Factors determining the flowability and spreading quality of gas-atomized Ti-48Al-2Cr-2Nb powders in powder bed fusion additive manufacturing

[1]  A. Chiba,et al.  Effect of mechanical ball milling on the electrical and powder bed properties of gas-atomized Ti–48Al–2Cr–2Nb and elucidation of the smoke mechanism in the powder bed fusion electron beam melting process , 2022, Journal of Materials Science & Technology.

[2]  A. Chiba,et al.  Non-equilibrium solidification behavior associated with powder characteristics during electron beam additive manufacturing , 2022, Materials & Design.

[3]  Zhongwei Li,et al.  Is high-speed powder spreading really unfavourable for the part quality of laser powder bed fusion additive manufacturing? , 2022, Acta Materialia.

[4]  Wenguang Nan,et al.  Experimental investigation on the spreadability of cohesive and frictional powder , 2022, Advanced Powder Technology.

[5]  D. Brackett,et al.  An integrated process and data framework for the purpose of knowledge management and closed-loop quality feedback in additive manufacturing , 2022, Progress in Additive Manufacturing.

[6]  A. Chiba,et al.  Ball-milling treatment of gas-atomized Ti 48Al 2Cr 2Nb powder and its effect on preventing smoking during electron beam powder bed fusion building process , 2022, Additive Manufacturing.

[7]  A. Spierings,et al.  Influence of the particle size distribution of monomodal 316L powder on its flowability and processability in powder bed fusion , 2021, Progress in Additive Manufacturing.

[8]  A. Zocca,et al.  Literature review: Methods for achieving high powder bed densities in ceramic powder bed based additive manufacturing , 2021, Open Ceramics.

[9]  A. Chiba,et al.  Controlling factors determining flowability of powders for additive manufacturing: A combined experimental and simulation study , 2021 .

[10]  M. Habibnejad-korayem,et al.  Effect of particle size distribution on the flowability of plasma atomized Ti-6Al-4V powders , 2021 .

[11]  A. Chiba,et al.  Spreading behavior of Ti 48Al 2Cr 2 Nb powders in powder bed fusion additive manufacturing process: experimental and discrete element method study , 2021, Additive Manufacturing.

[12]  Meng Li,et al.  Adaptability investigations on bottom modified blade in powder spreading process of additive manufacturing , 2021, Additive Manufacturing.

[13]  X. An,et al.  Numerical insights on the spreading of practical 316 L stainless steel powder in SLM additive manufacturing , 2021 .

[14]  A. Chiba,et al.  Smoke Suppression in Electron Beam Melting of Inconel 718 Alloy Powder Based on Insulator–Metal Transition of Surface Oxide Film by Mechanical Stimulation , 2021, Materials.

[15]  A. Chiba,et al.  Effect of multi-stage heat treatment on mechanical properties and microstructure transformation of Ti–48Al–2Cr–2Nb alloy , 2021 .

[16]  Taek-Soo Kim,et al.  Improving spreadability of hydrogenation–dehydrogenation Ti powder via surface treatment using silane-based compounds , 2021 .

[17]  Andre Mussatto,et al.  Influences of powder morphology and spreading parameters on the powder bed topography uniformity in powder bed fusion metal additive manufacturing , 2021 .

[18]  A. Chiba,et al.  Thermal properties of powder beds in energy absorption and heat transfer during additive manufacturing with electron beam , 2020 .

[19]  L. Mädler,et al.  Reducing cohesion of metal powders for additive manufacturing by nanoparticle dry-coating , 2020 .

[20]  A. Spierings,et al.  Effect of Particle size of monomodal 316L powder on powder layer density in powder bed fusion , 2020, Progress in Additive Manufacturing.

[21]  A. Chiba,et al.  Significance of powder feedstock characteristics in defect suppression of additively manufactured Inconel 718 , 2020 .

[22]  Yu-lei Du,et al.  Size-Dependent Structural Properties of a High-Nb TiAl Alloy Powder , 2020, Materials.

[23]  Liu Cao Study on the numerical simulation of laying powder for the selective laser melting process , 2019, The International Journal of Advanced Manufacturing Technology.

[24]  Wentao Yan,et al.  Powder-spreading mechanisms in powder-bed-based additive manufacturing: Experiments and computational modeling , 2019, Acta Materialia.

[25]  Annamaria Gisario,et al.  Metal additive manufacturing in the commercial aviation industry: A review , 2019, Journal of Manufacturing Systems.

[26]  C. Liew,et al.  Effects of Particle Surface Roughness on In-Die Flow and Tableting Behavior of Lactose. , 2019, Journal of pharmaceutical sciences.

[27]  Sanjay B. Joshi,et al.  On the development of powder spreadability metrics and feedstock requirements for powder bed fusion additive manufacturing , 2019, Additive Manufacturing.

[28]  E. von Hauff,et al.  Impedance Spectroscopy for Emerging Photovoltaics , 2019, The Journal of Physical Chemistry C.

[29]  Xi Zhang,et al.  Metal additive manufacturing in aircraft: current application, opportunities and challenges , 2019, IOP Conference Series: Materials Science and Engineering.

[30]  Christopher D. Pleass,et al.  Influence of powder characteristics and additive manufacturing process parameters on the microstructure and mechanical behaviour of Inconel 625 fabricated by Selective Laser Melting , 2018, Additive Manufacturing.

[31]  D. W. Wang,et al.  Layered surface structure of gas-atomized high Nb-containing TiAl powder and its impact on laser energy absorption for selective laser melting , 2018 .

[32]  Wolfgang A. Wall,et al.  Modeling and Characterization of Cohesion in Fine Metal Powders with a Focus on Additive Manufacturing Process Simulations , 2018, Powder Technology.

[33]  Zhongwei Li,et al.  Flow behavior of powder particles in layering process of selective laser melting: Numerical modeling and experimental verification based on discrete element method , 2017 .

[34]  Sina Haeri,et al.  Optimisation of blade type spreaders for powder bed preparation in Additive Manufacturing using DEM simulations , 2017 .

[35]  Matthias Markl,et al.  Predictive Simulation of Process Windows for Powder Bed Fusion Additive Manufacturing: Influence of the Powder Bulk Density , 2017, Materials.

[36]  R. Dehoff,et al.  Powder bed charging during electron-beam additive manufacturing , 2017 .

[37]  T. Bauer,et al.  Powder flowability characterisation methodology for powder-bed-based metal additive manufacturing , 2016 .

[38]  C. Körner,et al.  Additive manufacturing of metallic components by selective electron beam melting — a review , 2016 .

[39]  Sang-Wook Han,et al.  Anomalous structural disorder and distortion in metal-to-insulator-transition Ti2O3 , 2016 .

[40]  J. Kruth,et al.  Rheological behavior of β-Ti and NiTi powders produced by atomization for SLM production of open porous orthopedic implants , 2015 .

[41]  A. Rubenchik,et al.  Calculation of laser absorption by metal powders in additive manufacturing. , 2015, Applied optics.

[42]  Mohammed Benali,et al.  Characterization of flow properties of cohesive powders: A comparative study of traditional and new testing methods , 2014 .

[43]  R. Davé,et al.  Prediction of Inter-particle Adhesion Force from Surface Energy and Surface Roughness , 2011 .

[44]  Mojtaba Ghadiri,et al.  Triboelectric charging of powders: A review , 2010 .

[45]  Anton I. Gusev,et al.  Production of nanocrystalline powders by high-energy ball milling: model and experiment , 2008, Nanotechnology.

[46]  Jerry Y. H. Fuh,et al.  The influence of powder apparent density on the density in direct laser-sintered metallic parts , 2007 .

[47]  J. Visser,et al.  Van der Waals and other cohesive forces affecting powder fluidization , 1989 .

[48]  T. Pöschel,et al.  Influence of vibrating recoating mechanism for the deposition of powders in additive manufacturing: discrete element simulations of polyamide 12 , 2021 .

[49]  Y. S. Lee,et al.  Mesoscopic Simulation of Heat Transfer and Fluid Flow in Laser Powder Bed Additive Manufacturing , 2015 .