Analysis of methods for modeling operating modes of compressor equipment that ensures the operation of field low-temperature separation units

• Published in: Vestnik Dagestanskogo gosudarstvennogo tehničeskogo universiteta. Tehničeskie nauki (Online) Vol. 50; no. 4; pp. 6 - 16
• Main Authors: Vorontsov, M. A., Glazunov, V. Yu, Grachev, A. S., Mashtalir, M. S., Pospelov, S. A., Chernyshev, A. V.
• Format: Journal Article
• Language: English; Russian
• Published: Dagestan State Technical University 21.01.2024
• Subjects: high-pressure centrifugal compressors; low-temperature separation units; modeling of centrifugal compressors; reduced characteristics method
• ISSN: 2073-6185; 2542-095X
• DOI: 10.21822/2073-6185-2023-50-4-6-16

Objective . A booster compressor station (BCS) is one of the key technological facilities necessary to ensure the effective operation of low-temperature separation technology for natural gas in field gas preparation systems for transportation. Ensuring promising operating modes of booster compressor stations with high efficiency is an urgent task. Method . One of the tools for solving this problem is mathematical modeling of the operating modes of centrifugal compressors (hereinafter - CPC), which are part of gas pumping units (GPU). The basis of the mathematical model is the gas dynamic characteristic (GDC) of the pulp and paper mill. The existing regulatory documentation presents simplified methods for modeling HDC, which are suitable for low-pressure pulp and paper mills with a pressure ratio of up to 1.5 and the number of compression stages of no more than three, but are not suitable for multi-stage high-pressure pulp and paper mills. Result . The results of a comparison of three methods of modeling the hydrodynamic characteristics (method of reduced characteristics, refined method of reduced characteristics, method of two-parameter approximation) of high-pressure pulp and paper mills are presented using the example of a pulp and paper mill with a pressure ratio of up to 2.0, intended for equipping a gas pumping unit as part of field booster compressor stations. An analysis and comparison of the obtained modeling results with actual data was carried out. Conclusion . When using the UMPH-2D modeling method, the smallest errors were obtained (no more than 2.0%), which, in turn, indicates its highest accuracy among the considered methods for recalculating the gas flow characteristics of high-pressure and multi-stage compressors.