Mathematical simulation of complex gas transportation systems with underground gas storage

Authors

  • Володимир Ярославович Грудз Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016, Ukraine
  • Ярослава Василівна Костів Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016, Ukraine
  • Василь Романович Процюк Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016, Ukraine
  • Дмитро Федорович Тимків Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016, Ukraine

DOI:

https://doi.org/10.15587/2313-8416.2016.67695

Keywords:

flow capacity, method of equivalent diameter, hydraulic efficiency, compressor station, mathematical model

Abstract

In this paper the authors explore the problem of calculation of the complex gas transportation system, which includes a number of pipelines that form linear part and a number of compressor stations, which together represent segments connected in series and parallel, and the characteristics of which affect the value of the flow capacity. The method of equivalent diameter of the gas transportation system of any complexity was proposed

Author Biographies

Володимир Ярославович Грудз, Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016

Doctor of of Engineering Sciences, Professor

Department of construction and repair of gas and petroleum and gas oil storage

Василь Романович Процюк, Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016

PhD, Asociate professor

Department of Informatics

Дмитро Федорович Тимків, Ivano-Frankivsk National Technical University Oil and Gas 15 Carpathian str., Ivano-Frankivsk, Ukraine, 76016

Doctor of of Engineering Sciences, Professor

Department of Informatics

References

Kovalko, M. P., Grudz, V. Ja., Myhalkiv, V. B. et. al (2002). Truboprovidnyj transport gazu. Kyiv: ArenaEKO, 600.

Jakovlev, E. I., Kazak, O. S., Myhajlkiv, V. B., Tymkiv, D. F., Grudz, V. Ja. (1993). Rezhymy gazotransportnyh system. Lviv: Svit, 170.

Bobrovskij, S. A., Shherbakov, S. G., Jakovlev, E. I. et. al (1976). Truboprovodnyj transport gaza. Moscow: Nauka, 491.

Grudzv, Ja., Grudz, Ja. V., Slobodjan, V. I. (2009). Harakterystyka rezhymiv roboty kompresornyh stancij magistral'nogo gazoprovodu. Rozvidka i rozrobka gazovyh rodovyshh, 2.

Jakovlev, E. I., Kazak, A. S., Mihalkiv, V. B. et. al (1984). Metodika rasscheta slozhnyh gazotransportnyh sistem s peresechennym profilem trassy. Kyiv: Sojuzproekt, 112.

Grudz, V. Ja., Grudz, Ja. V., Slobodjan, V. I., Dacjuk, A. V. (2010). Doslidzhennja energetychnogo stanu skladnyh gazotransportnyh system. Shljahy pidvyshhennja efektyvnosti ekspluatacii' truboprovidnogo transportu nafty i gazu ta pidgotovka kadriv galuzi. Ivano-Frankivs'k, 9–12.

Grudz, V. Ja., Tymkiv, D. F., Myhalkiv, V. B., Kostiv, V. V. (2009). Obslugovuvannja i remont gazoprovodiv. Ivano – Frankivs'k: Lileja – NV, 711.

Ronald, C. (1976). Technigues of vibration and lysis applied to gas turbines. Gas Turbine Int., 17 (6), 16–22.

Randall, L. F. (1977). Preventive maintenance of rotating machinery ising Vibration detection Gronaud Steel Engineer, 54 (4), 52–60.

Rouch, P. (1980). Vychisleitel'naja gidrodinamika. Moscow: Mir, 287.

Published

2016-04-29

Issue

Section

Technical Sciences