Статті в журналах: "Steel 110G13L"

1

Dusevich, V. M., E. A. Shur, and I. A. Semenov. "Carbides in 110G13L steel." Metal Science and Heat Treatment 31, no. 9 (September 1989): 698–701. http://dx.doi.org/10.1007/bf00717492.

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2

Yanpolskiy, Vasily, Boris Krasilnikov, and Konstantin Rakhimyanov. "Electrolyte Pressure Influence on the Speed of Steel 110G13L Electrochemical Dissolution during Electrochemical Jet Machining." Applied Mechanics and Materials 698 (December 2014): 321–25. http://dx.doi.org/10.4028/www.scientific.net/amm.698.321.

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An experimental investigation of an electrochemical dissolution of steel 110G13L (steel of Hadfield) in NaNO3, Na2SO4, and NaCl aqueous solutions was carried out. It has been found that the electrochemical dissolution of steel 110G13L in NaNO3, Na2SO4 aqueous solutions occurs in the active state when φ = 4.5 V. Based on the results of the polarization analysis and determination of the steel 110G13L dissolution depth in each of these solutions, the rational electrolyte composition was chosen for ECJM. The technologic experiment has shown that an increase in the electrolyte feeding pressure up to two МPа leads to a machining depth increase up to 600 μm.

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3

Bolobov, Victor I., Stanislav A. Chupin, Erik V. Akhmerov, and Vyacheslav A. Plaschinskiy. "Comparative Wear Resistance of Existing and Prospective Materials of Fast-Wearing Elements of Mining Equipment." Materials Science Forum 1040 (July 27, 2021): 117–23. http://dx.doi.org/10.4028/www.scientific.net/msf.1040.117.

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The results of tests for resistance to abrasive wear on highly abrasive hard rock white electrocorundum are presented. The main material of fast-wearing elements of mining and processing equipment-110G13L steel (Gadfield steel) in comparison with other 9 grades of steel and cast iron, including specially developed wear-resistant foreign steels such as Hardox and Miiluks, is analyzed. The studies were carried out using an experimental stand for studying the material wearing process. On the stand the sample was fixed in a holding device and, after being brought into contact with the abrasive, it was rotated under a constant load. As a result of the experiments, it was confirmed that the order of placement of the tested materials in terms of increasing wear resistance coincides with their placement in terms of increasing hardness. At the same time, the wear resistance of the most resistant material – U8A steel after quenching – is about 4 times higher than this indicator for the least resistant components – low-carbon steel 25L, including gray and high-strength cast iron SCH21, VCH35. The wear resistance of 110G13L steel, as well as 65G, U8 steels in the hardened state, is from 1.5 to 2 times higher than that of foreign steels M400, H450, M500, H500. The results of the conducted studies allow us to evaluate the analyzed materials on the basis of their wear resistance and hardness indicators on the feasibility of using them in the manufacture of fast-wearing parts of mining equipment. Based on the research data, it seems promising to develop new ways to increase the wear resistance of domestic steel, including 110G13L steel traditionally used in mining.

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4

Poluboyarov, Vladimir A., Zoya A. Korotaeva, Alexander A. Zhdanok, and Victor A. Kuznetzov. "Nanodisperse Hadfield (110G13L) Steel Modification." Journal of Siberian Federal University. Engineering & Technologies 9, no. 1 (February 2016): 117–25. http://dx.doi.org/10.17516/1999-494x-2016-9-1-117-125.

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5

Poluboyarov, Vladimir A., Zoya A. Korotaeva, Alexander A. Zhdanok, and Victor A. Kuznetzov. "Nanodisperse Hadfield (110G13L) Steel Modification." Journal of Siberian Federal University. Engineering & Technologies 9, no. 1 (February 2016): 118–26. http://dx.doi.org/10.17516/1999-494x-2016-9-1-118-126.

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6

Steklov, O. I. "Flash welding of 110G13L steel (Hadfield steel)." Welding International 3, no. 10 (January 1989): 892–94. http://dx.doi.org/10.1080/09507118909446679.

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7

Rakhimyanov, Kh M., V. V. Yanpolskiy, and A. S. Yusupov. "Jet electrochemical machining of the steel 110G13L." Systems. Methods. Technologies, no. 2(30) (2016): 34–38. http://dx.doi.org/10.18324/2077-5415-2016-2-34-38.

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8

Filippov, Mikhail A., Elena I. Korzunova, and M. V. Tyumkova. "Engineering Method for Analysis of the Ability to Strain-Hardening of Steels." Solid State Phenomena 284 (October 2018): 1168–72. http://dx.doi.org/10.4028/www.scientific.net/ssp.284.1168.

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A study of the structure and strain-hardening ability relationship was carried out in this work for wear-resistant steels of two structural classes: high-manganese austenitic steel 110G13L and metastable austenitic chromium-manganese steel 60G9KhL. It is shown that the strain-hardening ability can be estimated using a methodologically simple engineering criterion. The criterion determines the metal tendency to harden by determining the Rockwell hardness at the bottom of the indentation cup of the Brinell press indenter

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9

Filippov, Mikhail A., G. Yagudin, V. Legchilo, M. Khadiyev, N. Ozerets, and S. Estemirova. "The Use of Metastable Austenite to Increase the Wear Resistance of Steels of the Pearlite Class." Solid State Phenomena 284 (October 2018): 1163–67. http://dx.doi.org/10.4028/www.scientific.net/ssp.284.1163.

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The wide application of steel 110G13L for armor plates in mills and crushers makes it urgent to search for alternative materials with close or sufficient operational stability in conditions of shock abrasive wear. A promising path in this direction is the replacement of steel 110G13L with high-carbon pearlitic steels. The aim of this work is a comparative study of the relationship between the structure formed in the heat treatment process of the low-alloyed pearlite steels 70X2GSML and 150HNML and their abrasive wear resistance. Special attention was paid to the possibility of using metastable austenite as a structural component, which increases the abrasive wear resistance of pearlitic steels. It is established that the steel of the pearlite class 70X2GSML, after normalization from 850 °C and tempering at 550 °C, can be used for casting armor plates for ball and rod mills, as well as to cast parts subjected to machining and operating under abrasive conditions without significant impact loads. It is shown that an additional reserve for increasing the abrasive wear resistance of steels of the pearlite class - 70X2GSML and 150XNML - is high-temperature quenching with the formation of a metastable austenite in the structure. The maximum abrasion wear resistance is achieved after the high-temperature quenching of steels (1150 °C) in oil, which forms a martensitic structure with a metastable austenite in the amount of 20-70%, which, with wear, turns into martensite with a high friction hardening ability on the wear surface.

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10

Kuskov, Yu M., F. K. Biktagirov, T. I. Grishchenko, and A. I. Evdokimov. "Electroslag surfacing of high-chromium cast iron with 110G13l steel." Paton Welding Journal 2018, no. 5 (May 28, 2018): 17–19. http://dx.doi.org/10.15407/tpwj2018.05.04.

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11

Vinokur, B. B., G. G. Lutsenko, S. E. Kondratyuk, and O. G. Kasatkin. "Abrasion resistance of 110G13L steel after heat treatment." Soviet Materials Science 21, no. 5 (1986): 501–3. http://dx.doi.org/10.1007/bf01147606.

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12

Seval’nev, G. S., T. G. Seval’neva, A. G. Kolmakov, K. V. Dulnev, and M. Yu Yazvitsky. "Influence of phase composition of austenitic-martensitic trip-steel VNS9-Sh on characteristics of dry sliding friction in tribocontact with steel ShKh 15." Deformation and Fracture of Materials, no. 10 (2021): 20–27. http://dx.doi.org/10.31044/1814-4632-2021-10-20-27.

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The influence of content of the martensite phase that is from 0 to 50% (vol.) on hardness and tribomechanical properties of trip-steel VNS9-Sh (ВНС9-Ш) under conditions of dry sliding friction on steel ShKh15 (ШХ15) (counterbody) has been investigated. It was found out that the best combination of hardness and wear resistance was possessed by steel with martensite phase content ≈32% (vol.). It is shown that with comparable hardness and tribomechanical properties, VNS9-Sh steel is more than twice as strong as 110G13L steel (110Г13Л).

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13

Balanovsky, A. E., M. G. Shtayger, V. V. Kondrat’ev, S. A. Nebogin, and A. I. Karlina. "Complex metallographic researches of 110G13L steel after heat treatment." IOP Conference Series: Materials Science and Engineering 411 (October 19, 2018): 012014. http://dx.doi.org/10.1088/1757-899x/411/1/012014.

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14

Chikova, O. A., N. I. Sinitsin, and V. V. V’yukhin. "Parameters of the Microheterogeneous Structure of Liquid 110G13L Steel." Russian Journal of Physical Chemistry A 93, no. 8 (August 2019): 1435–42. http://dx.doi.org/10.1134/s0036024419080065.

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15

Loktionov-Remizovsky, V. A., N. V. Kiryakova, G. E. Fedorov, N. N. Gribov, and I. V. Oleksenko. "Optimization of Carbon and Magganese Content in Steel 110G13L." Casting processes 142, no. 4 (December 1, 2020): 26–33. http://dx.doi.org/10.15407/plit2020.04.026.

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16

Guskov, A. V., K. M. Zubashevskii, K. E. Milevskii, and V. V. Samoilenko. "Effect of Explosion on the Mechanical Properties of 110G13L Steel." Combustion, Explosion, and Shock Waves 55, no. 6 (November 2019): 744–49. http://dx.doi.org/10.1134/s0010508219060170.

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17

Kuskov, Yu M., F. K. Biktagirov, T. I. Grishchenko, and A. I. Evdokimov. "Electroslag surfacing of high-chromium cast iron with 110G13l steel." Avtomatičeskaâ svarka (Kiev) 2018, no. 5 (May 28, 2018): 21–24. http://dx.doi.org/10.15407/as2018.05.04.

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18

Belyashin, P. A., �. P. Motus, and V. D. Tarlinskii. "Improvement of the weldability of high-manganese cast steel 110G13L." Chemical and Petroleum Engineering 26, no. 3 (March 1990): 154–57. http://dx.doi.org/10.1007/bf01147410.

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19

Popov, A. P., E. I. Mamaeva, B. M. Levin, T. V. Bodrova, and T. K. Kashirina. "Effect of alloying on the fatigue resistance of steel 110G13L." Metal Science and Heat Treatment 27, no. 12 (December 1985): 903–7. http://dx.doi.org/10.1007/bf00700098.

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20

Tulaganova, Vasila, Anvar Turaev, and Sadulla Fayzullayev. "Increasing the the wear resistance of parts made of 110G13L steel." ASIAN JOURNAL OF MULTIDIMENSIONAL RESEARCH 10, no. 5 (2021): 480–84. http://dx.doi.org/10.5958/2278-4853.2021.00435.3.

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21

Astaf'ev, A. A. "Effect of grain size on the properties of manganese austenite steel 110G13L." Metal Science and Heat Treatment 39, no. 5 (May 1997): 198–201. http://dx.doi.org/10.1007/bf02467284.

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22

Kurbatov, M. I., A. S. Nosenko, Ya P. Protsenko, and �. G. Zemka. "Influence of addition of Ti and V on the properties of 110G13L steel." Metal Science and Heat Treatment 32, no. 9 (September 1990): 711–13. http://dx.doi.org/10.1007/bf00693343.

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23

Nasirov, S. M., and S. A. Guseinov. "Phase composition and distribution of elements between phases for steel 110G13L after tempering." Metal Science and Heat Treatment 27, no. 7 (July 1985): 528–31. http://dx.doi.org/10.1007/bf00699586.

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24

Bolobov, V. I., and S. A. Chupin. "About the use of 110G13L steel as a material for the excavator bucket teeth." IOP Conference Series: Earth and Environmental Science 378 (November 13, 2019): 012005. http://dx.doi.org/10.1088/1755-1315/378/1/012005.

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25

Gabelchenko, Natalya, Artem Belov, Artem Kravchenko, and Oleg Kryuchkov. "Analysis of Wear-Resistant Materials of Mixer - Pneumosuperchargers Blades Operating under Conditions of Abrasive Wear." Solid State Phenomena 316 (April 2021): 893–98. http://dx.doi.org/10.4028/www.scientific.net/ssp.316.893.

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We conducted comparative tests of the wear resistance of metals operating under abrasive conditions. Samples were cut from the working parts of mixer-pneumosuperchargers. The chemical composition and mechanical properties were determined. To compare samples under abrasive wear conditions, we designed and assembled a carousel installation. The principle of its operation is based on mixing the abrasive medium by the samples being studied with a given speed. Wear resistance was evaluated by weight loss by samples after several test cycles. To determine changes in the structure of the metal during abrasive wear, metallographic studies of the samples were carried out before and after the tests. It is shown that the best complex of service and mechanical properties is possessed by 110G13L steel.

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26

Dragilev, B. L. "A surfacing alloy for hardening components of 110G13L steel and wear mechanism of the alloy." Welding International 3, no. 1 (January 1989): 58–60. http://dx.doi.org/10.1080/09507118909446582.

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27

Ten, E. B., T. A. Bazlova, and E. Yu Likholobov. "Effect of Out-of-Furnace Treatment on the Structure and Mechanical Properties of Steel 110G13l." Metal Science and Heat Treatment 57, no. 3-4 (July 2015): 146–50. http://dx.doi.org/10.1007/s11041-015-9853-y.

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28

Kondratyuk, S. E., and G. G. Lutsenko. "Determination of the heat-treatment cycle for 110G13L steel for increasing the abrasive wear resistance." Metal Science and Heat Treatment 27, no. 8 (August 1985): 621–24. http://dx.doi.org/10.1007/bf00699364.

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29

Chaykin, Andrey V., Vladimir A. Chaykin, Vitaly S. Lozov, Aset D. Kasimgazinov, Yury V. Karman, and Petr O. Bykov. "COMPARATIVE ANALISYS OF THE QUALITY INDICES OF THE 110G13L STEEL PRODUCED WITH VARIOUS INOCULANTS AND DEOXIDIZING AGENTS." Vestnik of Nosov Magnitogorsk State Technical University 16, no. 1 (2018): 19–25. http://dx.doi.org/10.18503/1995-2732-2018-16-1-19-25.

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30

Lazarova, R., P. Kuzmanov, R. Dimitrova, A. Cherepanov, and V. Manolov. "PROPERTIES OF 110G13L STEEL AND SCH 25 GREY CAST IRON, MODIFY ED BY NANOPOWDERS OF REFRACTORY COMPOUNDS." Izvestiya Visshikh Uchebnykh Zavedenii. Chernaya Metallurgiya = Izvestiya. Ferrous Metallurgy 55, no. 4 (January 1, 2012): 17–20. http://dx.doi.org/10.17073/0368-0797-2012-4-17-20.

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31

Davydov, N. G., and V. A. Lyamzin. "Heat Treatment of Parts and Castings from High-Manganese Steel of Type 110G13L and its Special Features." Metal Science and Heat Treatment 58, no. 9-10 (January 2017): 559–61. http://dx.doi.org/10.1007/s11041-017-0054-8.

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32

Leontiev, Mikhail Georgievich. "Compositions Based on Nanosized Powders Carbides of Tungsten and Titanium, Obtained by the Method Self-Propagating High Temperature Synthesis for the Modification of Gray Cast Iron and Steel 110g13L." Key Engineering Materials 802 (May 2019): 43–56. http://dx.doi.org/10.4028/www.scientific.net/kem.802.43.

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Iron-based alloys (steel and cast iron) are currently the main structural materials that provide a high level of mechanical and technological properties along with a relatively low cost. Increasing the performance characteristics (tensile strength, hardness, wear resistance, corrosion resistance and, ultimately, service life) of cast irons and steels is an urgent task. The quality of castings made of cast iron and steel depends on many technological parameters that affect the processes of crystallization of the melt (casting temperature, molding mixture, chemical composition, volume of casting, overheating of the metal during smelting, etc.). It is possible to improve the quality of castings without changing the technology of smelting and pouring metal into molds, if you learn how to manage the crystallization process. The laboratories have grown defect – free iron crystals with a tensile strength of more than 1000 kg/m2 (strength of carbon steel-40 kg/m2). Attempts to improve the mechanical properties by creating a single crystal are not justified, so you have to go the opposite way-to influence the crystallization process to get a lot of small crystals (grains), which also allows you to achieve high mechanical properties. The dependence of the strength characteristics on the grain size is well described by the law of Hall-Petch, according to which when the average grain size is reduced by 3...5 times there is an increase in the hardness of the material, with a further decrease in the average grain size by more than 10 times – an increase in plasticity. Influence on the processes of crystallization of iron and steel melts (change the size of metal grains, change the shape, size and distribution of graphite inclusions) can be the introduction of small additives substances (modifiers), not chemically interacting with the matrix. The use of modifiers to increase the rate of crystallization, reduce the structural heterogeneity of castings has good prospects. In addition, unlike doping, modification does not require a large number of expensive additives and, accordingly, slightly increases the final cost of production.

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33

Pashynskyi, Volodymyr, and Igor Boyko. "Study of the influence of the increased carbon content in electrodes on structure and properties of the welding seam during welding of 110G13 steel." Technology audit and production reserves 4, no. 3(60) (July 31, 2021): 14–17. http://dx.doi.org/10.15587/2706-5448.2021.237358.

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The object of research is the effect of the carbon-forming component of coated electrodes for welding and surfacing of Gadfield steel (110G13L and analogs) on the structure and properties of the weld. One of the most problematic areas in the welding and surfacing of high-carbon steel is the high irregularity of the rod and coating melting rates. Therefore, the non-melted part of the coating is literally poured into the weld pool, which leads to significant chemical and structural inhomogeneity of the welded metal. The main hypothesis of the study is the assumption that it is possible to increase the homogeneity of the deposited metal by changing the conditions for the transition of carbon from the electrode to the weld pool by using an electrode rod made of carbon steel. In the course of the study, electrode rods with different carbon contents were used. With an increase in the carbon content in the composition of the electrode rod, the fluidity of the drops increased, which contributed to a decrease in the strength of the welding current without harm to the welding and technological characteristics. This allows to reduce the generation of heat in the base metal, that is an effective measure to prevent hot cracks in the weld metal and heat affected zone Studies of the composition of the electrode metal droplets and the weld material showed that with an increase in the carbon content in the electrode rod from 0.08 % to 0.8 %, the carbon content in the droplets increases from 0.3 % to 0.97 %. The carbon content in the weld metal is 1.1 %. The assimilation of manganese by a drop increases with an increasing of coating and the droplet interaction time. A significant increasing in the rate of coating melting was obtained. This is due to the fact that the concomitant decrease in the content of graphite in the coating contributes to a decrease in the refractoriness of the electrode coating. The use of high carbon steels for the manufacturing of electrode rods for welding and surfacing of Gadfield steel improves the properties of the welded metal and sanitary and hygienic parameters.

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34

Filippov, Mikhail A., Elena I. Korzunova, and Valentina A. Sharapova. "Engineering Method for Analysis of the Ability to Strain-Hardening of Steels." Solid State Phenomena 299 (January 2020): 1190–94. http://dx.doi.org/10.4028/www.scientific.net/ssp.299.1190.

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The strain-hardening ability has been estimated using a methodologically simple engineering criterion. A simple engineering method estimates the ability of metals and alloys to strain-hardening by the hardness increase determining. The Rockwell hardness has been measured at the bottom of the indentation cup of the Brinell press indenter. The strain-hardening tendency is investigated by the “two hardness-measuring instruments” method for two austenitic manganese steels, 110G13L and 110G6L, with different austenite stability to strain martensitic transformation. This hardness estimating method can be applied without making special samples and using deforming equipment.

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35

Vdovin, Konstantin N., Nikolai A. Feoktistov, and Shamil M. Khabibullin. "Increasing the lifetime of cast high-manganese steel liners for the semi-autogenous grinding mill." Vestnik of Nosov Magnitogorsk State Technical University 17, no. 1 (March 25, 2019): 26–31. http://dx.doi.org/10.18503/1995-2732-2019-17-1-26-31.

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At the processing plants of the mining industry, a significant part of the total processing costs (from 45 to 65%) is spent on crushing and grinding operations, including mill lining. The efficiency of grinding equipment in the conditions of abrasive impact of ore and a continuous operation requires periodic replacement of a worn-out lining. The costs for its purchase, delivery and installation during a year amount to tens of millions of rubles, and the equipment downtime associated with the replacement of the lining reduces the volume of finished products by hundreds of millions of rubles per year. The practical efficiency of imported mill liners is not always confirmed by the expected positive result of their actual operation, and an increase in the equipment utilization coefficient (EUC), but their use definitely requires significant financial costs and entails risks in an unstable political and financial situation. Therefore, the task of increasing the service life of the mill liners is urgent. The paper presents a suggested and implemented solution to increase the lifetime of 110G13L steel lining for the wet semi-autogenous grinding mill (SAG mill-70х23). It includes monitoring of the actual liner operation and a mathematical simulation of the ore and ball trajectory in the mill, reveals zones of intensive wear, defects of liner castings and developed new structures of the lining elements. Applying the simulation software package, the authors studied the existing casting technologies, found reasons for defects and developed the casting technology for a new design of liners excluding defects. The paper contains industrial tests of the liners of a new design manufactured according to the developed technologies.

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36

Posviatenko, Eduard, Ruslan Budyak, and Petro Aksom. "EXPANSION OF APPLICATION OF AUSTENITE STEEL PRODUCTS IN THE FOOD INDUSTRY." ENGINEERING, ENERGY, TRANSPORT AIC, no. 1(112) (March 23, 2021): 70–80. http://dx.doi.org/10.37128/2520-6168-2021-1-9.

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The article considers the increase of machinability of austenitic steels by combining preliminary cold plastic deformation with the use of environmentally friendly lubricating and cooling fluids based on rapeseed oil. It is shown that by fusing plastic steels with a large amount of chromium, nickel and manganese, the Curie point can be reduced to room temperature. State diagrams of Fe - Mn and Fe - Cr - Ni systems after such transformations are considered. In the latter case, steels become suitable for products and technologies of the food industry, but they are difficult to process in mechanical technologies. The study of steels 12Х15G9ND (AISI 201) is given; 08X18H10 (AISI 304); 110G13L (A128). A mathematical model of the object of study was developed, where the process factors were cold plastic deformation (COD), lubricating and cooling fluid (MPC) and cutting speed. The optimization parameters were the shrinkage of the chips and the length of contact of the latter with the front surface of the tool. The equation of the mathematical model is given. A number of modern installations and methods of process research are described. Among the research methods, new ones are noted, in particular, methods of transverse compression, determination of the number of dislocations, spectral analysis, cutting of steels using MPAs of plant origin. The optimal brand of ecologically pure vegetable MPA is determined. It is rapeseed oil together with anti-emergency and anti-wear additives. The main physical and mechanical characteristics of cutting austenitic steels in the context of the impact of HPD together with MPA are presented: friction force, normal force, contact stress, contact pressure, contact length, coefficient of friction, angles of action and shear. It is shown that HPD with coolant reduces the cutting temperature by 30 - 50 ºC, and the components of the cutting forces by 30 – 50%. The effect of selected three main factors of the process on growth is studied. It is shown that the stress-strain state of the system "machined material - tool - chips" from the action of these factors approaches the specified state. That is, the intensity of growth decreases. The relationship between the main phenomena in the cutting of austenitic steels obtained in the study is presented. It is established that medium temperature tempering in a protective environment should be recommended to restore the initial performance properties of austenitic steels. The final finishing operation can be processing with an elastic tool made of superhard materials.

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37

Sokur, Mykola, Volodymyr Biletskyi, Mykhailo Fyk, Oleksandr Fyk, and Igor Zaselskiy. "The study of the lining layer abrasing wear in the semi-autogenous grinding mill." E3S Web of Conferences 166 (2020): 03008. http://dx.doi.org/10.1051/e3sconf/202016603008.

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In this work complex investigations of the abrasing wear of lining of self-grinding mills (semiautogenous grinding mills) are carried out with the obtaining of mathematical models of wear-abrasing of elevators in terms of height, weight, volume and worn-out area. In particular, according to the location and nature of the abrasing wear processes, the liner-lifters mill self-grinding are identified in three typical groups. During 1 year, in the conditions of Ingulets GOK, the monitoring of the abrasing wear of selected groups of lifters of self-grinding mills was performed. On the basis of the experimental data calculationed in the Microsoft Office Excel program, a set of mathematical models of lifter abrasing wear was obtained in terms of height, weight, volume and worn-out area. The obtained dependencies are recommended for prediction of abrasing wear of lining and necessary frequency of replacement of inserts-lifters. In addition, the research of wear of lining made of cast iron RF–4, showed a significant reduction in their abrasing wear compared with steel 110G13L. Thus, it has been shown that the selection of liner-lifters materials can reduce the inter–repair period by 3 times or more (replacement of worn-out lifters). A comparison of the actual picture of the abrasing wear of elevators and Simulation Statics simulated result (using SolidWorks) stresses shows the convergence of the arrangement of the zones of maximum stresses and the maximum abrasing wear of the lining. Investigation of the influence of the stressed state of lining plates on the intensity of their abrasing wear – a promising direction for further research.

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38

Ivanov, Yu F., A. V. Paul', S. F. Gnyusov, S. N. Kul'kov, and �. V. Kozlov. "Structural-phase analysis of sintered alloy WC-30% steel 110G13." Russian Physics Journal 36, no. 5 (May 1993): 497–500. http://dx.doi.org/10.1007/bf00560431.

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39

Zubenko, N. S., E. A. Tsvelik, and R. V. Pirozhkov. "Technology Optimization for Producing 110G13P Powder Steel by System Analysis Methods." Global Nuclear Safety 34, no. 1 (January 2020): 48–55. http://dx.doi.org/10.26583/gns-2020-01-05.

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40

Gnyusov, S. F., S. N. Kul'kov, A. V. Paul', Yu F. Ivanov, and �. V. Kozlov. "Study of the character of deformation of hard alloy WC-steel 110G13." Russian Physics Journal 37, no. 2 (February 1994): 130–36. http://dx.doi.org/10.1007/bf00559058.

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41

Paul', A. V., S. F. Gnyusov, Yu F. Ivanov, S. N. Kul'kov, and E. V. Kozlov. "Structural-phase changes in hard alloy WC-steel 110G13 after dynamic loading." Russian Physics Journal 37, no. 8 (August 1994): 757–61. http://dx.doi.org/10.1007/bf00559871.

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42

Kolokolov, Evgeny Ivanovich, Roman Vladimirovich Pirozhkov, and Sergey Alekseevich Tomilin. "APPLICABILITY OF 110G13P TYPE POWDER STEEL FOR PRODUCTION OF CONSOLIDATION DETAILS OF HIGH PARAMETERS POWER FITTINGS." V mire nauchnykh otkrytiy, no. 8 (November 24, 2014): 119. http://dx.doi.org/10.12731/wsd-2014-8-9.

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43

Ivanov, Yu F., and S. F. Gnyusov. "Modification of hard alloy WC-steel 110G13 by a pulsed low-energy, high-current electron beam." Russian Physics Journal 39, no. 8 (August 1996): 792–97. http://dx.doi.org/10.1007/bf02437091.

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44

Gnyusov, S. F., Yu F. Ivanov, D. I. Proskurovskii, and V. P. Rotshtein. "Bulk changes in the microhardness of a solid WC-110G13 steel alloy exposed to a low-energy, high-current electron beam." Technical Physics Letters 25, no. 10 (October 1999): 825–27. http://dx.doi.org/10.1134/1.1262649.

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45

"Nanodispersing Modification of 110G13L Steel." Химия в интересах устойчивого развития, no. 2 (2016). http://dx.doi.org/10.15372/khur20160210.

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46

Fadeev, Timur V., Mikhail V. Dorokhin, Iurii M. Kuznetsov, Lyudmila I. Kveglis, and Vladimir V. Shevchuk. "Steel 110G13L. Thermomagnetic and Galvanomagnetic Effects in its Films." Journal of Siberian Federal University. Mathematics & Physics, February 2021, 244–50. http://dx.doi.org/10.17516/1997-1397-2021-14-2-244-250.

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The article shows the ability to control magnetic properties due to modulation of phases in the film with varying temperature of growth. So, at low growth temperatures, a film is formed with an axis of easy magnetization in plane. An increase in temperature leads to a change in the phase composition of the film. It is shown that the presence of even a small component of the magnetization vector in the perpendicular direction leads to the appearance of a thermomagnetic effect of a large magnitude with respect to thermal noise

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47

"Effect of Explosion on the Mechanical Properties of 110G13L Steel." Физика горения и взрыва, no. 6 (2019). http://dx.doi.org/10.15372/fgv20190617.

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48

Zykova, A. P., S. N. Fedoseev, and D. V. Lychagin. "STEEL GX120MN12 MODIFYING BY ULTRADISPERSE POWDERS OF REFRACTORY METAL OXIDES." Spravochnik. Inzhenernyi zhurnal, 2014, 3–7. http://dx.doi.org/10.14489/hb.2014.09.pp.003-007.

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49

Kuskov, Yu M., I. L. Bogaychuk, N. P. Shevchenko, and M. A. Fesenko. "Electrocinder deposition with 110G13L steel chips at a current-supplying crystallizer." Welding International, July 12, 2021, 1–6. http://dx.doi.org/10.1080/09507116.2021.1945318.

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50

Kuskov, Yu M., I. L. Bogaychuk, N. P. Shevchenko, and M. A. Fesenko. "Electroslag surfacing of 110G13L steel using various types of surfacing materials." Welding International, July 14, 2021, 1–6. http://dx.doi.org/10.1080/09507116.2021.1945321.

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