УСТАНОВКА ДЛЯ СЕЛЕКТИВНОГО ЛАЗЕРНОГО СПЕКАНИЯ ВЫСОКОТЕМПЕРАТУРНЫХ ПОЛИМЕРОВ* (27-34)

DOI:

Дата публикации статьи в журнале: 2018/08/15

Название журнала: Евразийский Союз Ученых — публикация научных статей в ежемесячном научном журнале, Выпуск: 52, Том: 1, Страницы в выпуске: 27-34

Автор: Назаров Алексей Петрович
, ФГБОУ ВО «МГТУ «СТАНКИН», Москва

Автор: Скорняков Иннокентий Алексеевич
, ФГБОУ ВО «МГТУ «СТАНКИН», Москва

Автор: Шишковский Игорь Владимирович
, ФГБУН Физический институт им. П.Н. Лебедева РАН ,

Анотация: В данной работе представлена конструкция аддитивной установки для селективного лазерного спекания высокотемпературных полимерных материалов, отличающаяся оригинальной системой контроля юстировки устройства нанесения слоев порошка полиэфирэфиркетона. Приведены ее кинематическая и лазерно-оптическая схемы. Описаны основные контуры охлаждения. Технические и конструкторские решения, предложенные нами, позволяют проводить селективное лазерное спекание целого спектра различных порошковых материалов на основе полиэфиэфиркетона. Раскрыты принципы юстировки устройства нанесения слоев порошка, основанные на интегральном тепловом анализе нагрева наносимых слоев порошка. Описаны эксперименты, проводимые при пуско-наладке установки.

Ключевые слова: селективное лазерное спекание, установка,конструкция,высокотемпературные полимеры,полиэфиркетон,

Данные для цитирования: Назаров Алексей Петрович Скорняков Иннокентий Алексеевич Шишковский Игорь Владимирович. УСТАНОВКА ДЛЯ СЕЛЕКТИВНОГО ЛАЗЕРНОГО СПЕКАНИЯ ВЫСОКОТЕМПЕРАТУРНЫХ ПОЛИМЕРОВ* (27-34) // Евразийский Союз Ученых — публикация научных статей в ежемесячном научном журнале. Технические науки. 2018/08/15; 52(1):27-34.

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Список литературы: 1. Gibson, I.; Rosen, D.W.; and Stucker, B. Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing. New York, NY: Springer, 2010. 2. Rundle, G.A. Revolution in the Making: 3D Printing, Robots and the Future; Affirm Press: South Melbourne, Australia, 2014. 3. Shishkovsky I.V. Laser synthesis of functional mesostructures and 3D parts. Fizmatlit Publ.: Moscow, 2009. 4. Nazarov A.P. Perspective of rapid prototyping via selective laser sintering/melting method. Vestnik MGTU «Stankin». 2011, (4), 46-51. 5. Tarasova, T.V.; Nazarov A.P. Investigation of the processes of modification of the surface layer and the manufacture of three-dimensional engineering components through selective laser melting. Vestnik MGTU «Stankin». 2013, (2), 17-21. 6. Kinstlinger, I.S.; Bastian, A.; Paulsen, S.J.; Hwang, D.H.; Ta, A.H.; Yalacki, D.R. ; Schmidt, T.; Miller, J. S. Open-Source Selective Laser Sintering (OpenSLS) of Nylon and Biocompatible Polycaprolactone. PLoS One. 2016, 11(2), e0147399. doi: 10.1371/journal.pone.0147399 7. Van Hooreweder, B.; Moens, D.; Boonen, R.; Kruth, J.-P.; Sas, P. On the difference in material structure and fatigue properties of nylon specimens produced by injection molding and selective laser sintering, Polymer Testing, 2013, 32(5), 972-981. 8. Nelson, J.S.; Xue, S.; Barlow, J.W. et al. Model of Selective Laser Sintering of Bisphenol-A Polycarbonate. Ind. Chem. Eng. Res. 1993, 32, 2305-2317. 9. Berzins, M.; Childs, T.H.C.; Ryder, G.R.The Selective Laser Sintering of Polycarbonate. CIRP Annals. 1996, 45(1), 187-190.doi: 10.1016/S0007- 8506(07)63044-3 10. Ivanova, A.M.; Kotova, S.P.; Kupriyanov, N.L.; Petrov, A.L.; Tarasova, E.Yu; Shishkovskii, I.V. Physical characteristics of selective laser sintering of metal—polymer powder composites. Quantum Electronics, Vol. 28, 1998, No 5, P. 420-425. doi: 10.1070/QE1998v028n05ABEH001240 11. Shishkovskii, IV; Kupriyanov, NL Thermal fields in metal-polymer powder compositions during laser treatment . High temperature 1997, 35 (5), 710714. 12. Ho, H.C.H.; Cheung, W.L.; Gibson, I. Morphology and Properties of Selective Laser Sintered Bisphenol A Polycarbonate. Ind. Eng. Chem. Res., 2003, 42(9), 1850–1862. DOI: 10.1021/ie0206352 13. Goodridge, RD; Tuck, CJ; Hague, RJM. Laser sintering of polyamides and other polymers Progress in Materials Science 2012, 57 (2), 229-267. 14. Franco, A.;; Lanzetta, M. ; Romoli L.., Experimental analysis of selective laser sintering of polyamide powders: an energy perspective. Journal of Cleaner Production 2010, 18(16–17), 1722-1730 https://doi.org/10.1016/j.jclepro.2010.07.018 15. Goodridge, RD ; Hague, RJM ; Tuck, CJ. Effect of long-term ageing on the tensile properties of a polyamide 12 laser sintering material. Polymer Testing 2010, 29 (4), 483-493. 16. Shishkovsky, I.V.; Juravleva, I.N. Kinetics of polycarbonate distraction during laser-assisted sintering. International Journal of Advanced Manufacturing Technology, 2014, 72, 193-199. 10.1007/s00170-013- 5575-8 17. Shishkovsky, I.; Nagulin, K.; Sherbakov, V. Study of biocompatible nano oxide ceramics, interstitial in polymer matrix during laser-assisted sintering. International Journal of Advanced Manufacturing Technology. 2015, 78(1-4), 449-455. 10.1007/s00170- 014-6633-6 18. Goodridge, RD; Hague, RJM; Tuck, CJ. An empirical study into laser sintering of ultra-high molecular weight polyethylene (UHMWPE) Journal of Materials Processing Technology 2010, 210 (1), 72-80. 19. Laureto, J.J.; Dessiatoun, S.V.; Ohadi, M.M.; Pearce, J.M. Open Source Laser Polymer Welding System: Design and Characterization of Linear Low-Density Polyethylene Multilayer Welds. Machines 2016, 4, 14. 20. Tarasova, E; Juravleva, I.; Shishkovsky, I.; Ruzhechko, R. Layering laser-assisted sintering of functional graded porous PZT ceramoplasts. Phase Transitions - A Multinational Journal. 2013, 86(11), 1121-1129. 10.1080/01411594.2013.803105 21. Volyansky, I.; Shishkovsky, I. Laser assisted 3D printing of functional graded structures from polymer covered nanocomposites. p. 237-258. Book Chapter 11 in InTech Publ., Igor V. Shishkovsky (Ed.) 'New Trends in 3D Printing', 2016, Rijeka, Croatia, 268 p. Open access 22. Serra, T.; Planell, J.A.; Navarro, M. High-resolution PLA-based composite scaffolds via 3-D printing technology. Acta Biomaterialia 2013, 9(3), 5521- 5530 doi: 10.1016/j.actbio.2012.10.041 23. Chia, H.N.; Wu, B.M. Recent advances in 3D printing of biomaterials. Journal of Biological Engineering 2015, 9, 4. doi: 10.1186/s13036-015- 0001-4 24. Trachtenberg, JE; Mountziaris, PM; Miller, JS; Wettergreen, M; Kasper, FK, Mikos, AG. Opensource three-dimensional printing of biodegradable polymer scaffolds for tissue engineering. 2014, 102(12) 4326–4335. DOI: 10.1002/jbm.a.35108 25. Laureto, J.; Tomasi, J.; King, J.A ; Pearce, J.M. Thermal properties of 3-D printed polylactic acidmetal composites. Progress in Additive Manufacturing 2017, 2(1), 57–71. 26. Wittbrodt, B.; Pearce, J.M. The effects of PLA color on material properties of 3-D printed components. Additive Manufacturing 2015, 8, 110-116. doi: 10.1016/j.addma.2015.09.006 27. EOS Plastic Materials for Additive Manufacturing. https://www.eos.info/material-p (accessed on 10 January 2018). 28. https://en.wikipedia.org/wiki/Polyether_ether_ketone (accessed on 10 January 2018). 29. VICTREX™ PEEK Polymers. https://www.victrex.com/~/media/datasheets/victrex_tds_450g.ashx (accessed on 10 January 2018) 30. Berretta, S.; Evans, K.E.; Ghita, O. Processability of PEEK, a new polymer for High Temperature Laser Sintering (HT-LS). European Polymer Journal, 2015, 68, 243-266. 31. Schmidt, M.; Pohle, D. Rechtenwald, T. Selective Laser Sintering of PEEK. CIRP Annals - Manufacturing Technology, 2007, 56(1), 205-208. 32. PEEK (Polyarylethe-retherketone). http://www.bpf.co.uk/plastipedia/polymers/peek.aspx (accessed on 10 January 2018). 33. EOS Systems and Equipment for Plastic Additive Manufacturing. https://www.eos.info/systems_solutions/plastic/systems_equipment (accessed on 10 January 2018) 34. 3D Systems - https://www.3dsystems.com/3dprinters/plastic#selective-laser-sintering-printers-sls (accessed on 10 January 2018) 35. EOS P 500 - The automation-ready manufacturing platform for laser sintering of plastic parts on an industrial scale - https://www.eos.info/systems_solutions/eos-p-500 (accessed on 17 January 2018) 36. Zhirnov, I.; Podrabinnik, P.; Okunkova, A.; Gusarov, V. Laser beam profiling: experimental study of its influence on single-track formation by selective laser melting. Mechanics & Industry, 2015, 16(7), 709. doi: 10.1051/meca/2015082 37. Gusarov, V.; Okunkova, A.; Peretyagin, P.; Zhirnov, I.; Podrabinnik, P. Means of Optical Diagnostics of Selective Laser Melting with Non-Gaussian Beams. Measurement Techniques, 2016, 58(10), 1185– 1185. doi: 10.1007/s11018-015-0810-3 38. πShaper - http://www.pishaper.com/public.php (accessed on 10 January 2018) 39. HEATRODSHOP - http://www.heatrod- shop.com/product/qhs (accessed on 10 January 2018) 40. Mir nagreva - https://www.mirnagreva.ru/catalog/infrakrasnye_nagrevateli_obogrevateli_lampy/kvartsevy e_nagrevateli/kvartsevye_galogenovye_izluchateli/ (accessed on 10 January 2018) 41. Thermon - http://www.thermon.co.za/catalogue/heating-elements/flat-elements-box-heaters/thermon-fc-flat-heater-ceramic-insulation (accessed on 10 January 2018) 42. Marion - http://elektroteni.ru/ploskie.html (accessed on 10 January 2018)