From the development of low-cost filament to 3D printing ceramic parts obtained by fused filament fabrication
暂无分享,去创建一个
[1] J. Chevalier,et al. Optimization of mechanical properties of robocast alumina parts through control of the paste rheology , 2022, Journal of the European Ceramic Society.
[2] G. Cicala,et al. Fused Filament Fabrication of Alumina/Polymer Filaments for Obtaining Ceramic Parts after Debinding and Sintering Processes , 2022, Materials.
[3] Bhargav Prajwal Pathri,et al. Machining of ceramic materials: a state-of-the-art review , 2022, International Journal on Interactive Design and Manufacturing (IJIDeM).
[4] S. Olhero,et al. Conventional versus additive manufacturing in the structural performance of dense alumina-zirconia ceramics: 20 years of research, challenges and future perspectives , 2022, Journal of Manufacturing Processes.
[5] M. Ackermann,et al. Alumina Manufactured by Fused Filament Fabrication: A Comprehensive Study of Mechanical Properties and Porosity , 2022, Polymers.
[6] L. Guillaumat,et al. In-nozzle impregnation of continuous textile flax fiber/polyamide 6 composite during FFF process , 2021, Composites Part A: Applied Science and Manufacturing.
[7] L. Hattali,et al. Design of experiment analysis on tensile properties of PLA samples produced by fused filament fabrication , 2021, The International Journal of Advanced Manufacturing Technology.
[8] V. Dhawan,et al. Machining of hard and brittle materials: A comprehensive review , 2021, Materials Today: Proceedings.
[9] F. Nanni,et al. A simple route for additive manufacturing of 316L stainless steel via Fused Filament Fabrication , 2021, Journal of Manufacturing Processes.
[10] G. Bertrand,et al. A review of additive manufacturing of ceramics by powder bed selective laser processing (sintering / melting): Calcium phosphate, silicon carbide, zirconia, alumina, and their composites , 2021, Open Ceramics.
[11] P. Cheng,et al. Material extrusion additively manufactured alumina monolithic structures to improve the efficiency of plasma-catalytic oxidation of toluene , 2020 .
[12] T. Hanemann,et al. New Feedstock System for Fused Filament Fabrication of Sintered Alumina Parts , 2020, Materials.
[13] T. Tarasova,et al. On the difference in material structure and fatigue properties of polyamide specimens produced by fused filament fabrication and selective laser sintering , 2020, The International Journal of Advanced Manufacturing Technology.
[14] L. Guillaumat,et al. The effect of build orientation on both flexural quasi-static and fatigue behaviours of filament deposited PA6 polymer , 2020, International Journal of Fatigue.
[15] F. Clemens,et al. Effect of stearic acid on rheological properties and printability of ethylene vinyl acetate based feedstocks for fused filament fabrication of alumina , 2020, Additive Manufacturing.
[16] S. Malakooti,et al. Nanoindentation measurement of core–skin interphase viscoelastic properties in a sandwich glass composite , 2020, Mechanics of Time-Dependent Materials.
[17] A. Kwade,et al. Influence of formulation parameters on the freeform extrusion process of ceramic pastes and resulting product properties , 2020 .
[18] Ľ. Bača,et al. Fracture and mechanical properties of lightweight alumina ceramics prepared by fused filament fabrication , 2020 .
[19] A. Smirnov,et al. The Influence of Wire Electrical Discharge Machining Cutting Parameters on the Surface Roughness and Flexural Strength of ZrO2/TiN Ceramic Nanocomposites Obtained by Spark Plasma Sintering , 2019, Nanomaterials.
[20] A. Smirnov,et al. Processing and mechanical properties of new hierarchical metal-graphene flakes reinforced ceramic matrix composites , 2019, Journal of the European Ceramic Society.
[21] V. Schulze,et al. Process porosity and mechanical performance of fused filament fabricated 316L stainless steel , 2019, Rapid Prototyping Journal.
[22] Gerwin Smit,et al. A review of the fatigue behavior of 3D printed polymers , 2019, Additive Manufacturing.
[23] J. Gonzalez-Gutierrez,et al. Debinding behaviour of feedstock for material extrusion additive manufacturing of zirconia , 2019, Powder Metallurgy.
[24] J. Gonzalez-Gutierrez,et al. Additive manufacturing of zirconia parts by fused filament fabrication and solvent debinding: Selection of binder formulation , 2019, Additive Manufacturing.
[25] T. Moritz,et al. Fused Filament Fabrication (FFF) of Metal-Ceramic Components. , 2019, Journal of visualized experiments : JoVE.
[26] A. Laskin,et al. On productivity of laser additive manufacturing , 2018, Journal of Materials Processing Technology.
[27] W. R. W.R. Matizamhuka,et al. Advanced ceramics - the new frontier in modern-day technology: Part I , 2018 .
[28] M. K. Kuzman,et al. Effect of wood content in FDM filament on properties of 3D printed parts , 2018 .
[29] B. Khatri,et al. A 3D-Printable Polymer-Metal Soft-Magnetic Functional Composite—Development and Characterization , 2018, Materials.
[30] Clemens Holzer,et al. Effect of the printing bed temperature on the adhesion of parts produced by fused filament fabrication , 2018 .
[31] Wai Yee Yeong,et al. Direct selective laser sintering and melting of ceramics: a review , 2017 .
[32] A. Sova,et al. Velocity of the Particles Accelerated by a Cold Spray Micronozzle: Experimental Measurements and Numerical Simulation , 2013, Journal of Thermal Spray Technology.
[33] D. Tréheux,et al. Interfacial behavior on Al2O3/HAYNES® 214™ joints fabricated by solid state bonding technique with Ni or Cu–Ni–Cu interlayers , 2012 .
[34] Sergey N. Grigoriev,et al. Optical Monitoring in Laser Cladding of Ti6Al4V , 2012, Journal of Thermal Spray Technology.
[35] G. Rizvi,et al. Effect of processing conditions on the bonding quality of FDM polymer filaments , 2008 .
[36] Noshir A. Langrana,et al. Microstructural Characterization and Mechanical Properties of Si3N4 Formed by Fused Deposition of Ceramics , 2008 .
[37] L. Shor,et al. New developments in fused deposition modeling of ceramics , 2005 .
[38] J. Käs,et al. Excitation beyond the monochromatic laser limit: simultaneous 3-D confocal and multiphoton microscopy with a tapered fiber as white-light laser source. , 2005, Journal of biomedical optics.
[39] Stephen C. Danforth,et al. Powder Processing, Rheology, and Mechanical Properties of Feedstock for Fused Deposition of Si3N4 Ceramics , 2004 .
[40] Noshir A. Langrana,et al. Structural quality of parts processed by fused deposition , 1996 .
[41] P. Podrabinnik,et al. Development of Al2O3 and PLA ceramic-polymer filament for 3D printing by fused deposition modelling method , 2022, PROCEEDINGS OF THE II INTERNATIONAL CONFERENCE ON ADVANCES IN MATERIALS, SYSTEMS AND TECHNOLOGIES: (CAMSTech-II 2021).
[42] Andreas Öchsner,et al. 3D-Printing Technologies for Dental Material Processing , 2020 .
[43] Claire Lartigue,et al. Multi-scale surface characterization in additive manufacturing using CT , 2017 .
[44] A. Boccaccini,et al. Stereolithographic Ceramic Manufacturing of High Strength Bioactive Glass , 2015 .
[45] Andrey V. Gusarov,et al. On the Possibility of Selective Laser Melting of Quartz Glass , 2014 .
[46] R. Danzer,et al. The ball on three balls test—Strength and failure analysis of different materials , 2007 .
[47] Qian Sun,et al. Modeling of Bond Formation Between Polymer Filaments in the Fused Deposition Modeling Process , 2004 .
[48] Amit Bandyopadhyay,et al. Fused Deposition of Ceramics (FDC) and Composites , 2001 .
[49] S. Pekin,et al. A Study on Weight Loss Rate Controlled Binder Removal From Parts Produced by FDC , 1998 .
[50] F. Klocke,et al. Modern approaches for the production of ceramic components , 1997 .
[51] S. Danforth,et al. Filament Feed Materials for Fused Deposition Processing of Ceramics and Metals , 1996 .
[52] S. Sōmiya. A review of: “ADVANCED TECHNICAL CERAMICS” , 1991 .
[53] C. Handwerker,et al. Sintering of Ceramics , 1989 .
[54] John Evans,et al. Ceramic Injection Moulding , 1987 .
[55] R. M. Woolley,et al. Symmetrical bending of thin circular elastic plates on equally spaced point supports , 1967 .