pp. 2213-2225 | Article Number: iejme.2016.195
Published Online: September 01, 2016
Article Views: 204 | Article Download: 250
The article focuses on a novel solution to one of the key problems of modern mechanical engineering – the development of digital manufacturing in the field of engineering. This paper presents a project aimed at the development of technical support centers in the field of modern digital manufacturing. The article thoroughly analyses prerequisites for the establishment of such centers, the problems associated with the functioning of such centers, technology that can be used in the design and infrastructure development of the centers, as well as key characteristics of the courseware and equipment process. These solutions can be used in such fields of science and technology as virtual engineering, learning systems, e-manufacturing, education and engineering, digital products, digital manufacturing, rapid manufacturing, rapid product development, rapid prototyping and fully meet the objectives and goals of procedia engineering. The project of technical support centers development in the field of modern digital manufacturing, offered by the authors of the article, is aimed at the organization of functional bonds between educational, engineering and manufacturing innovative enterprises and at the development of laboratories in the field of innovative technologies training based on those enterprises.
Keywords: Engineering education; Technical designs; Smart manufacturing process; Information and computer technologies; E-learning method
Basmer, S., Buxbaum-Conradi, S., Krenz, P., Redlich, T., Wulfsberg, J. P., Bruhns, F. L. (2015) Open Production: Chances for Social Sustainability in Manufacturing. Procedia CIRP, 12th Global Conference on Sustainable Manufacturing – Emerging Potentials, 26, 46–51.
Botti, A. (2014) Next generation Manufacturing: the Mediterranean Fab Lab case study. Proceedings of the 13th International Conference of the Society for Global Business and Economic Development. Managing the “Intangibles”: Business and Entrepreneurship Perspectives in a Global Context, 1, 601-611.
Brinkmann, V. (2011) The "persian rider" from the Athenian acropolis; or, a reconstruction of the "third generation". Notes in the history of art, 30(3), 12-17.
Degrigny, C. (2004). Altération et conservation des objets métalliques issus de fouilles sous marines. Roma: Livorno. 243p.
Degrigny, C., Le Gall, R. (1999) Conservation of ancient lead artefacts corroded in organic acid environments: electrolytic stabilisation/consolidation. Studies in Conservation, 44, 157-169.
Degrigny, C., Wery, M., Vescoli, V., Blengino, M. (1996) Altération et nettoyage de pièces en argent doré. Studies in Conservation, 41, 170-178.
Degrigny, V., Witschard, D. (2006) La Châsse des Enfants de Saint Sigismond de l’Abbaye de SaintMaurice: traitements électrochimiques des reliefs en argent en cours de restauration. Anheuser, K. et Werner, C. (eds), Châssesreliquaires et orfèvrerie médiévales. Actes du colloque au Musée d’art et d’histoire, Genève (9-16), Londres: Archétype.
Egorov, S. (2014a) Educational and methodical complex-center of high-technology equipment with CNC and technological production preparation. Modern problems of science and education, 3, 22-28.
Egorov, S. (2014b) Innovative educational-industrial complex based on modern technological equipment with CNC and integrated system of production preparation in the field of machining. Vestnik «MSTU «STANKIN», 3, 31-34.
Egorov, S. (2014d) Technical youth education – technological support centers of additional education of children. Fundamental research, 6(5), 920-927.
Egorov, S. (2014с) Integrated educational and methodical complex for programming technology, CNC systems and development of control programs studies. Fundamental research, 8(1), 26-31.
Fantini, M., Crescienzo, F., Persiani, F., Benazzi, S. (2008) 3D restitution, restoration, and prototyping of a medieval damaged skull. Rapid Prototyping Journal, 14(5), 318-324.
Fastermann, P. (2014) FabLabs – wie sich in offenen Werkstaetten weitere Moeglichkeiten erschliessen. Berlin: Springer Verlag. 163p.
Gershenfeld, N. (1999) When Things Start to Think. New York: Henry Holt. 225p.
Gershenfeld, N. (2011) The Nature of Mathematical Modeling. England: Cambridge University Press. 344 p.
Gershenfeld, N. & Fab, A. (2005) The coming revolution on your desktop—from personal computers to personal fabrication. New York: Basic Books. 278 p.
Greenberg, A. (2008) The Fab Life. Forbes. Direct access: http://www.forbes.com/2008/08/13/diy-innovation-gershenfeld-tech-egang08-cx_ag_0813gershenfeld.html
Mitrofanov, V. G., Drachyov, O. I. & Kapitanov, A. V. (2011) Modeling and control of production systems. Irbit: Tolyatti, 243 p.
Mitrofanov, V. G., Kapitanov, A. V., Popov, A. P. (2013) Design of automated engineering industries. Tolyatti: Irbit, 282 p.
Schweizer, F. & Witschard, D. (2007) La châsse des enfants de saint Sigismond. Paris: Somogy. 231p.
Wachowiak, M. J. & Basiliki, V. K. (2009) 3D scanning and replication for museum and cultural heritage applications. Journal of the American Institute for Conservation, 41, 141-158.
Wolfe, J., Bouchard, M. & Degrigny, C. (2010) Testing for localized electrochemical cleaning of two 17th century gilt silver decorative objects. Direct access: http://www.tandfonline.com/doi-/pdf/10.1179/2047058415Y.0000000015.