Mathematical modelling of the process of natural gas transportation via pipe networks using crossing-branch method
DOI:
https://doi.org/10.26577/JMMCS202412112Keywords:
natural gas transportation, mathematical modelling, nonlinear modelAbstract
This research is among the most relevant research on the problems of natural gas transportation through pipeline networks. The increased demand for natural gas in Kazakhstan is associated with a greater level of environmental friendliness; as a result, many power generating stations use natural gas as their main source of energy. Modernization of existing thermal power plants is necessary to improve the environmental situation in the country. There are three main groups of gas pipeline systems considered in the literature: collection, transmission, and distribution systems. In this article, we present detailed research on the transmission process and develop useful approaches. Over the past few years, a huge amount of research has been conducted on many problems of decision-making in the gas industry and, in particular, on optimizing the pipeline network. In this paper, we consider dynamical models, highlighting aspects of modelling and the most relevant solutions to date. This research can serve as a useful tool for understanding the evolution of many real-world applications and the most recent advances in solution methodologies emerging in this complex field of research. The results of this research can be used to develop technologies for automating calculations, planning, and optimizing natural gas transportation.
References
Herty, M. and Mohring, J. and Sachers, V. "A new model for gas flow in pipe networks", Math Meth Appl Sci, 33:1
(2010): 845-855.
Steinbach, M. On PDE solution in transient optimization of gas networks (Berlin: ZIB Berlin, 2004).
PSIG "Pipeline Simulation Interest Group", https://psig.org/
White, F.M. Fluid Mechanics (New York: McGraw-Hill, 2002).
Osiadacz, A.J. Dynamic optimization of high pressure gas networks using hierarchical systems theory (Warsaw: Warsaw
University of Technology, 2002).
Cameron, I. Using an excel-based model for steady-state and transient simulation (Ottawa: TransCanada Transmission
Company, 2000).
Zhou, J. and Adewumi, M.A. "Simulation of transients in natural gas pipelines using hybrid TVD schemes", International
Journal for Numerical Methods in Fluids, 32:4 (2000): 407-437.
Li, T. "Interdependency of natural gas network and power system security", IEEE Trans. Power Systems, 23:4 (2008):
-1824.
MITEI "Growing concerns, possible solutions: The interdependency of natural gas and electricity systems", MIT Energy
Initiative Symposium, Cambridge, United States, April 16, 2013.
Chertkov, M. and Backhaus, S. and Lebedev, V. "Cascading of Fluctuations in Interdependent Energy Infrastructures:
Gas-Grid Coupling", Applied Energy, 160:1 (2000): 541-551.
Chertkov, M. and Fisher, M. and Backhaus, S. and Bent, R. and Misra, S. "Measurement of energy market inefficiencies
in the coordination of natural gas and power", In 47th Hawaii Internat. Conf. on System Sci., (2014): 2335-2343.
Tabors, R. and Adamson, S. "Measurement of energy market inefficiencies in the coordination of natural gas and power",
In 47th Hawaii Internat. Conf. on System Sci., (2014): 2335-2343.
Rios-Mercado, R.Z. and Borraz-Sanchez, C. "Optimization problems in natural gas transportation systems: A state-of
the-art review", Applied Energy, 147:1 (2015): 536-555.
Koch, T. and Hiller, B. and Pfetsch, M.E. and Schewe, L. Evaluating Gas Network Capacities (Philadelphia, United
States: Society for Industrial and Applied Mathematics Philadelphia, 2015).
Zlotnik, A. and Chertkov, M. and Backhaus, S. "Optimal control of transient flow in natural gas networks", 54th IEEE
Conference on Decision and Control, Osaka, Japan: 4563-4570.
Mak, T. and Van Hentenryck, P. and Zlotnik, A. and Bent, R. "Dynamic Compressor Optimization in Natural Gas
Pipeline Systems", INFORMS Journal on Computing, 31:1 (2019): 40-65.
Chen N.H. "An explicit equation for friction factor in pipe", Industrial and Engineering Chemistry Fundamentals, 18:3
(1979): 296-297
