CONSTRUCTION OF A MATHEMATICAL MODEL OF THE10Е02 CONDENSER HEAT EXCHANGER FOR HEATING OIL AND GAS CONDENSATE RAW MATERIALS

Authors

  • Rakhimjanova Shakhnoza Saidanvarovna Tashkent Institute of Chemical Technology, Tashkent, Republic of Uzbekistan
  • Khudayberdiev Absalom Abdurasulovich Namangan Institute of Engineering and Technology, Namangan, Republic of Uzbekistan.
  • Sheralieva Ozoda Anvarovna Tashkent Institute of Chemical Technology, Tashkent, Republic of Uzbekistan
  • Akhmedov Mansur Eshmamatovich Tashkent Institute of Chemical Technology, Tashkent, Republic of Uzbekistan
  • Shamadinova Nargis Erkinovna Tashkent Institute of Chemical Technology, Tashkent, Republic of Uzbekistan
  • Atamuratova Malohat Shovkatovna Tashkent Institute of Chemical Technology, Tashkent, Republic of Uzbekistan

Keywords:

Optimization, modernization, shell-and-tube heat exchanger, condenser, energy efficiency, naphtha, fuel fraction, rectification, distillation.

Abstract

Ensuring energy efficiency and energy conservation is one of the most important factors for the successful implementation of the economic and social reforms being carried out in our country. The intensification of the problem associated with the constant increase in the cost of energy carriers leads to finding ways to reduce consumption costs and efficient use of energy resources. Finding the optimal modes of production and consumption of energy, organizing its accounting. When solving a set of technical measures to increase the efficiency of the atmospheric oil distillation unit of the Bukhara Oil Refinery, a system of mathematical equations has been developed. It allows determining the optimal technological cost of oil and gas condensate of raw materials, while reducing the existing heat transfer surface of heat exchange equipment in production and reducing the consumption of heat and electricity. Based on thermal, technical, and economic calculations, it is shown that the proposed method helps to reduce the consumption of energy costs.

References

Law of the Republic of Uzbekistan “On the rational use of energy” dated July 14, 2020 No. ZRU-628.

Babkin V.A. and others. Increasing energy efficiency in the process of atmospheric distillation of oil. Bulletin of the Tomsk Polytechnic University. Chemistry and chemical technologies. 2014. V.325. Number 3. pp. 56-63.

Kuznetsov N.V., Danovskaya O.A. Energy Efficiency and Energy Survey of Industrial Enterprises// International Journal of Experimental Education. 2012. №2. p.65-66.

Khudaiberdiev A.A. Intensification of the process of heating oil feedstock. Monograph. - Tashkent: Navroz, 2019, p.213.

Antipin A.A. Methods for optimizing heat exchange processes in the oil and gas industry / Innovative development of oil and gas industry, modern energy and their current problems. Proceedings of the international conference May 26, 2020.p.120.

Khudaiberdiev A.A., Rakhimzhanova Sh.S. Simulation of the statics of the process of heating the oil and gas condensate mixture during the condensation of naphtha vapor in a horizontal shell-and-tube apparatus. // Universum magazine: technical sciences. Moscow, 2022. No. 4(97). p.17-21.

Khudaiberdiev A.A., A. Artykov, Rakhimzhanova Sh.S., Shomansurov F.F. Optimization of the process of heating the oil and gas condensate mixture with naphtha vapor in the heat exchanger-condenser 10E-03 of the primary oil distillation unit // Universum magazine: technical sciences. Moscow, 2022. No. 4(97). p.10-17.

Khudayberdiev A.A., Rakhimjanova Sh.S. Technique for refined calculation of heat exchange during condensation of vapors of fractions of oil and gas condensate mixture in the shell and pipe apparatus //Scientific and technical journal of Namangan institute of engineering and technology/ Namangan, 2021/ -Vol.6 Issue ( 4) 2021. p.126-133.

Pavlov K.F., Romankov P.G., Noskov A.A. Examples and tasks in the course of processes and apparatuses of chemical technology. Textbook for universities / Ed. P.G. Romankov. 10th ed., revised. and additional L.: Chemistry, 1987. - 576 p.

Technological regulations for the installation of atmospheric distillation of a mixture of gas condensate and oil and fractionation of hydrotreated naphtha (installation 10) of the Bukhara Oil Refinery. TR 16472899-001: 2009.

Ziyatdinov N.N. et al. Optimization of the operating mode of the distillation unit of the installation, hydrotreatment of heavy coking gas oil in the environment of the modeling program Hysys. / Bulletin of the Technological University 2016. V.19, No. 22. P.112-115.

Нигматов, Х., & Турсунбаев, Б. Х. (2017). Методика расчета радиуса атома водорода и других элементов таблицы Менделеева. Инновации в науке, (8 (69)), 17-19.

Kh, N. To a technique of maintenance of information safety in networks and systems of telecommunication. Tretya Mejdunarodnaya sentralno-Aziatskaya konferensiya. Na angl. yazike ICI-2007 i ITRA-2007 g. Parij.

Нигматов, Х., Турсунбаев, Б. Х., & Турсунбаев, Т. Б. (2020). НОВАЯ ИНТЕРПРЕТАЦИЯ РЕЗУЛЬТАТОВ ЭКСПЕРИМЕНТА ПО ВИЗУАЛИЗАЦИЮ СТРУКТУРЫ АТОМА ВОДОРОДА. Евразийский союз ученых, (7-2), 64-68.

Nigmatov, X. (1984). dr. The structure of propositions and current issues syntax of Turkic languages (Thesis of formal-functional research). Soviet Turkology, 5, 5-10.

Nigmatov, K., & Umarov, U. (2020). Analytical simulation methods determining the basic characteristics of a telecommunication network with different communication channels and a changing structure. Bulletin of TUIT: Management and Communication Technologies, 4(3), 3.

Nigmatov, K., & Umarov, U. (2020). Opredelenie osnovnsrx xarakteristik telekommunikatsionnoy seti s raznotipnimi kanalami svyazi i izmenyayusheesya strukturoy. Muhammad al-Xorazmiy avlodlari, 2(12), 78-82.

Nigmatov, K., & Umarov, U. (2018). Vibor kriteriya effektivnosti pri zashite informatsii v setyax telekommunikatsii. Materiali XXIII mejdunarodnoy nauchno-texnicheskoy konferensii, 18-19.

Рахимов, Т. Г., Соколов, В. К., & Нигматов, Х. Н. (1997). Определение оптимального соотношения между накоплением и потреблением в условиях рынка.«. Проблемы информатики и энергетики».,(1).

Рахимов, Т. Г., Соколов, В. К., Нигматов, Х., & Махмудов, М. М. (1997). Математические основы формирования идеальной шкалы тарифов на услуги телефонной связи.«. Проблемы информатики и энергетики».,(3).

Nigmatov, H., & Tursunbaev, B. H. Metodika rascheta radiusa atoma vodoroda i drugih jelementov Tablicy Mendeleeva. Innovacii v nauke: nauchnyj zhurnal, (8), 69.

Рахимов, Т. Г., Соколов, В. К., Нигматов, Х. Н., & Махмудов, М. М. (1997). О семантическом единстве экономических понятий предельного продукта и предельной ресурсе-или фондоотдачи. Проблемы информатики и энергетики., (5).

Agzamovich, U. U., & Hikmatulla, N. (2021, November). Exchange of messages in the telecommunication network with different types of communication channels. In 2021 International Conference on Information Science and Communications Technologies (ICISCT) (pp. 1-4). IEEE.

Downloads

Published

2025-11-30

How to Cite

Rakhimjanova Shakhnoza Saidanvarovna, Khudayberdiev Absalom Abdurasulovich, Sheralieva Ozoda Anvarovna, Akhmedov Mansur Eshmamatovich, Shamadinova Nargis Erkinovna, & Atamuratova Malohat Shovkatovna. (2025). CONSTRUCTION OF A MATHEMATICAL MODEL OF THE10Е02 CONDENSER HEAT EXCHANGER FOR HEATING OIL AND GAS CONDENSATE RAW MATERIALS . INTERNATIONAL JOURNAL OF SOCIAL SCIENCE & INTERDISCIPLINARY RESEARCH ISSN: 2277-3630 Impact Factor: 8.036, 14(11), 102–109. Retrieved from https://www.gejournal.net/index.php/IJSSIR/article/view/2777

Issue

Vol. 14 No. 11 (2025): INTERNATIONAL JOURNAL OF SOCIAL SCIENCE & INTERDISCIPLINARY RESEARCH

Section

Articles

License

Copyright (c) 2025 GEJournals

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Creative Commons Attribution- 3.0 Unported License.