KOMBAYEV, Kuat ;MUZDYBAYEV, Murat ;MUZDYBAYEVA, Alfiya ;MYRZABEKOVA, Dinara ;WIELEBA, Wojciech ;LEŚNIEWSKI, Tadeusz . Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 68, n.9, p. 542-551, august 2022. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/>. Date accessed: 14 oct. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2022.147.
Kombayev, K., Muzdybayev, M., Muzdybayeva, A., Myrzabekova, D., Wieleba, W., & Leśniewski, T. (2022). Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing. Strojniški vestnik - Journal of Mechanical Engineering, 68(9), 542-551. doi:http://dx.doi.org/10.5545/sv-jme.2022.147
@article{sv-jmesv-jme.2022.147, author = {Kuat Kombayev and Murat Muzdybayev and Alfiya Muzdybayeva and Dinara Myrzabekova and Wojciech Wieleba and Tadeusz Leśniewski}, title = {Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {68}, number = {9}, year = {2022}, keywords = {low-carbon compound steel; strengthening; electrolytic plasma processing; }, abstract = {The modified technology for strengthening the surface layer of low-carbon steel for machine components by electroplasma processing is proposed. This technology is to be used as an alternative carburizing method with subsequent hardening. The developed technology of strengthening by the proposed method is based on the author’s invention. The parameters of this process are given, resulting in a thickness of the reinforced surface layer of 1000 µm to 1700 µm. An increase in microhardness of 1.5 to 2 times (compared to the initial state) was observed. With hardening, chemical modification of the material’s surface layer occurs. The microstructure of the treated surface of the steel samples is characterised by a dark modified surface layer: a fine needle-like structure of martensitic origin under the dark layer transforms into an initial perlite-ferritic structure. The advantage of strengthening based on the electrolytic plasma processing consists of low energy consumption at high hardening speeds and the possibility of local processing of surface areas, especially large parts of complex shapes. In addition, the proposed surface treatment method using electrolytic plasma processing (EPP) not only achieves a smooth surface but also improves the service qualities of the components, specifically wear resistance.}, issn = {0039-2480}, pages = {542-551}, doi = {10.5545/sv-jme.2022.147}, url = {https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/} }
Kombayev, K.,Muzdybayev, M.,Muzdybayeva, A.,Myrzabekova, D.,Wieleba, W.,Leśniewski, T. 2022 August 68. Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 68:9
%A Kombayev, Kuat %A Muzdybayev, Murat %A Muzdybayeva, Alfiya %A Myrzabekova, Dinara %A Wieleba, Wojciech %A Leśniewski, Tadeusz %D 2022 %T Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing %B 2022 %9 low-carbon compound steel; strengthening; electrolytic plasma processing; %! Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing %K low-carbon compound steel; strengthening; electrolytic plasma processing; %X The modified technology for strengthening the surface layer of low-carbon steel for machine components by electroplasma processing is proposed. This technology is to be used as an alternative carburizing method with subsequent hardening. The developed technology of strengthening by the proposed method is based on the author’s invention. The parameters of this process are given, resulting in a thickness of the reinforced surface layer of 1000 µm to 1700 µm. An increase in microhardness of 1.5 to 2 times (compared to the initial state) was observed. With hardening, chemical modification of the material’s surface layer occurs. The microstructure of the treated surface of the steel samples is characterised by a dark modified surface layer: a fine needle-like structure of martensitic origin under the dark layer transforms into an initial perlite-ferritic structure. The advantage of strengthening based on the electrolytic plasma processing consists of low energy consumption at high hardening speeds and the possibility of local processing of surface areas, especially large parts of complex shapes. In addition, the proposed surface treatment method using electrolytic plasma processing (EPP) not only achieves a smooth surface but also improves the service qualities of the components, specifically wear resistance. %U https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/ %0 Journal Article %R 10.5545/sv-jme.2022.147 %& 542 %P 10 %J Strojniški vestnik - Journal of Mechanical Engineering %V 68 %N 9 %@ 0039-2480 %8 2022-08-08 %7 2022-08-08
Kombayev, Kuat, Murat Muzdybayev, Alfiya Muzdybayeva, Dinara Myrzabekova, Wojciech Wieleba, & Tadeusz Leśniewski. "Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing." Strojniški vestnik - Journal of Mechanical Engineering [Online], 68.9 (2022): 542-551. Web. 14 Oct. 2024
TY - JOUR AU - Kombayev, Kuat AU - Muzdybayev, Murat AU - Muzdybayeva, Alfiya AU - Myrzabekova, Dinara AU - Wieleba, Wojciech AU - Leśniewski, Tadeusz PY - 2022 TI - Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing JF - Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2022.147 KW - low-carbon compound steel; strengthening; electrolytic plasma processing; N2 - The modified technology for strengthening the surface layer of low-carbon steel for machine components by electroplasma processing is proposed. This technology is to be used as an alternative carburizing method with subsequent hardening. The developed technology of strengthening by the proposed method is based on the author’s invention. The parameters of this process are given, resulting in a thickness of the reinforced surface layer of 1000 µm to 1700 µm. An increase in microhardness of 1.5 to 2 times (compared to the initial state) was observed. With hardening, chemical modification of the material’s surface layer occurs. The microstructure of the treated surface of the steel samples is characterised by a dark modified surface layer: a fine needle-like structure of martensitic origin under the dark layer transforms into an initial perlite-ferritic structure. The advantage of strengthening based on the electrolytic plasma processing consists of low energy consumption at high hardening speeds and the possibility of local processing of surface areas, especially large parts of complex shapes. In addition, the proposed surface treatment method using electrolytic plasma processing (EPP) not only achieves a smooth surface but also improves the service qualities of the components, specifically wear resistance. UR - https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/
@article{{sv-jme}{sv-jme.2022.147}, author = {Kombayev, K., Muzdybayev, M., Muzdybayeva, A., Myrzabekova, D., Wieleba, W., Leśniewski, T.}, title = {Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {68}, number = {9}, year = {2022}, doi = {10.5545/sv-jme.2022.147}, url = {https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/} }
TY - JOUR AU - Kombayev, Kuat AU - Muzdybayev, Murat AU - Muzdybayeva, Alfiya AU - Myrzabekova, Dinara AU - Wieleba, Wojciech AU - Leśniewski, Tadeusz PY - 2022/08/08 TI - Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 68, No 9 (2022): Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2022.147 KW - low-carbon compound steel, strengthening, electrolytic plasma processing, N2 - The modified technology for strengthening the surface layer of low-carbon steel for machine components by electroplasma processing is proposed. This technology is to be used as an alternative carburizing method with subsequent hardening. The developed technology of strengthening by the proposed method is based on the author’s invention. The parameters of this process are given, resulting in a thickness of the reinforced surface layer of 1000 µm to 1700 µm. An increase in microhardness of 1.5 to 2 times (compared to the initial state) was observed. With hardening, chemical modification of the material’s surface layer occurs. The microstructure of the treated surface of the steel samples is characterised by a dark modified surface layer: a fine needle-like structure of martensitic origin under the dark layer transforms into an initial perlite-ferritic structure. The advantage of strengthening based on the electrolytic plasma processing consists of low energy consumption at high hardening speeds and the possibility of local processing of surface areas, especially large parts of complex shapes. In addition, the proposed surface treatment method using electrolytic plasma processing (EPP) not only achieves a smooth surface but also improves the service qualities of the components, specifically wear resistance. UR - https://www.sv-jme.eu/article/functional-surface-layer-strengthening-and-wear-resistance-increasing-of-a-low-carbon-steel-details-of-machines-by-electrolytic-plasma-processing/
Kombayev, Kuat, Muzdybayev, Murat, Muzdybayeva, Alfiya , Myrzabekova, Dinara , Wieleba, Wojciech, AND Leśniewski, Tadeusz. "Functional Surface Layer Strengthening and Wear Resistance Increasing of a Low Carbon Steel by Electrolytic-Plasma Processing" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 68 Number 9 (08 August 2022)
Strojniški vestnik - Journal of Mechanical Engineering 68(2022)9, 542-551
© The Authors 2022. CC BY 4.0 Int.
The modified technology for strengthening the surface layer of low-carbon steel for machine components by electroplasma processing is proposed. This technology is to be used as an alternative carburizing method with subsequent hardening. The developed technology of strengthening by the proposed method is based on the author’s invention. The parameters of this process are given, resulting in a thickness of the reinforced surface layer of 1000 µm to 1700 µm. An increase in microhardness of 1.5 to 2 times (compared to the initial state) was observed. With hardening, chemical modification of the material’s surface layer occurs. The microstructure of the treated surface of the steel samples is characterised by a dark modified surface layer: a fine needle-like structure of martensitic origin under the dark layer transforms into an initial perlite-ferritic structure. The advantage of strengthening based on the electrolytic plasma processing consists of low energy consumption at high hardening speeds and the possibility of local processing of surface areas, especially large parts of complex shapes. In addition, the proposed surface treatment method using electrolytic plasma processing (EPP) not only achieves a smooth surface but also improves the service qualities of the components, specifically wear resistance.