Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials
Аутори
Konovalov, SergeyChen, Xizhang
Sarychev, Vladimir
Nevskii, Sergey
Gromov, Victor
Trtica, Milan
Чланак у часопису (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
Numerous processes take place in materials under the action of concentrated energy flows. The most important ones include heating together with the temperature misdistribution throughout the depth, probable vaporization on the surface layer, melting to a definite depth, and hydrodynamic flotation; generation of thermo-elastic waves; dissolution of heterogeneous matrix particles; and formation of nanolayers. The heat-based model is presented in an enthalpy statement involving changes in the boundary conditions, which makes it possible to consider melting and vaporization on the material surface. As a result, a linear dependence of penetration depth vs. energy density has been derived. The model of thermo-elastic wave generation is based on the system of equations on the uncoupled one-dimensional problem of dynamic thermo-elasticity for a layer with the finite thickness. This problem was solved analytically by the symbolic method. It has been revealed for the first time that the generate...d stress pulse comprises tension and compression zones, which are caused by increases and decreases in temperature on the boundary. The dissolution of alloying elements is modeled on the example of a titanium-carbon system in the process of electron beam action. The mathematical model is proposed to describe it, and a procedure is suggested to solve the problem of carbon distribution in titanium carbide and liquid titanium-carbide solution in terms of the state diagram and temperature changes caused by phase transitions. Carbon concentration vs. spatial values were calculated for various points of time at diverse initial temperatures of the cell. The dependence of carbon particle dissolution on initial temperature and radius of the particle were derived. A hydrodynamic model based on the evolution of Kelvin-Helmholtz instability in shear viscous flows has been proposed to specify the formation of nanostructures in materials subjected to the action of concentrated energy flows. It has been pointed out for the first time that, for certain parameters of the problem, that there are two micro-and nanoscale peaks in the relation of the decrement to the wavelength of the interface disturbance.
Кључне речи:
electron-beam treatment / Kelvin-Helmholtz instability / thermoelastic waves / nanostructuresИзвор:
Metals, 2017, 7, 1Финансирање / пројекти:
- Russian Scientific Foundation [15-19-00065]
- Russian Foundation for Basic Research [15-08-03411a]
- National Natural Science Foundation of China [51575401]
- Zhejiang Provincial Natural Science Foundation [LY16E050007]
DOI: 10.3390/met7010004
ISSN: 2075-4701
WoS: 000396509900004
Scopus: 2-s2.0-85009809596
Колекције
Институција/група
VinčaTY - JOUR AU - Konovalov, Sergey AU - Chen, Xizhang AU - Sarychev, Vladimir AU - Nevskii, Sergey AU - Gromov, Victor AU - Trtica, Milan PY - 2017 UR - https://vinar.vin.bg.ac.rs/handle/123456789/1463 AB - Numerous processes take place in materials under the action of concentrated energy flows. The most important ones include heating together with the temperature misdistribution throughout the depth, probable vaporization on the surface layer, melting to a definite depth, and hydrodynamic flotation; generation of thermo-elastic waves; dissolution of heterogeneous matrix particles; and formation of nanolayers. The heat-based model is presented in an enthalpy statement involving changes in the boundary conditions, which makes it possible to consider melting and vaporization on the material surface. As a result, a linear dependence of penetration depth vs. energy density has been derived. The model of thermo-elastic wave generation is based on the system of equations on the uncoupled one-dimensional problem of dynamic thermo-elasticity for a layer with the finite thickness. This problem was solved analytically by the symbolic method. It has been revealed for the first time that the generated stress pulse comprises tension and compression zones, which are caused by increases and decreases in temperature on the boundary. The dissolution of alloying elements is modeled on the example of a titanium-carbon system in the process of electron beam action. The mathematical model is proposed to describe it, and a procedure is suggested to solve the problem of carbon distribution in titanium carbide and liquid titanium-carbide solution in terms of the state diagram and temperature changes caused by phase transitions. Carbon concentration vs. spatial values were calculated for various points of time at diverse initial temperatures of the cell. The dependence of carbon particle dissolution on initial temperature and radius of the particle were derived. A hydrodynamic model based on the evolution of Kelvin-Helmholtz instability in shear viscous flows has been proposed to specify the formation of nanostructures in materials subjected to the action of concentrated energy flows. It has been pointed out for the first time that, for certain parameters of the problem, that there are two micro-and nanoscale peaks in the relation of the decrement to the wavelength of the interface disturbance. T2 - Metals T1 - Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials VL - 7 IS - 1 DO - 10.3390/met7010004 ER -
@article{ author = "Konovalov, Sergey and Chen, Xizhang and Sarychev, Vladimir and Nevskii, Sergey and Gromov, Victor and Trtica, Milan", year = "2017", abstract = "Numerous processes take place in materials under the action of concentrated energy flows. The most important ones include heating together with the temperature misdistribution throughout the depth, probable vaporization on the surface layer, melting to a definite depth, and hydrodynamic flotation; generation of thermo-elastic waves; dissolution of heterogeneous matrix particles; and formation of nanolayers. The heat-based model is presented in an enthalpy statement involving changes in the boundary conditions, which makes it possible to consider melting and vaporization on the material surface. As a result, a linear dependence of penetration depth vs. energy density has been derived. The model of thermo-elastic wave generation is based on the system of equations on the uncoupled one-dimensional problem of dynamic thermo-elasticity for a layer with the finite thickness. This problem was solved analytically by the symbolic method. It has been revealed for the first time that the generated stress pulse comprises tension and compression zones, which are caused by increases and decreases in temperature on the boundary. The dissolution of alloying elements is modeled on the example of a titanium-carbon system in the process of electron beam action. The mathematical model is proposed to describe it, and a procedure is suggested to solve the problem of carbon distribution in titanium carbide and liquid titanium-carbide solution in terms of the state diagram and temperature changes caused by phase transitions. Carbon concentration vs. spatial values were calculated for various points of time at diverse initial temperatures of the cell. The dependence of carbon particle dissolution on initial temperature and radius of the particle were derived. A hydrodynamic model based on the evolution of Kelvin-Helmholtz instability in shear viscous flows has been proposed to specify the formation of nanostructures in materials subjected to the action of concentrated energy flows. It has been pointed out for the first time that, for certain parameters of the problem, that there are two micro-and nanoscale peaks in the relation of the decrement to the wavelength of the interface disturbance.", journal = "Metals", title = "Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials", volume = "7", number = "1", doi = "10.3390/met7010004" }
Konovalov, S., Chen, X., Sarychev, V., Nevskii, S., Gromov, V.,& Trtica, M.. (2017). Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials. in Metals, 7(1). https://doi.org/10.3390/met7010004
Konovalov S, Chen X, Sarychev V, Nevskii S, Gromov V, Trtica M. Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials. in Metals. 2017;7(1). doi:10.3390/met7010004 .
Konovalov, Sergey, Chen, Xizhang, Sarychev, Vladimir, Nevskii, Sergey, Gromov, Victor, Trtica, Milan, "Mathematical Modeling of the Concentrated Energy Flow Effect on Metallic Materials" in Metals, 7, no. 1 (2017), https://doi.org/10.3390/met7010004 . .