Abstract
A two-dimensional mathematical model describing a combination of the processes of self-propagating high-temperature synthesis and selective laser sintering of powder compositions (it is controlled by the laser-radiation energy) has been proposed. The model makes it possible to evaluate the correspondence of the geometric characteristics of the system to the values of the velocities of a moving laser spot at which the layer poured completely reacts in the vicinity of the spot.
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V. V. Bagrov, N. A. Klimov, S. V. Nefedov, A. L. Petrov, V. I. Shcherbakov, and I. V. Shishkovskii, Program-device system on selective laser sintering, Izv. Nauch. Tsentra Ross. Akad. Nauk, 5, No. 1 (9), 55–64 (2003).
I. V. Shishkovskii, A. G. Makarenko, and A. L. Petrov, Studying the conditions of SHS of intermetallides in selective laser sintering of a powder composition, Fiz. Goreniya Vzryva, 35, No. 2, 59–64 (1999).
I. V. Shishkovskii, D. M. Gureev, and A. L. Petrov, Formation of biocompatible intermetallide phases in laser sintering of powder SHS compositions, Izv. Ross. Akad. Nauk, Ser. Fizicheskaya, 63, No. 10, 2077–2081 (1999).
A. V. Kamashev, A. S. Panin, A. L. Petrov, and I. V. Shishkovskii, Use of a laser source for synthesis of intermetallides in the system Ni-Al, Pis’ma Zh. Tekh. Fiz., 27, Issue 12, 28–33 (2001).
Yu. G. Morozov, S. A. Nefedov, A. S. Panin, A. L. Petrov, and I. V. Shishkovskii, Studying the conditions of selective laser sintering in the powder system Al-Ti, Izv. Ross. Akad. Nauk, Ser. Fizicheskaya, 66, No. 8, 1156–1158 (2002).
D. M. Gureev, R. V. Ruzhechko, and I. V. Shishkovskii, Studying the conditions of selective laser sintering of ceramic powder materials of the lead zirconate-titanate system, Pis’ma Zh. Tekh. Fiz., 26, Issue 6, 84–89 (2000).
I. V. Shishkovskii, M. V. Kuznetsov, and Yu. G. Morozov, Manufacture of bulk products based on barium hexaferrite with addition of chromium by combining the processes of SHS and SLS, Steklo Keram., 60, No. 6, 14–18 (2003).
K. Dai and L. Shaw, Thermal and mechanical finite element modeling of laser forming from metal and ceramic powders, Acta Materialia, 52, 69–80 (2004).
G. B. M. Cervera and G. Lombera, Numerical prediction of temperature and density distributions in selective laser sintering processes, Rapid Prototyping J., 5, No. 1, 21–26 (1999).
Y. Zhang, A. Faghri, C. M. Buckley, and T. L. Bergman, Three-dimensional sintering of two-component metal powders with stationary and moving laser beams, J. Heat Transfer, Trans. ASME, 122, No. 2, 150–158 (2000).
S. E. Zakiev and L. G. Shkadinskii, Thermal effect of high-frequency radiation on the front of high-temperature synthesis, Khim. Fiz., 17, No. 10, 112–120 (1998).
A. M. Ivanova, S. P. Kotova, N. L. Kupriyanov, E. Yu. Tarasova, and I. V. Shishkovskii, Physical principles of the process of selective laser sintering of metal-polymer powder compositions, Kvantovaya Élektron., 28, No. 5, 433–438 (1998).
I. V. Shishkovsky, Thermal field analysis under SLS of metal-polymer powder compositions, Proc. SPIE, 4, 446–449 (2002).
A. G. Merzhanov, History and new developments in SHS, Ceram. Trans., 56, 3–25 (1995).
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Translated from Inzhenerno-Fizicheskii Zhurnal, Vol. 78, No. 6, pp. 42–48, November–December, 2005.
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Kholpanov, L.P., Zakiev, S.E. & Shishkovskii, I.V. Modeling of thermal processes in laser sintering of reactive powder compositions. J Eng Phys Thermophys 78, 1088–1095 (2005). https://doi.org/10.1007/s10891-006-0038-9
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DOI: https://doi.org/10.1007/s10891-006-0038-9