Compressor stations ensure the movement of gas through the main gas pipeline. The compressor station increases the gas pressure by compressing it. Since the wellhead pressure always drops at the fields during the extraction of raw materials, there is an irregularity in energy consumption, therefore, there is a need for compressor stations. For that, the study of its design parameters is important task. The aim of the research is to study and analyze methods compressor parameter calculation. The initial stage of designing industrial facilities is a Preliminary Front and Engineering Design (Pre-FEED). It is at the Pre-FEED stage that the economic efficiency, analysis and calculation of the technical and economic indicators of the investment project are studied. It is not difficult to understand that the Pre-FEED decides the further "life" of the project. Therefore, in our work, we studied the process of selecting equipment and calculating its parameters, which are determined at the Pre-FEED. In the course of the research, the types of a natural gas blower, the types of its drive, as well as their area of application have been studied. It is concluded that the centrifugal compressor has a wide range of applications for increasing natural gas pressure. The empirical method has been used in the calculation, as well as the method using the technological method modeling tool. As a result, the power and discharge temperature of the centrifugal compressor have been determined in three ways and analyzed, the methods used have also been compared. When choosing calculation methods, we studied the experience of using existing methods, and also conducted experiments with the technological process from the point of view of fundamental science. Firstly, we considered the experience of calculating the power and discharge temperature according to the requirements of the production organization, then with the use of a software product, and at the end we approached from the side of the fundamental science laws. The results of each approach to the problem did not differ much from each other, but the characteristics of each method influenced the output result. We came to the conclusion that the use of a simulator makes it easier to solve problems, and also gives more detailed results. The possibilities of modeling Aspen HYSYS tools for technological processes in the oil and gas industry have been studied. The capability of Aspen HYSYS to work as a tool for determining the parameters of equipment is shown. The use of Aspen HYSYS makes it possible to solve one of the most important current issues - optimization.
| № | Имя автора | Должность | Наименование организации |
|---|---|---|---|
| 1 | Khabibullaev S.S. | Dotsent | TDTU |
| 2 | Saparaliyeva A.L. | O'qituvchi | TDTU |
| 3 | Jang H.T. | O'qituvchi | Hanseo University Chemical engineering department South Korea |
| № | Название ссылки |
|---|---|
| 1 | 1. Available from: https://neftegaz.ru/tech-library/economy/148251-tekhniko-ekonomicheskoe-obosnovanie-teo/minenergy_uz |
| 2 | 2. U.S. EPA Office of Air Quality Planning and Standards (OAQPS). Oil and gas sector natural gas compressors. - Review Panel, 2014. – 47 p. |
| 3 | 3. G.Dissinger, M. Blanchard. Compressor modeling using Aspen HYSYS Dynamics. - Aspen Technology, Inc. 2013. |
| 4 | 4. A.K. Mikhaylov, V.P. Voroshilov. Compressor machines, textbook, M. Energoatomizdat 1989. – 288 p (in Russian). |
| 5 | 5. STO Gasprom 2-3.5-051-2006 (in Russian). |
| 6 | 6. O.A. Kuznetsov. Getting started in Aspen Hysys. – M-Berlin. Direct-Media, 2015. – 68 p (in Russian). |
| 7 | 7. L.V. Shishmina, O.V Nosova. Technological modeling of processes and devices for gathering and preparation of oil and gas wells products in the environment of the hysys modeling program. Tomsk Polytechnic University Publishing House 2015 (in Russian). |
| 8 | 8. Julie Levine, Glenn Dissinger. Jump Start: Aspen HYSYS®Dynamics V8. |
| 9 | 9. Aspen HYSYS. Getting Started in Aspen HYSYS: A Quick Tutorial. |
| 10 | 10. A.I. Saparalieva, S.Sh. Khabibullaev. Application of Aspen HYSYS software in the design of a compressor shop. Materials of the republican scientific and technical conference "Innovative developments in the field of science, education and production - the basis for the investment attractiveness of the oil and gas industry", 2020 (in Russian). |
| 11 | 11. Danesh A. PVT and Phase Behavior of Petroleum Reservoir Fluids. Elsevier, 1998. pp. 210-212. |
| 12 | 12. Riazi M.R. Characterization and Properties of Petroleum Fractions. ASTM. 2005. pp. 88-89. |
| 13 | 13. A.I. Brusilovsky. Phase transformations in oil and gas development. -M: The Grail. 2002.- 575 p (in Russian). |
| 14 | 14. The Properties of Gases and Liquids, 3rd Edition, R.C. Reid, J.M. Prausnitz, T.K. Sherwood, McGraw Hill Book Company (1981). |
| 15 | 15. Gas industry. Science Magazine. №7, 2018 (in Russian). |
| 16 | 16. A.I. Brusilovsky. Theoretical foundations of phase transformations of hydrocarbon mixtures: Textbook. 2010 - 92 p (in Russian). |
| 17 | 17. I.T. Mishchenko. Calculations for oil and gas production. Moscow: publishing house "Oil and Gas" Russian State University of Oil and Gas named after I.M. Gubkin, 2008.- 296 p (in Russian). |
| 18 | 18. B.C. Rice. Centrifugal compressor machines. M.: Mashgiz, 1964 (in Russian). |
| 19 | 19. G.K. Khrapach. Operation of compressor installations. M.: Nedra, 1972. |