21 феврал 2023
2КОНЦЕНТРАЦИЯЛАНГАН ҚУЁШ НУРЛАНИШИ ОҚИМИ ТАЪСИРИДА ЭРИТИШ ОРҚАЛИ МЕТАЛЛУРГИЯ ТЕХНОГЕН ЧИҚИНДИЛАРИ ТАРКИБИДАН МЕТАЛЛ ҚОТИШМАЛАРИНИ АЖРАТИБ ОЛИШ ЖИҲАТЛАРИ
65d877553f90f.pdf
MAQOLA ANNOTATSIYASI
MUALIFLAR
Teglar
Maqolani baholang
0
Maqola idintifikatorlari
DOI:
Mavjud emas
Foydalanilgan adabiyotlar
Herranz G., Rodríguez G.P. Uses of concentrated solar energy in materials science. Source: Solar Energy. Ed. R.D. Rugescu. Croatia, INTECH, 2010, February, p. 432. Available at: http://www.sciyo. com/.
Fernández-González D., Ruiz-Bustinza I., González-Gasca C.; Piñuela-Noval J. Concentrated solar energy applications in materials science and metallurgy. Solar Energy, 2018, August, vol. 170, pp. 520– 540.
Sorensen. Renewable energy. Physics, Engineering, Environmental Impacts, Economics and Planning. Elsevier, 2017, p. 1030.
Fernández-González D., Prazuch J., Ruiz-Bustinza I., González-Gasca C., Piñuela-Noval J. Iron metallurgy via concentrated solar energy. Solar Energy, 2018, vol. 171, pp. 658–666.
Ruiz-Bustinza I., Cañadas I., Rodríguez J., Mochón J., Verdeja L.F., García-Carcedo F. magnetite production from steel wastes with concentrated solar energy. Steel Res. Int., 2013, vol. 84, pp. 207–217.
Sibieude F.M., Tofighi A., Ambriz J. High temperature experiments with a solar furnace: The decomposition of Fe3 O4 , Mn3 O4 , CdO. Int. J. Hydrogen Energy, 1982, no. 7, pp. 79–88.
Steinfeld A., Fletcher E.A. Theoretical and experimental investigation of the carbothermic reduction of Fe2 O3 using solar energy. Energy, 1991, no. 16, pp. 1011–1019.
Akbarov R.Y., Paizullakhanov M.S. Characteristic features of the energy modes of a large solar furnace with a capacity of 1000 kW. Applied Solar Energy, 2017, vol. 54 (2), pp. 99–109.
Faiziev S.A, Paizullakhanov M.S., Nodirmatov E.Z. Synthesis of pyroxene pyroceramics in large solar furnace with ZrO2 crystallization nucleator. Applied Solar Energy, 2008, vol.44, iss. 2, pp.139–141.
Puig J., Balat-Pichelin M., Magn J. Experimental carbothermal reduction of Mg at low pressure using consentrated solar energy. Min. Metall. Sect. B-Metall., 2018, vol. 54 (1), pp. 39–50.
Puig J., Balat-Pichelin M. Production of metallic nanopowders (Mg, Al) by solar carbothermal reduction of their oxides at low pressure. Journal of Magnesium and Alloys, 2016, no. 4, pp. 140–150.
Murray J.P. Aluminium production using high-temperature solar process heat. Solar Energy, 1999, vol. 66 (2), pp. 133–142.
Pardo N., Moya J.A. Prospective scenarios on energy efficiency and CO2 emissions in the European iron & steel industry. Energy, 2013, no. 54, pp. 113–128.
Wang, K., Wang C., Lu X., Chen J. Scenario analysis on CO2 emissions reduction potential in China’s iron and steel industry. Energy Policy, 2007, no. 35, pp. 2320–2335.
Parpiev O.R., Paizullahanov M.S., Nodirmatov E.Z. Peculiarities of processing metallurgical waste in a large solar furnace. Theory and Technology of the Metallurgical Process, 2021, vol. 36, no. 1, pp. 15–20.
Paizullakhanov M.S., Shermatov Z.Z., Nodirmatov E.Z. Sinthesis of materials by concentrated solar radiation. High Temperature Material Processes, 2021, vol. 25, no. 2, pp. 25–34.
Khmelev V.N. et al. Ulʹtrazvukovyye mnogofunktsionalʹnyye i spetsializirovannyye apparaty dlya intensifikatsii tekhnologicheskikh protsessov v promyshlennosti [Ultrasonic multifunctional and specialized devices for the intensification of technological processes in industry]. Barnaul, Altai State Technical University, 2007, 416 p.