An integrated approach to development and simulation manufacturing processes of optical products

• Autorzy: Yablochnikov E. I. , Vasilkov S. D. , Andreev Y. S. , Pirogov A. V. , Tretyakov S. D.

Identyfikatory

DOI

10.1515/mper-2015-0040

• Języki publikacji: EN

Abstrakty

EN

The engineering management process and automation method for making pilot set of optical polymer parts used in LED systems are considered. Optical system and lens geometry development are realized in Zemax. 3D model and molding tools with further generating of NC coded data are developed in Cimatron E. Pre simulation of injection molding process is realized in Moldex3D and thermo-mechanical analysis is provided by OOFELIE. 3D printer Objet is used for parts prototyping on different stages of the process. Data and process management are realized with a help of PDM system SmarTeam.

Słowa kluczowe

EN

optical products; polymer lens; simulation; CAD/CAM/CAE; technological process; injection molding; additive technologies; cyber-physical systems

• Wydawca: Production Engineering Committee of the Polish Academy of Sciences ; Polish Association for Production Management
• Czasopismo: Management and Production Engineering Review
• Rocznik: 2015
• Tom: Vol. 6, No. 4
• Strony: 94--103
• Opis fizyczny: Bibliogr. 25 poz., rys., tab., wykr.

Twórcy

autor

Yablochnikov E. I.

• ITMO University, Technologies and Industrial Engineering Department, Russia

autor

Vasilkov S. D.

• ITMO University, Technologies and Industrial Engineering Department, Russia

autor

Andreev Y. S.

• ITMO University, Technologies and Industrial Engineering Department, Russia

autor

Pirogov A. V.

• ITMO University, Technologies and Industrial Engineering Department, Russia

autor

Tretyakov S. D.

• ITMO University, Technologies and Industrial Engineering Department, Russia

Bibliografia

• [1] Bäumer S., Handbook of Plastic Optics, John Wiley & Sons, p. 196, 2005.
• [2] Osvald T., Tung L.-S., Gremman P.J., Injection molding, SPb, p. 712, 2006.
• [3] Schaub M.P., The design of plastic optical systems, Bellingham: SPIE Press, p. 215, 2009.
• [4] Lee K., Lin J.-C., Optimization of injection molding parameters for led lampshade, Transactions of the Canadian Society for Mechanical Engineering, 37, 3, 2013.
• [5] Mayer R., Precision injection molding, Optik&Photonik, 4, 46-51, 2007.
• [6] Moldex3D, URL: http://www.moldex3d.com/.
• [7] Powell S., Fisher D., Polymer optics gain increased precision, Laser Focus World, pp. 111-117, June 2007.
• [8] Berman B., de Mare J., Loren S., Svenson T. [Ed.], Robust design methodology for reliability: Exploring the effects of variation and uncertainty, John Wiley & Sons, p. 191, 2009.
• [9] Montgomery D.C., Design and analysis of experiments, 5 th edition, John Wiley & Sons, p. 684, 2001.
• [10] Malkin A.Y., Isaev A.I., Rheology: concepts, methods and applications, SPb, p. 506, 2007.
• [11] Oktem H., Erzurumlu T., Uzman I., Application of Taguchi optimization technique in determining plastic injection molding process parameters for a thinshell part, Mater. Des., 28, 1271-1278, 2007.
• [12] Gordon M.J., Quality control management of injection molding, SPb, p. 824, 2012.
• [13] Yablochnikov E.I., Pirogov A.V., Vasilkov S.D., Andreev Y.S., Barvinsky I.A., Studies of design and technology influence on optical properties of injection molding parts by simulation, Proceedings of the 58th Ilmenau Scientific Colloquium, Technische Universit¨at Ilmenau, 08 - 12 September 2014, URN (Paper): http://nbn-resolving.de/urn/resolver.pl?urn= urn: nbn:de:gbv:ilm1-2014iwk-106:2.
• [14] Optima research - Zemax features, http://www.optima-research.com/index.php?page =zemax-features.
• [15] Mazzoli A., Saint-Georges P., Orban A., Ruess J.- S., Loicq J, Barbier C., Stockman Y., Georges M., Nachtergaele P., Paquay S., Vincenzo P., Experimental validation of opto-thermo-elastic modeling in OOFELIE: Multiphysics, Optical Design and Engineering IV, Proceedings of SPIE, vol. 8167, 2011.
• [16] Kamal M.R., Isayev A., Liu S.-J. [Eds.], Injection molding: Technology and fundamentals, Munich, Cincinnati: Hanser, p. 926, 2009.
• [17] Pirogov A.V., Development and simulation of technological manufacturing preparation polymer optical materials products, PhD-thesis, SPb, p. 175, 2014.
• [18] Boyarintsev A.V., Duvidzon V.G., Podsoblyaev D.S., Rapid manufacturing of pilot series of details from thermoplastic polymer materials, Polymer materials. Products, equipment, technology, 6, 4-9, 2013.
• [19] Cimatron E., http://www.cimatron.com/.
• [20] Accura Bluestone plastic for use with solid-state stereolithography (SLA) systems, 2006, http://3dsystems.co.jp/documents/products/material/accura/Accura Bluestone plastic E.pdf
• [21] Ahram T.Z., Karwowski W., Engineering sustainable complex systems, Management and Production Engineering Review, 4, 4, 4-14, 2013.
• [22] Wua D., Rosena D.W., Wangb L., Schaefer D., Cloud-based design and manufacturing: A new paradigm in digital manufacturing and design innovation, Computer-Aided Design, 59, 1-14, 2015.
• [23] Koch M., Sturm S., Düngen M., Innovationsfelder der Kunststofftechnik, Roadmap für die Thüringer Kunststoffverarbeitungsindustrie, TU Ilmenau, 2011.
• [24] Colombo A.W., Bangemann T., Karnouskos S., Delsing S., Stluka P., Harrison R. et al., Industrial cloud-based cyber-physical systems, Springer International Publishing, 2014.
• [25] Yablochnikov E.I., Vosorkin A.S., Tsupikov A.V., Integrated system for polymer composite material products development based on PLM methodology, Software & Systems, 2, 100-104, 2014.