42

  • Internet havola
  • DOI
  • UzSCI tizimida yaratilgan sana 16-09-2024
  • O'qishlar soni 42
  • Nashr sanasi 28-12-2023
  • Asosiy tilRus
  • Sahifalar51-57
Kalit so'z
Ўзбек

Растущие потребности в энергии удовлетворяются главным образом за
счет использования ископаемого топлива, что увеличивает энергетическую нагрузку на
природу. Эту проблему можно решить путем обеспечения экологической и энергетической
безопасности и ресурсосбережения. Ведущая роль в реализации этих процессов принадлежит
нетрадиционной возобновляемой энергетике, при этом особое значение приобретают
переработка промышленных отходов и производство альтернативной энергии. В том числе
отходы масложировых заводов.

Havola nomi
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2 Беляев Н.М., Кисель А.А. Новые способы и потенциальные возможности применения отходов производства пищевой продукции. Сборник статей Всероссийской научно- практической конференции «Региональные проблемы геологии, географии, техносферной и экологической безопасности». Екатеринбург, 2019, с. 162-166.
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4 Juping Liu, Xu Chen, Wei Chen, Mingwei Xia, Yingquan Chen, Hanping Chen, Kuo Zeng, Haiping Yang. Biomass pyrolysis mechanism for carbon-based high-value products. https://doi.org/10.1016/j.proci.2022.09.063.
5 Mamta Devi, Sachin Rawat, Swati Sharma. A comprehensive review of the pyrolysis process: from carbon nanomaterial synthesis to waste treatment. Oxford Open Materials Science, Volume 1, Issue 1, 2021, itab014, https://doi.org/10.1093/oxfmat/itab014 .
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8 Pyrolysis of cotton seed and characterization of the liquid product. A Thesis submitted in partial fulfillment of the requirements for the Degree of BACHELOR OF TECHNOLOGY. Submitted by Suprabhat Seal, Supervisor: Dr. R.K Singh, Department of Chemical Engineering National Institute of Technology, ROURKELA, 2013, oai:generic.eprints.org:5344/core1451.
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11 Kodirov D., Tursunov O., Ahmedov A., Khakimov R., Rakhmataliev M. Economic efficiency in the use of solar energy: A case study of Agriculture in Uzbekistan, IOP Conf. Ser.: Earth Environ. Sci. 614, 012031 (2020).
12 Uzakov G.N., Efficiency of joint operation of greenhouses and solar greenhouses, Applied Solar Energy 46(4), 319–320 (2010).
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15 Zeaiter J., Ahmad M.N., Rooney D., Samneh B., Shammas E.. Design of an automated solar concentrator for the pyrolysis of scrap rubber. Energy Convers. Manag. 101, 118-125 (2015).
16 Uzakov G.N., Davlonov H.A., Holikov K.N., Study of the Influence of the Source Biomass Moisture Content on Pyrolysis Parameters, Applied Solar Energy 54, 481 - 484 (2018).
17 Almardanov X.A., Khatamov I.A., Turaev Z.B., Yusupov R.E., Application of solar concentrators to obtain alternative fuel through a heliopyrolysis device, Universum: Technical Sciences 8-12 (2021)
18 Davlonov X.A., Almardanov X.A., Khatamov I.A., A program for modeling and calculating the exergic balance of a heliopyrolysis device to obtain alternative fuels from biomass (DGU 10337, Tashkent, 2021).
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