Your search keyword '"A.D. Badikova"' showing total 14 results

1. Producing a siliceous ferroalloy from a mixture of amorphous rocks

Author

V.M. Shevko, N.M. Mirkayev, D.K. Aitkulov, and A.D. Badikova

Subjects

Tripoli, Diatomite, Opoka, Electric smelting, Planning of experiments, Optimization, Technology

Abstract

The main silicon-containing component in a charge during ferrosilicon smelting is quartzite. The carbothermic reduction rate of the crystalline structure SiO2 has a limitation associated with a fixed energy reserve of silicon-oxygen bond. The reactive capacity of silica can be increased by using its amorphous form instead of the crystalline SiO2. The amorphous form of silica has a higher dispersion, greater free surface energy, and, consequently, a more active degree of entering into a reaction. Such silica-containing materials include amorphous rocks: diatomite, opoka, tripoli. The article presents the results of experimental studies of electrothermal ferrosilicon production from a mixture of amorphous rocks (tripoli, opoka, diatomite with a mass ratio of 1:1:1).It is established that when smelting the mixture of amorphous rocks containing 77 % SiO2, 7.9 % Al2O3, 5.2 % Σ CaO and MgO, 4 % Σ K2O Na2O, 3.3 % Fe2O3, 1.3 % CaCO3, 0.9 % CaSO4, 0.4 % others, three ferrosilicon grades are formed: FeSi25 (22–29 % Si), FeSi45 (41–47 % Si), FeSi50 (47–52 % Si) with the extraction degree of 70–87.6 % silicon into the alloy. Moreover, the ferrosilicon grade decreases with an increase in steel shavings in the charge from 21.9-31.4 % to 33–35 %. In comparison with ferrosilicon smelting from a standard charge containing quartzite with the crystalline form of SiO2, steel shavings and coke, ferrosilicon production from the mixture of amorphous rocks allows to increase the process rate by 17.5–21.6 %. It is possible to increase the silicon extraction degree into the alloy from 80-85 %–94.5 % if its final stage is carried out in the resistance mode. Widespread occurrence in nature, favorable conditions of occurrence, low cost, high reactive capacity are favorable factors for using amorphous rocks in the production of ferroalloys.

Published

2024

2. Effective mineral additive on the basis of wastes of petrochemical plants for a concrete structural mix

Author

A.D. Badikova, S.R. Sakhibgareev, R.A. Fedina, M.N. Rakhimov, and M.A. Tsadkin

Subjects

concrete structural mix, active mineral additive, sulfur-alkaline effluents of petrochemical plants, waste soda, Building construction, TH1-9745

Abstract

The use of concrete in building allows obtaining reliable and long-lasting operation of buildings, but such conditions require concrete with specified characteristics. Today hardly one can produce a concrete structural mix of high quality without any additives. To control actively the structure and properties of a concrete mix and concrete, along with chemical additives, mineral additives are used. The mineral additives are the powders of various mineral nature, obtained from natural or man-made raw materials: ground slag, rocks, etc. The article introduces the method of obtaining a mineral additive for a structural mix, in particularly for concrete. Qualitative characteristics of the additive obtained were studied as follows: the index of the degree of grinding to be equal to 1, standard consistency (normal density) – (180±5) mm with a mass ratio of «additive: water») – 100: 70, setting time – beginning 20 min, water absorption 0.27%, water content 9.65%, the proportion of insoluble residue in hydrochloric acid solution is 1.70%. Implementation of the additive in the concrete composition has shown that the quality of the product does not fall, and the actual strength is 250.7 kgf/cm2, which is slightly higher than the strength of the concrete sample without an additive. It was determined that the quality of concrete products with a mineral additive corresponds to GOST as follows: density 1775 kg/m3; mass humidity 0.3%; volume humidity 0.5%. The introduction of a structural mix will significantly improve the properties of a concrete structural mix and will also reduce the fuel resources consumption for production of the concrete structural mix, products and constructions of its basis.

Published

2020

3. THERMODYNAMIC AND EXPERIMENTAL RESEARCH OF EFFECTS OF TEMPERATURE AND PRESSURE ON THE PRODUCTION OF SILICON ALLOY, CALCIUM CARBIDE, AND PHOSPHORUS FROM CHILISAY PHOSPHORITES

Author

V.M. Shevko, A.D. Badikova, M.A. Tuleev, G.E. Karataeva, and R.A. Uteeva

Subjects

General Medicine

Published

2022

4. Ferroalloy production from ferrosilicon manganese dusts

Author

M.A. Tuleyev, V.M. Shevko, A.D. Badikova, and D.K. Aitkulov

Subjects

Ferrosilicon, Materials science, chemistry, Metallurgy, Ferroalloy, chemistry.chemical_element, Manganese

Abstract

The article presents the results of studies on the influence of time, the amount of steel shavings and coke on the electric melting of ferrosilicon manganese dusts to obtain a ferroalloy. The research was carried out by the method of rotational planning of the second order (Box-Hunter plans) and by electric smelting of dust in laboratory ore-thermal arc furnace. Dust from the production of ferromanganese by LLP Taraz Metallurgical Plant, coke and steel shavings were used during the research. It was determined that to achieve αSi≥70%the process must be carried out in the presence of 25% coke and 8.1-9% steel shavings from the mass of dust for 55.8-60 minutes, to achieve αMn in an alloy of 80-85% the process must be carried out in the presence of 25% coke, 5.7-9.0% steel shavings for 41.2-54.4 minutes. When melting the charge containing 75.2% of dust, 18.8% of coke, 6% of steel shavings, within 60 minutes the weight of the ferroalloy was 258 g (38.8% of the weight of the charge or 51.6% of the weight of dust). The degree of extraction of manganese into the alloy was 82.3%, silicon - 66.1%. The resulting ferroalloy belongs to ferrosilicon manganese of the FeMnSi12 grade.

Published

2021

5. THEORY AND TECHNOLOGY OF MANUFACTURING A FERROALLOY FROM CARBON FERROCHROME DUSTS

Author

A.D. Badikova, V.M. Shevko, Timur Ibrayev, Gul'nara Karatayeva, and Yevgeniy Afimin

Subjects

Materials science, Silicon, Ferrochrome, Metallurgy, Alloy, Metals and Alloys, chemistry.chemical_element, Ferroalloy, Coke, engineering.material, Chromium, chemistry, engineering, Carbon, Electric arc furnace

Abstract

The article contains the research results of obtaining a ferroalloy from a carbon ferrochrome dust containing 30,2% of Сr2O3, 23.4% of SiO2, 32.7% of MgO, 5.0% of FeO, 1.6% of CaO, 4.5%of Al2O3, 2.3%of C, and 0.3 %-others. The studies were carried out by a thermodynamic modeling method using the HSC-5.1 software package (Outokumpy) based on the principle of the Gibbs energy minimum, the Box-Hunter rototable planning technique and electric melting of the dust in an arc furnace. It was found that the interaction of the dust with carbon under equilibrium conditions and in the presence of iron leads to formation of Cr4C(T>10000C),Cr3C2, Cr7C3,Cr (T>11000C), FeSi (T>13000C), SiC (T>14000C), SiOg and Si(T>15000C). In the temperature range of 1745-19000C and in the presence of 18-34% of carbon and 8% of iron of the dust mass, the resulting ferroalloy contained 18.5-25.2% of Si and 46.8-49.4% of Cr (in this case the silicon extraction degree into the alloy was 60.0-64.4%, the chromium one–99.8%). When the electrosmelting the granulated dust together with coke and steel shavings, the chromium extraction degree into the alloy was 98-99%, the silicon one–53-57%; the obtained ferroalloys containing 18.3-21.9% of silicon and 45.6-53.6%of chromium meet the requirements to FeCrSi23-grade ferrosilicochromium.

Published

2021

6. Obtaining of ferrosilicon from technogenic magnetite concentrate

Author

D.D. Amanov, P. V. Kaskin, A.D. Badikova, and V.M. Shevko

Subjects

chemistry.chemical_compound, Materials science, Ferrosilicon, chemistry, Metallurgy, Magnetite

Abstract

The article presents the results of studies on the production of ferrosilicon from iron ore (magnetite) concentrate and quartzite. The studies were carried out by thermodynamic simulation using the HSC-5.1 software package, based on the principle of Gibbs minimum energy and electric smelting of the concentrate together with coke and quartzite in a single-electrode arc furnace. Based on the studies, it was found that, under equilibrium conditions, the interaction of magnetite concentrate with silicon oxide (IV) and carbon is accompanied by the formation of FeSi (> 1200 0C), Fe3Si (> 1100 0C), FeSi2 (> 500 0C), Zng (> 800 0C) Pbg (> 1200 0C); the degree of silicon extraction into the ferroalloy depends on the ratio in the SiO2 / Fe3O4 mixture, decreasing from 85.6 to 66.1 (for example, at 17000С) with an increase in the SiO2 / Fe3O4 ratio from 0.42 to 1.25. When melting a mixture containing 70% concentrate, 11% quartzite, 19% coke, a ferroalloy containing 15-18% Si. The resulting ferroalloys are graded from FeSi15 to FeSi45.

Published

2020

7. Spectral methods of analysis capabilities for investigation of the composition of oil sludges

Author

R.U. Muhamadeev, I.G. Ibragimov, A.D. Badikova, A.V. Rullo, R.N. Shiryaeva, and A.G. Mustafin

Subjects

Geophysics, Fuel Technology, Chemistry (miscellaneous), Applied Mathematics, Chemical Engineering (miscellaneous), Energy Engineering and Power Technology, Environmental science, Mineralogy, Geology, Composition (visual arts), Geotechnical Engineering and Engineering Geology, Spectral method

Published

2019

8. PRODUCTION OF FERROALLOYS AND CALCIUM CARBIDE FROM THE BASALT OF THE DUBERSAY DEPOSIT

Author

A.D. Badikova, Boris A. Lavrov, V.M. Shevko, and G. E. Karataeva

Subjects

Basalt, chemistry.chemical_compound, Materials science, chemistry, Calcium carbide, Metallurgy, Ferroalloy, General Medicine

Published

2019

9. THERMODYNAMIC OPTIMIZATION OF FERROSILICON PRODUCTION FROM DIATOMITE

Author

Dmitry Malykhin, V.M. Shevko, and A.D. Badikova

Subjects

Materials science, Ferrosilicon, Metallurgy, Production (economics)

Published

2020

10. Thermodynamic model of the influence of temperature and carbon on the production of ferroalloy and calcium carbide from the basalt of Dubersay deposit

Author

D.D. Amanov, G. E. Karataeva, A.D. Badikova, V.M. Shevko, and Mustafa Azatovich Tuleev

Subjects

Thermodynamic model, Basalt, chemistry.chemical_compound, Materials science, chemistry, Calcium carbide, Metallurgy, Ferroalloy, chemistry.chemical_element, Carbon

Abstract

The article covers the results of researches on thermodynamic modeling of ferroalloy and calcium carbide obtaining from basalts of deposit Dubersay. The software package HSC-5.1, based on the principle of Gibbs energy minimum uses in the study. The influence of temperature (from 500 to 2500 °C) and the amount of carbon (from 40 to 60 % of the basalt mass) in the basalt–Fe–nC system was determined. It has been established that iron silicides are formed at T ≥ 1300 °C, Si at T ≥ 1400 °C, CaSi and Al at T> 1700 °C and CaC2 – at T ≥ 1800 °C. An increase of the amount of carbon from 40 to 60 % allows rise the degree of distribution of Si in the alloy up to 94 %, calcium in CaCl2 – up to 62.3 %, aluminum – to alloy up to 93.9 %. An increase of the amount of carbon allows increase the silicon concentration in alloy up to 55 % (at 1800 °C), aluminum – up to 17 % (at 2000 °C) and calcium carbide capacity – up to 350 dm3/kg. The method of rototable planning of the second order allows find equations of regressions of the influence of temperature and amount of carbon on the equilibrium distribution of silicon, aluminum, and calcium between the ferroalloy and calcium carbide. On the basis of this equations were determined, that within the temperature range 1956-1996 °C from the Dubersay deposit basalt, the ferroalloy with a content of ΣSi and Al 60.8-65.4 % (including 12- 15 % Si) and calcium carbide with a capacity of 250-300 dm3/kg are formed. Wherein degree of recovery into the alloy for silicon is 91-91.4 % and for aluminum is 63-75.1 % and calcium – into CaC2 is 60-60.7 %. The resulting ferroalloy by the content of silicon and aluminum can be attributed to the complex ferroalloy – ferrosilicoaluminium, calcium carbide – to the industrial product of grade from 3 and up to the highest.

Published

2018

11. A Ferro-alloy, Calcium Carbide and Zinc Sublimates, Production from the Achisay Deposit Ore (Complex tests)

Author

D.D. Amanov, A.D. Badikova, G. E. Karataeva, V.M. Shevko, and Mustafa Azatovich Tuleev

Subjects

Calcium carbide, Metallurgy, Alloy, Ornamental horticulture, chemistry.chemical_element, Industrial chemistry, General Chemistry, Zinc, engineering.material, Biochemistry, Elsevier Biobase, chemistry.chemical_compound, chemistry, Drug Discovery, engineering, Environmental Chemistry, Material chemistry

Published

2018

12. INVESTIGATION OF AN ALUMINOTHERMIC SILICON SEPARATION FROM A CORUNDUM MATRIX

Author

B. A. Lavrov, A.D. Badikova, D.D. Amanov, V.M. Shevko, and G. E. Karataeva

Subjects

Materials science, Silicon, General Chemical Engineering, chemistry.chemical_element, Corundum, General Chemistry, engineering.material, Biochemistry, Matrix (mathematics), General Energy, chemistry, engineering, General Pharmacology, Toxicology and Pharmaceutics, Composite material

Published

2018

13. JET TURBINE CONTACTOR OF THE NEW TYPE FOR THE SULPHURIC ACID ALKYLATION BY OLEFINS

Author

M.A. Tsadkin and A.D. Badikova

Subjects

Pulmonary and Respiratory Medicine, law, Chemistry, Pediatrics, Perinatology and Child Health, Inorganic chemistry, Alkylation, Jet engine, law.invention, Contactor

Published

2016

14. Modification of sodium lignosulfonate with reagent obtaining for drilling fluids

Author

D.A. Dubovtsev, R.A. Fedina, A.D. Badikova, I.N. Kulyashova, and M.A. Tsadkin

Subjects

chemistry.chemical_compound, chemistry, Chemical engineering, Sodium lignosulfonate, Drilling fluid, Reagent