Научные публикации | Oʻz FA "Fizika-Quyosh" IICHB Materialshunoslik instituti

№	Краткое описание научной разработки/достижения	Ссылка на документ
1.	Phase formation in ceramic materials that contain a cordierite glass synthesized by means of a large solar furnace	Applied Solar Energy 01/2013; 49(1). DOI:10.3103/S0003701X13010106
2.	Characteristics of phase formation in Angren deposit clays melted with a solar furnace	Applied Solar Energy 01/2014; 50(1):27-29. DOI:10.3103/S0003701X14010113 Renewable Energy Global Innovations {ISSN 2291-2460}, October 11, 2014
3.	Manufacture of Ceramic High-Porosity Cellular Materials Based on Raw Materials and Production Wastes in Uzbekistan	Glass and Ceramics 05/2015; 72(1-2):35-37. DOI:10.1007/s10717-015-9718-2, 0.38 Impact Factor
4.	Solar technologies in Uzbekistan: State, priorities, and perspectives of development	Applied Solar Energy 04/2012; 48(2). DOI:10.3103/S0003701X1202003X
5.	Synthesis of calcium aluminates on the big solar furnace	Applied Solar Energy 04/2012; 48(2). DOI:10.3103/S0003701X12020041
6.	Results of actinometric measurements at location of LSF with thermal capacity of 1000 kW	Applied Solar Energy 07/2012; 48(3). DOI:10.3103/S0003701X12030024
7.	A system with a tracking concentrating heliostat for lighting underground spaces with beams of sunlight	Applied Solar Energy 04/2014; 50(2):122-124. DOI:10.3103/S0003701X14020030
8.	The optimization of the optical-geometric characteristics of mirror concentrating systems	Applied Solar Energy 10/2015; 50(4):244-251. DOI:10.3103/S0003701X14040033
9.	Optical-geometric parameters of a linear Fresnel mirror with flat facets	Applied Solar Energy. Volume 50, Issue 3, pp. 168-170
10.	Adjustment Of Facets Of Flat And Focusing Heliostats, Concentrators, And Fresnel Mirror Concentrating Systems.	Applied Solar Energy. v.51.pp,151-155. ИМПАКТ-фактор 0.16-0.2 SJR
11.	The calculation procedure of the optical-energy characteristics of mirror concentrating systems for technological and energy application	Applied Solar Energy. Volume 51, Issue 4, pp 301-305. ИМПАКТ-фактор 0.16-0.2 SJR
12.	Creation Of Impulses Of Concentrated Solar Radiation Of Different Capacity And Duration	Applied Solar Energy. v.51. pp, 148-150. ИМПАКТ-фактор 0.16-0.2 SJR
13.	Antireflection textured coating for silicon solar cells	Applied Solar Energy, Volume 51, Issue 1, pp 83-84. ИМПАКТ-фактор 0.16-0.2 SJR
14.	The Properties of Pyroceramic Materials Syntheses by Concentrated Solar Energy	International Journal of Mining Science (IJMS) Volume 1, issue 2, pp.1-5. ИМПАКТ-фактор 0.868 SJR
15.	Особенности получения многофункциональной керамики на базе минерального сырья Узбекистана	Огнеупоры и техническая керамика №1-2, с.77-81. ИМПАКТ-фактор 0.25 SJR
16.	Отличительные особенности керамогранита и естественного гранита	Огнеупоры и техническая керамика. — № 3. — С. 35-37. ИМПАКТ-фактор 0.25 SJR
17.	Функциональная керамика, синтезированная в солнечной печи	Огнеупоры и техническая керамика. — № 3. — С. 42-47. ИМПАКТ-фактор 0.25 SJR
18.	Manufacture of Ceramic High-Porosity Cellular Materials Based on Raw Materials and Production Wastes in Uzbekistan	Glass and Ceramics. Volume 72(1-2). pp. 35-37. Impact Factor: 0.65.
19.	Basalt Fibers Obtained in a Solar Furnace	Glass and Ceramics. Volume 72, Issue 7, pp. 278-279. Impact Factor: 0.65. https://link.springer.com/journal/10717
20.	Solar technology for the synthesis and investigation of superconducting ceramics Bi1,7Pb0,3Sr2Ca(n-1)CunOy(n= 3÷5)	Refractories and Industrial Ceramics №1. pp 35-39. Impact Factor: 0.54
21.	Структурообразование в системе TiO2–BaСO3 в поле концентрированного солнечного излучения	Журнал Стекло и керамика. №3.ст.16-19. Impact Factor: 0.65
22.	Об изменении характеристик зонной структуры оксидных материалов при высоких температурах	Журнал «Теплофизика высоких температур», том 54, № 4, с. 1–7
23.	Analytical Approaches of Calculation of the Density Distribution of Radiant Flux from the Sun for Parabolic–Cylindrical Mirror-Concentrating Systems	Applied Solar Energy, Vol. 52, No. 2, pp. 137–140
24.	Method of Alignment of the Optical Axis of a Heliostat Tracking Sensor with the Main Optical Axis of the Concentrator	Applied Solar Energy, Vol. 52, No. 3, pp. 215–219. ИМПАКТ-фактор 0.25 SJR
25.	On ensuring the plasticity of molding composition in the manufacture of ceramic catalyst carriers	Refractories and Industrial Ceramics. pp 21-26. Impact Factor: 0.54
26.	Improving dielectric properties of piezoelectric ceramics of concentrated solar radiation flux	Refractories and Industrial Ceramics. pp 34-37. Impact Factor: 0.54
27.	Определение эффективности фильтрации пенокерамических фильтров на основе сырьевых материалов и отходов производства Узбекистана	«Стекло и керамика». №4. ст.30-32. Impact Factor: 0.65
28.	Получение мелкокристаллического иттрий-алюминиевого граната в солнечных печах	Новые огнеупоры. №3,144-147
29.	Preparation of finely crystalline yttrium-aluminum garnet in solar furnaces	Refractories and Industrial Ceramics. Vol.58, No.2, р.179-182. Impact Factor: 0.54
30.	Эффективность очистки жидкостей от механических примесей при использовании керамических мембран	Огнеупоры и техническая керамика. №3. стр.24-28
31.	Calculation of optical-geometrical characteristics of parabolic-cylindrical mirror concentrating systems	«European science review» # 1-2, pp.28-32. Impact Factor: 1
32.	Measurements of Solar Resources in Uzbekistan	Applied Solar Energy, Vol. 1, pp. 57-60. ИМПАКТ-фактор 0.25 SJR
33.	Глины Узбекистана как сырьевой материал для получения защитных покрытий на стальных поверхностях	“Огнеупоры и техническая керамика” — №1-2. — стр. 45-48. Impact Factor: 0.65
34.	Materials for Surface Protection of Heating Boiler Tubes	Glass and Ceramics. Volume 74, Issue 5–6, pp 172–175. Impact Factor: 0.65
35.	Химическая стойкость материалов на основе плавленого минерального сырья Узбекистана	Стекло и керамика. №7 — С.32-36. Impact Factor: 0.65
36.	Влияние термообработки на свойства жидкого стекла	Огнеупоры и техническая керамика. — №6 — С.44-50
37.	Обеспечение безопасности хранения серной кислоты	Computational nanotechnology, № 2. ст. 62-79 Impact Factor: 0.19
38.	Characteristic Features of the Energy Modes of a Large Solar Furnace with a Capacity of 1000 kW	Applied Solar Energy, 2018, Vol. 54, No. 2, pp. 99–109. ИМПАКТ-фактор 0.25 SJR
39.	Optical-energy characteristics of the optimal module of a solar composite parabolic-cylindrical installation	Applied Solar Energy, 2018, Vol. 54, No. 4 .pp.43-48
40.	Modeling and Calculation of Optical-Geometric Characteristics of a Solar Concentrator with Flat Fresnel Mirrors	Applied Solar Energy, 2018, Vol. 54, No. 3, pp. 187–192
41.	O features of synthesis of functional ceramics with a complex of the set properties by a radiation method. Part 3	Computational nanotechnology, 2-2018, 77-87. Impact Factor: 0.19
42.	Regressions models for forecasting of earthquakes	Computational nanotechnology, 2-2018, 43-46. Impact Factor: 0.19

Р.Ю. АКБАРОВ, М.С. ПАЙЗУЛЛАХАНОВ, ХАРАКТЕРНЫЕ ОСОБЕННОСТИ ЭНЕРГЕТИЧЕСКИХ РЕЖИМОВ БОЛЬШОЙ СОЛНЕЧНОЙ ПЕЧИ МОЩНОСТЬЮ 1000 кВт
R. AKBAROV, DOUBLE MIRROR HIGH-TEMPERATURE THOUSAND KW SOLAR FURNACE
HIGH-TEMPERATURE SUPERCONDUCTORS OF THE Bi1.7Pb0.3Sr2Ca (n – 1) CunOy (n = 2–20) SERIES SYNTHESIZED UNDER THE INFLUENCE OF CONCENTRATED SOLAR ENERGY
HIGHLY EFFECTIVE RESOURCE — SAVING TECHNOLOGIES OF WELDING MATERIALS FOR STRUCTURAL METALS AND ALLOYS
OPTIMIZATION OF TECHNOLOGY FOR CREATION OF COMPOSITE ANTIREFLECTION COATINGS FOR SILICON SOLAR CELLS
ANTIREFLECTIVE COATINGS FOR GLASS AND PLASTIC SUBSTRATES OF ORGANIC SOLAR CELLS

Если у Вас возникли вопросы, пожалуйста, оставьте сообщение.

Контакты