Comparative analysis of computer systems for casting processes simulation

Danylchenko, Larysa

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Title:	Comparative analysis of computer systems for casting processes simulation
Authors:	Danylchenko, Larysa
Affiliation:	Ternopil National Ivan Puluj Technical University, Rus’ka str. 56, 46001, Ternopil, Ukraine
Bibliographic description (Ukraine):	Danylchenko L. Comparative analysis of computer systems for casting processes simulation / Larysa Danylchenko // ICAAEIT 2021, 15-17 December 2021. — Tern. : TNTU, Zhytomyr «Publishing house „Book-Druk“» LLC, 2021. — P. 105–113. — (Electrical engineering and power electronics).
Bibliographic description (International):	Danylchenko L. (2021) Comparative analysis of computer systems for casting processes simulation. ICAAEIT 2021 (Tern., 15-17 December 2021), pp. 105-113.
Is part of:	Proceedings of the International Conference „Advanced applied energy and information technologies 2021”, 2021
Issue Date:	15-十二月-2021
Date of entry:	28-十二月-2021
Publisher:	TNTU, Zhytomyr «Publishing house „Book-Druk“» LLC
Place of the edition/event:	Ternopil
Temporal Coverage:	15-17 December 2021
Keywords:	casting process computer modeling casting simulation software
Number of pages:	9
Page range:	105-113
Start page:	105
End page:	113
Abstract:	Casting processes simulation is one of the advanced research tendencies of foundry production. This article analyzes the current state and prospects for the development of innovative computer technologies in the national and world foundry. The main directions of the strategy for the further development of the foundry are formulated. An overview of the most well-known systems for computer modeling of foundry processes is presented, which allow simulating and controlling the quality of castings to maximize productivity and minimize defects. However, the choice of software for casting processes simulation is of decisive importance, which requires reliable information about the capabilities of computer programs and the principles of their operation. The purpose of the study is to carry out a comparative analysis of the most well-known systems for casting processes simulation and the possibility of their use for various casting methods. The software tools were compared by purpose, functionality, the number of simulated technological processes, the numerical method used for solving the problems of differential equations in the shaping of the casting, as well as the degree of completeness of the factors taken into account in the simulation. The research results can serve as recommended guidelines for specialists and managers of foundries on the choice of the necessary software, taking into account their requirements and the special aspects of the casting processes.
URI:	http://elartu.tntu.edu.ua/handle/lib/36933
ISBN:	978-617-8079-60-4
Copyright owner:	© Ternopil Ivan Puluj National Technical University, Ukraine, 2021
References (International):	1. Danylchenko, L., Radyk, D. (2021). Features of introduction the additive technologies in workpieces’ manufacturing processes. Problems of design theory and manufacture of transport and technological machines, Preceeding of the International Scientific and Technical Conference dedicated to the memory of Prof. Hevko B. Ternopil, Ukraine. 2. Cleary, P., Ha, J., Alguine, V., Nguyen, T. (2002). Flow modelling in casting processes. Applied Mathematical Modelling, 26(2), 171-190, doi: 10.1016/S0307. 3. Fu, M.W., Yong, M. S. (2009). Simulation-enabled casting product defect prediction in die casting process. International Journal of Production Research, 47(18), 5203-5216, doi: 10.1080/00207540801935616. 4. Jolly, M. (2003). Castings (Cʼh. 1.18), Milne, 1., Ritchie, R., Karihaloo, B. L. (Eds.). Comprehensive Structural Integrity, Vol. 1, Elsevier, Pergamon, Amsterdam, pp. 377-466. 5. Khan, M.A.A., Sheikh, A.K. (2016). Simulation tools in enhancing metal casting productivity and quality. Proceeding of the Institution of Mechanical Engineers, part B; Journal of Engineering Manufacture, 230(10), 1799-1817, doi: 10.1177/0954405416640183. 6. Koptev, A. (2016). The Navier–Stokes equations. From theory forward to solution of practical problems. International Research Journal, 49(7-4), 86–89. 7. Lewis, R. W., Ravindran, K. (2000). Finite element simulation of metal casting. International Journal for Numerical Methods in Engineering, 47(1-3), 29-59, doi: 10.1002/(SIC1) 1097-0207(20000110/30)47. 8. Pylypets, M., Danylchenko, L. (2019). Simulation modeling in designing applications for sheet metal forming. XXI-th scientific conference of Ternopil Ivan Pul’uj National Technical University, Preceeding of the International conference. Ternopil, Ukraine. 9. Shirokikh, E., Perfilova, V. (2015). Improving pouring gate systems in casting process computer modeling. Bulletin of the Moscow Region State University, 20(4), 65–69. 10. Sutaria, M., Ravi, B. (2014). Computation of casting solidication feed-paths using gradient vector method with various boundary conditions. The International Journal of Advanced Manufacturing Technology, 75(1-4), 209-223, doi: 10. 1007/s00170-014-6049-3.
Content type:	Conference Abstract
�蝷箔����:	International conference „Advanced Applied Energy and Information Technologies 2021“, (ICAAEIT 2021)

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