COMPUTER HYBRID DESIGN USING PYTHON SCRIPTING AND CONVENTIONAL 3D MODELING TO BUILD (FCC) CRYSTAL STRUCTURES OF PRECIOUS METALS AND THEIR PREPARING FOR 3D PRINTING

Tihomir DOVRAMADJIEV, Mariana STOEVA, Violeta BOZHIKOVA, Rozalina DIMOVA, Rusko FILCHEV

Abstract


Developing a properly constructed 3D geometry is essential for obtaining high quality digital and real 3D models. Gold (Au 79) and Platinum Crystal (Pt 78) Face Centered Cubic (FCC) Crystal Structures are designed to illustrate the training content of models invisible to the human eye. The present study optimizes the design approach by applying Python programming language directly in Blender 3D environments, and further developing it into software compatible with 3D printers to produce the final model.


Full Text:

PDF

References


Eiben A. & Smith J., Introduction to Evolutionary Computing, Second Edition, ISSN 1619-7127, Natural Computing Series, ISBN 978-3-662-44873-1 ISBN 978-3-662-44874-8 (eBook), DOI 10.1007/978-3-662-44874-8, Library of Congress Control Number: 2015944812, Springer Heidelberg New York Dordrecht London, © Springer-Verlag Berlin Heidelberg 2003, 2015

Dovramadjiev T., Advanced Technologies in Design, publisher: Technical University of Varna, 228, Bulgaria, 2017.

Gibson I., Rosen D. & Stucker B., Additive Manufacturing Technologies Rapid Prototyping to Direct Digital Manufacturing, Springer New York Heidelberg Dordrecht London, Library of Congress Control Number: 2009934499 # Springer ScienceþBusiness Media, LLC 2010.

Riel, A., Draghici, A., Draghici, G., Grajewski, D., & Messnarz, R., Process and product innovation needs integrated engineering collaboration skills. Journal of Software: Evolution and Process, 24(5), 551-560, 2012.

Scherer P., Computational Physics, Simulation of Classical and Quantum Systems, Third Edition, Library of Congress Control Number: 2017944306, © Springer International Publishing AG 2010, 2013, 2017.

Witelski T. & M. Bowen, Methods of Mathematical Modelling. Continuous Systems and Differential Equations, Library of Congress Control Number: 2015948859, Mathematics Subject Classification: 34-01, 35-01, 34Exx, 34B40, 35Qxx, 49-01, 92-XX, Springer Cham Heidelberg New York Dordrecht London, © Springer International Publishing Switzerland, 2015.

Dean A., Voss Daniel & Draguljić D., Design and Analysis of Experiments, Second Edition, Library of Congress Control Number: 2016963195, 1st edition: © Springer-Verlag New York, Inc. 1999, 2nd edition: © Springer International Publishing AG 2017.

Soroka O. & Vasilyeva I., Visualization of educational information, University of Pedagogical Self-Education №12 / 2015.

Ivanov I. & Ivanova M., Computer models as an effective means of implementing the principle of visualization in teaching, Bulletin SGUTiKD, No 1 (19), 2012.

Zadpoor A. A. Additively manufactured porous metallic biomaterials, Journal of Materials Chemistry B. Materials for biology and medicine, Delft University of Technology, 2019.

Weißmann V., Boss C., Schulze C., Hansmann H. & Bader R., Experimental Characterization of the Primary Stability of Acetabular Press-Fit Cups with Open-Porous Load-Bearing Structures on the Surface Layer, Metals, 8, 839, 2018.

Maconachie T., Leary M., Lozanovski B., Zhang X., Qian M., Faruque O. & Brandt M., SLM lattice structures: Properties, performance, applications and challenges, Elsevier, 2019.

Bai L., Gong C., Chen X., Sun Y., Zhang J., Cai L., Zhu S. & Sheng X., Additive Manufacturing of Customized Metallic Orthopedic Implants: Materials, Structures, and Surface Modifications, Metals 2019, 9, 1004.

Baltzer, N. & Copponnex, T., Properties, and processing of precious metal alloys for biomedical applications. In Precious Metals for Biomedical Applications; Elsevier: Amsterdam, The Netherlands, 3–36, 2014.

ARKEMA, Expansion of additive manufacturing: 5 cases of industrial application, 2019. Retrieved from:

https://www.arkema.com.cn/en/webzine/story/Expansion-of-additive-manufacturing-5-cases-of-industrial-application/ (Access 15 March 2020).

Lundberg D., The Periodic Table of Elements, Swedish University of Agricultural Sciences, p/ 2, 2015.

Blain J. M., An introduction to Blender 3D, Blender Foundation, p. 305, 2011.

Chronister J., Blender Basics: A Classroom Tutorial Book, 5th Edtion, cdschools.org, p. 266, 2017.

Blender Foundation, Quickstart Introduction — Blender Python API, Running Scripts & Key Concepts. Retrieved from: https://docs.blender.org/api/current/info_quickstart.html. (Access 15 March 2020).

Filipov S. V., Blender software platform as an environment for modeling objects and processes of science disciplines, № 230. p. 42, Moscow, 2018.

Jaworski W., Programming Add-Ons for Blender 2.5 - version 1.01, Writing Python Scripts, with Eclipse IDE, p. 135, 2011.

Jaworski W., Programming Add-Ons for Blender 2.8 - version 2.0, Writing Python Scripts, with Eclipse IDE, p. 168, 2019.

Lee K. & Hubbard S., Data Structures and Algorithms with Python, Library of Congress Control Number: 2014953918, Springer Cham Heidelberg New York Dordrecht London, © Springer International Publishing Switzerland, 2015.

NDT – Resource Center, Primary Metallic Crystalline Structures (BCC, FCC, HCP). Retrieved from: https://www.nde-ed.org/EducationResources/CommunityCollege/Materials/Structure/metallic_structures.htm (Access 15 March 2020).

Magyari-Kope B., Ozolins V., K. & Persson A., Lattice instabilities in metallic elements, Modern Physics, 2012.

Shaobo H., Guang-Jie X., Chao C., Wang Qi, Yang-Gang W., Meng G. & Li Jun, Gas-assisted transformation of gold from fcc to the metastable 4H phase. Nature Communications|, 2020. Retrieved from: www.nature.com/naturecommunications. (Access 15 March 2020).

Carter C. & Norton M., Ceramic Materials - Science and Engineering, Library of Congress Control Number: 2006938045, Springer Science+Business Media, LLC, 2007.

Chawla K. K., Composite Materials, Science and Engineering, Third Edition, Springer New York Heidelberg Dordrecht London, Library of Congress Control Number: 2012940847# Springer Science+Business Media New York, USA, 2012.

Blender Foundation, Blender 2.79 - Light Attenuation / Falloff Types, Lin/Quad Weighted. Retrieved from: https://docs.blender.org/manual/en/2.79/render/blender_render/lighting/lights/attenuation.html (Access 15 March 2020).

Williams T., Basic Model Preparation with Meshmixer, Digital Media Tutorial. https://digitalmedia.architecture.yale.edu/sites/default/files/files/Meshmixer.pdf (Access 15 March 2020).

Zontek T. L., Ogle B. R., Jankovic J. T. & Hollenbeck S. M., An exposure assessment of desktop 3D printing, Division of Chemical Health and Safety of the American Chemical Society. Published by Elsevier Inc, 15-25, 2016.

Adamczak S. & Graba M., The 3D printing in industrial design, Mechanik, 1/2020, 21-26.

Arvanitidi E., Drosos C., Theocharis E. & Papoutsidakis M., 3D Printing and Education, International Journal of Computer Applications (0975 – 8887), 177(24), 55-59, 2019.

AMRG, About Additive Manufacturing. The 7 Categories of Additive Manufacturing. Retrieved from: https://www.lboro.ac.uk/research/amrg/about/the7categoriesofadditivemanufacturing/ (Access 15 March 2020).

Mrugalska, B., & Stetter, R., Health-aware model-predictive control of a cooperative AGV-based production system. Sensors, 19(3), 532, 2019.

DMG MORI, Additive manufacturing. Retrieved from: https://en.dmgmori.com/products/machines/additive-manufacturing. (Access 15 March 2020).

AMT, End-to-End Automated Post Processing Technology Solutions for Additive Manufacturing. Retrieved from: https://amtechnologies.com/. (Access 15 March 2020).


Refbacks

  • There are currently no refbacks.


JOURNAL INDEXED IN :