonding strength of metal-polymer. Surf Coatings Technol, 2022; 433:128132; doi: 10.1016/j.surfcoat.2022.128132
5.
FadzilAFbA, PramanikA, BasakAK, et al.Role of surface quality on biocompatibility of implants—A review. Ann 3D Print Med, 2022; 8:100082; doi: 10.1016/j.stlm.2022.100082
6.
ZhangW-M, MengG, WeiX-Y, et al.Slip flow and heat transfer in microbearings with fractal surface topographies. Int J Heat Mass Transf, 2012; 55(23):7223–7233; doi: 10.1016/j.ijheatmasstransfer.2012.07.045
7.
SerdyukovV, StarinskiyS, MalakhovI, et al.Laser texturing of silicon surface to enhance nucleate pool boiling heat transfer. Appl Therm Eng, 2021; 194:117102; doi: 10.1016/j.applthermaleng.2021.117102
8.
GradlPR, CervoneA, GillE. Surface texture characterization for thin-wall NASA HR-1 Fe–Ni–Cr alloy using laser powder directed energy deposition (LP-DED). Adv Ind Manuf Eng, 2022; 4:100084; doi: 10.1016/j.aime.2022.100084
9.
ByunTS, GarrisonBE, McAlisterMR, et al.Mechanical behavior of additively manufactured and wrought 316L stainless steels before and after neutron irradiation. J Nucl Mater, 2021; 548:152849; doi: 10.1016/j.jnucmat.2021.152849
10.
SahinS, ÜbeyliM. A review on the potential use of austenitic stainless steels in nuclear fusion reactors. J Fusion Energy, 2008; 27:271–277; doi: 10.1007/s10894-008-9136-3
11.
PranotoI, RahmanMA, WaluyoJ. The role of pin fin array configurations and bubble characteristics on the pool boiling heat transfer enhancement. Fluids, 2022; 7(7):232; doi: 10.3390/fluids7070232
12.
ZhaoZ, XiaolongM, LiS, et al.Visualization-based nucleate pool boiling heat transfer enhancement on different sizes of square micropillar array surfaces. Exp Therm Fluid Sci, 2020; 119:110212; doi: 10.1016/j.expthermflusci.2020.110212
13.
ZhangX, DuA, LuoY, et al.Wetting behaviors and mechanism of micro droplets on hydrophilic micropillar-structured surfaces. Surf Interf, 2022; 33:102242; doi: 10.1016/j.surfin.2022.102242
14.
WangZ, SongY, YangJ, et al.The visualized investigation of a silicon based built-in heat pipe micropillar wick structure. Appl Therm Eng, 2018; 144:1117–1125; doi: 10.1016/j.applthermaleng.2018.08.060
15.
CalabreseL, AzzoliniM, BassiF, et al.Micro-milling process of metals: A comparison between femtosecond laser and EDM techniques. Manuf Mater Process, 2021; 5(4):125; doi: 10.3390/jmmp5040125
16.
WangX, ZhengB, YuK, et al.The role of cell boundary orientation on mechanical behavior: A site-specific micro-pillar characterization study. Addit Manuf, 2021; 46:102154; doi: 10.1016/j.addma.2021.102154
17.
BaytemirG, CiftpinarEH, TuranR. Enhanced metal assisted etching method for high aspect ratio microstructures: Applications in silicon micropillar array solar cells. Solar Energy, 2019; 194:148–155; doi: 10.1016/j.solener.2019.10.033
18.
ChenJ-K, ChenW-T, ChengC-C, et al.Metallic glass nanotube arrays: Preparation and surface characterizations. Mater Today, 2018; 21(2):178–185; doi: 10.1016/j.mattod.2017.10.007
19.
KaurG, MarmurA, MagdassiS. Fabrication of superhydrophobic 3D objects by digital light processing. Addit Manuf, 2020; 36:101669; doi: 10.1016/j.addma.2020.101669
20.
PengX, KongL, AnH, et al.A review of in situ defect detection and monitoring technologies in selective laser melting. 3D Print Addit Manuf, 2022; 10(3):438–466; doi: 10.1089/3dp.2021.0114
21.
JagadeeshB, DuraiselvamM, PrashanthKG. Deformation behavior of metallic lattice structures with symmetrical gradients of porosity manufactured by metal additive manufacturing. Vacuum, 2023; 211:111955; doi: 10.1016/j.vacuum.2023.111955
22.
JagadeeshB, DuraiselvamM. Investigations on the compressive behaviour of novel cell size graded primitive lattice structure produced by Metal Additive Manufacturing. Mater Lett, 2023; 333:133643; doi: 10.1016/j.matlet.2022.133643
23.
ChakkravarthyV, JeromeS. Printability of multiwalled SS 316L by wire arc additive manufacturing route with tunable texture. Mater Lett, 2020; 260:126981; doi: 10.1016/j.matlet.2019.126981
24.
BartolomeuF, BuciumeanuM, PintoE, et al.316L stainless steel mechanical and tribological behavior—A comparison between selective laser melting, hot pressing and conventional casting. Addit Manuf, 2017; 16:81–89; doi: 10.1016/j.addma.2017.05.007
25.
WangD, WangH, LiuZ, et al.Influence mechanism of laser delay on internal defect and surface quality in stitching region of 316L stainless steel fabricated by dual-laser selective laser melting. J Manuf Process, 2023; 94:35–48; doi: 10.1016/j.jmapro.2023.03.051
26.
ShanmuganathanPK, PurushothamanDB, PonnusamyM. Effect of high laser energy density on selective laser melted 316L Stainless Steel: Analysis on metallurgical and mechanical properties and comparison with wrought 316L Stainless Steel. 3D Print Addit Manuf, 2021; 10(3):9; doi: 10.1089/3dp.2021.0061
27.
MekhielS, KoshyP, ElbestawiMA. Additive texturing of metallic surfaces for wetting control. Addit Manuf, 2021; 37:101631; doi: 10.1016/j.addma.2020.101631
28.
KuoC, ChenY, NienY. Effects of energy parameters on dimensional accuracy when joining stainless-steel powders with heterogeneous metal substrates. Materials, 2021; 14(2):320; doi: 10.3390/ma14020320
29.
JiangC-P, WibisonoAT, PasangT. Selective laser melting of stainless steel 316L with face-centered-cubic-based lattice structures to produce rib implants. Materials, 2021; 14(20):5962; doi: 10.3390/ma14205962
30.
JiangC-P, WibisonoAT, WangS-H, et al.Selective laser melting of free-assembled stainless steel 316L hinges: Optimization of volumetric laser energy density and joint clearance. Metals, 2022; 12(7):1223; doi: 10.3390/met12071223
31.
KumarSP, ChakkravarthyV, MahalingamA, et al.Investigation of crystallographic orientation and mechanical behaviour in Laser-Welded Stainless Steel 316L Additive Components. Trans Indian Instit Metals, 2023; 76(2):527–535; doi: 10.1007/s12666-022-02756-6
32.
NongXD, ZhouXL. Effect of scanning strategy on the microstructure, texture, and mechanical properties of 15-5PH stainless steel processed by selective laser melting. Mater Charact, 2021; 174:111012; doi: 10.1016/j.matchar.2021.111012
33.
RallsAM, JohnM, NoudJ, et al.Tribological, corrosion, and mechanical properties of selective laser melted steel. Metals, 2022; 12(10):1732; doi: 10.3390/met12101732
34.
WüstP, EdelmannA, HellmannR. Areal surface roughness optimization of maraging steel parts produced by hybrid additive manufacturing. Materials, 2020; 13(2):418; doi: 10.3390/ma13020418
35.
XiaohuiJ, ChunboY, HonglanG, et al.Effect of supporting structure design on residual stresses in selective laser melting of AlSi10Mg. Int J Adv Manuf Technol, 2022; 118(5):1597–1608; doi: 10.1007/s00170-021-08010-5
36.
YakoutM, ElbestawiMA, VeldhuisSC. A study of thermal expansion coefficients and microstructure during selective laser melting of Invar 36 and stainless steel 316L. Addit Manuf, 2018; 24:405–418; doi: 10.1016/j.addma.2018.09.035
37.
KrólikowskiM, FilipowiczK. Verification of geometrical accuracy of selective laser melting (SLM) built model. Adv Manuf Sci Technol, 2013; 37:85–91; doi: 10.2478/amst-2013-0026
38.
CuestaE, ÁlvarezB, ZapicoP, et al.Analysis of post-processing influence on the geometrical and dimensional accuracy of selective laser melting parts. Rapid Prototyp J, 2020; 26:1713–1722; doi: 10.1108/RPJ-02-2020-0042
39.
SoylemezE. Modelling the Melt Pool of the Laser Sintered Ti6Al4V Layers with Goldak's Double-Ellipsoidal Heat Source. International Solid Freeform Fabrication Symposium: University of Texas at Austin;, 2018; pp. 1721–1736, doi: 10.26153/tsw/17163
40.
BalbaaM, MekhielS, ElbestawiM, et al.On selective laser melting of Inconel 718: Densification, surface roughness, and residual stresses. Mater Des, 2020; 193:108818; doi: 10.1016/j.matdes.2020.108818
41.
TanprayoonD, SrisawadiS, SatoY, et al.Microstructure and hardness response of novel 316L stainless steel composite with TiN addition fabricated by SLM. Opt Laser Technol, 2020; 129:106238; doi: 10.1016/j.optlastec.2020.106238
42.
MorozovaI, KehmC, ObrosovA, et al.On the heat treatment of selective-laser-melted 316L. J Mater Eng Perform, 2023; 32(10):4295–4305; doi: 10.1007/s11665-022-07404-0
43.
GuoF, GuoY, KongX, et al.The effect of wall thickness and scanning speed on the martensitic transformation and tensile properties of selective laser melted NiTi Thin-wall structures. Metals, 2022; 12(3):519; doi: 10.3390/met12030519
44.
TakataN, KodairaH, SuzukiA, et al.Size dependence of microstructure of AlSi10Mg alloy fabricated by selective laser melting. Mater Charact, 2018; 143:18–26; doi: 10.1016/j.matchar.2017.11.052
45.
CarassusH, GuérinJD, MorvanH, et al.An experimental investigation into influences of build orientation and specimen thickness on quasi-static and dynamic mechanical responses of Selective Laser Melting 316L Stainless Steel. Mater Sci Eng A, 2022; 835:142683; doi: 10.1016/j.msea.2022.142683
46.
MeliaMA, DuranJG, KoepkeJR, et al.How build angle and post-processing impact roughness and corrosion of additively manufactured 316L stainless steel. NPJ Mater Degrad, 2020; 4(1):21; doi: 10.1038/s41529-020-00126-5
47.
JiangJ, ChenJ, RenZ, et al.The influence of process parameters and scanning strategy on lower surface quality of TA15 parts fabricated by selective laser melting. Metals, 2020; 10(9):1228; doi: 10.3390/met10091228
48.
WuZ, NarraS, RollettA. Exploring the fabrication limits of thin-wall structures in a laser powder bed fusion process. Int J Adv Manuf Technol, 2020; 110:191–207; doi: 10.1007/s00170-020-05827-4
49.
YangY, ZhuY, KhonsariMM, et al.Wear anisotropy of selective laser melted 316L stainless steel. Wear, 2019; 428–429:376–386; doi: 10.1016/j.wear.2019.04.001
50.
ZhouB, XuP, LiW, et al.Microstructure and anisotropy of the mechanical properties of 316L stainless steel fabricated by selective laser melting. Metals, 2021; 11(5):775; doi: 10.3390/met11050775
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