An integrated system of computer simulation of processes of pressure treatment of powder components

1. M. B. Shtern, “Development of the theory of compacting and plastic deformation of powder materials,” Poroshk. Metall., No. 9, 12–24 (1992).

2. S. Shima and M. Oyane, “Plasticity theory for porous metals,” Int. J. Mech. Sci.,18, No. 6, 285–291 (1976).

   Google Scholar 

3. V. V. Skorokhod, M. B. Shtern, and I. F. Martynova, “Theory of nonlinear-viscose and plastic behavior of porous materials,” Poroshk. Metall., No. 8, 23–30 (1987).

   Google Scholar 

4. G. L. Petrosyan, Plastic Deformation of Powder Materials [in Russian], Metallurgiya, Moscow (1988).

   Google Scholar 

5. V. V. Skorokhod and L. I. Tuchinskii, “Plasticity condition of porous solids,” Poroshk. Metall., No. 11, 83–87 (1978).

6. A. M. Laptev, “Plasticity criteria of porous metals,” Poroshk. Metall., No. 7, 12–18 (1982).

7. M. S. Koval'chenko, Theoretical Fundamentals of Hot Pressure Treatment of Porous Materials [in Russian], Naukova Dumka, Kiev (1980).

   Google Scholar 

8. V. A. Druyanov, Applied Theory of Plasticity of Porous Bodies [in Russian], Mashinostroenie, Moscow (1989).

   Google Scholar 

9. M. Oyane, T. Kawakami, and S. Shima, “Plasticity theory for porous metals and application,” J. Jap. Soc. Powder Powder Met.,20, No. 5, 142–156 (1978).

   Google Scholar 

10. G. G. Serdyuk and O. V. Mikhailov, “Stress state of two-layered porous cylinders under radial deformation,” Poroshk. Metall., No. 2, 18–22 (1989).

11. G. Ya. Gun, O. B. Sadykhov, and A. A. Frolov, “A system for designing technological regimes of hot isostatic compacting,” Poroshk, Metall., No. 6, 12–17 (1991).

12. E. A. Olevskii, M. B, Shtern, G. G. Serdyuk, et al., “Determination of the density field in compacting components of complicated form by the method of permeable elements,” Poroshk. Metall., No. 3, 15–21 (1989).

13. A. L. Novofastovskii, “Mathematical simulation of the process of compacting powders by the large particle method,” Poroshk. Metall., No. 12, 4–7 (1989).

14. G. Eremenko, Graphical Possibilities of the Computer: Graphical Board can Replace the Work Station, SOFT-MARKET, 4(68), 6 (1993).

15. A. I. Boldyrev, O. V. Mihailov, and V. G. Moroz, “IBM PC XT/AT based 2-D geometry modeling and finite elements analysis interactive integrated shell system,” in: Int. Conf. “Artificial intelligence-industrial application,” Leningrad (1990), pp. 217–219.

16. O. V. Mikhailov, “An integrated instrumental system-shell for geometrical modeling and numerical solution of physical problems for two-dimensional objects in a IBM PC XT/AT (TEKHNOMOD),” in: Programing Technology of the Nineties, Proceedings of an International Conference/Exhibition, Kiev (1991), pp. 202–203.

17. A. S. Tsybenko, N. G. Vashchenko, N. G. Kritshchuk, et al., An Automated System for Finite-Element Calculations [in Russian], Vishcha shkola, Kiev (1986).

    Google Scholar 

18. G. G. Serdyuk and O. V. Mikhailov, “Mathematical simulation of plastic deformation of porous materials in the presence of the free surface,” Poroshk. Metall., No. 4, 18–22 (1986).

19. V. M. Gorokhov, E. A. Doroshkevich, E. V. Zvonarev, et al., “Elastoplastic deformation of sintered porous materials in pressure treatment processes. I. Theory of elastoplastic deformation of porous materials,” Poroshk. Metall., No. 4, 1–5 (1992).

20. T. Tabata and S. Masaki, “A criterion of fracture of porous materials and its application in selecting the form of sintered blanks for stamping,” Tor. Osnovy Inzh. Rashch., No. 1, 17–22 (1977).

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