Modares Mechanical Engineering

Modares Mechanical Engineering

Design of load sharing algorithm in a compression station by MPC method and real-time optimization in response to variable demand

Authors
omid mansourzadeh 1
Karim Salahshoor 2
1 Department of Automation and Instrumentation, Petroleum University of Technology, Ahvaz
2 Petroleum University of Technology
Abstract
To transport the natural gas from the producer sources to the consumers, gas pipelines are used. The extension of the pipelines reduces gas pressure and compression stations are considered to compensate for the loss of pressure in the transport path. At these stations, several compressor units usually work in parallel to share the gas inlet flow. The purpose of the present study is to investigate the load distribution method between parallel compressors in an optimal manner according to the capacity of each compressor. In this paper, a load sharing algorithm is proposed with the help of a model-based predictive controller (MPC) to achieve a stable and efficient operation at the compression station. In this algorithm, real-time optimization is used by an adaptive modifier method when faced with a variable demand from the consumer. The optimization is done according to the capacity of each compressor and using the approximated efficiency curve. In this way, the coordinates of the optimal working points for each compressor are obtained. The proposed algorithm is implemented in MATLAB software on the dynamics of centrifugal compressors in parallel arrangement. The results show that the load distribution using the proposed method has a much better performance than the old methods such as equal load balancing. This method results in the optimal operation of each compressor and thus storing and saving the natural gas.
Keywords
Gas compressor
Real-time optimization
Variable demand
Load sharing
Predictive controller

Subjects

[1] F. Paparella, L. DomĂ­nguez, A. Cortinovis, M. Mercangoz, D. Pareschi, S. Bittanti, Load sharing optimization of parallel compressors, In: European Control Conference (ECC), IEEE, pp.4059-4064, 2013.
[2] J.M. Maciejowski, Predictive control: with constraints, Pearson education, 2002.
[3] C.Y. Chen, B. Joseph, On-line optimization using a two-phase approach: An application study, Industrial & engineering chemistry research, Vol. 26, No. 9, pp.1924-1930, 1987.
[4] M.L. Darby, M. Nikolaou, J. Jones, D. Nicholson, RTO: An overview and assessment of current practice, Journal of Process Control, Vol. 21, No. 6, pp.874-884, 2011.
[5] A. Marchetti, B. Chachuat, D. Bonvin, Modifier-adaptation methodology for real-time optimization. Industrial & engineering chemistry research, Vol. 48, No. 13, pp.6022-6033, 2009.
[6] W. Gao, S. Engell, Iterative set-point optimization of batch chromatography, Computers & Chemical Engineering, Vol.29, No. 6, pp.1401-1409, 2005.
[7] G.A. Bunin, G. Francois, D. Bonvin, Sufficient conditions for feasibility and optimality of real-time optimization schemes-I. Theoretical foundations. arXiv preprint arXiv:1308.2620, 2013.
[8] P. Milosavljevic, A. Cortinovis, A.G. Marchetti, T. Faulwasser, M. Mercangöz, D. Bonvin, Optimal load sharing of parallel compressors via modifier adaptation, In: Control Applications (CCA), IEEE Conference on, pp.1488-1493, 2016.
[9] J.T. Gravdahl, O. Egeland, Centrifugal compressor surge and speed control, IEEE Transactions on control systems technology, Vol. 7, No. 5, pp.567-579, 1999.
[10] A. Cortinovis, D. Pareschi, M. Mercangoez, T. Besselmann, Model predictive anti-surge control of centrifugal compressors with variable-speed drives, IFAC Proceedings Volumes, Vol. 45, No. 8, pp.251-256, 2012.
[11] J.T. Gravdahl, O. Egeland, A Moore-Greitzer axial compressor model with spool dynamics, In: Decision and Control, Proceedings of the 36th IEEE Conference on, IEEE, Vol. 5, pp.4714-4719, 1997.
[12] M. Taleb Ziabari, J. Motlagh, M. Reza, K. Salahshoor, A. Ramazani, Surge Control in Constant Speed Centrifugal Compressors Using Nonlinear Model Predictive Control, The Modares Journal of Electrical Engineering, Vol. 12, No. 1, pp.49-53, 2015.
[13] E.S. Menon, Gas pipeline hydraulics, CRC Press, 2005.
[14] M.P. Boyce, Centrifugal compressors: a basic guide. PennWell Books, 2003.
[15] P. Ferber, U. Basu, G. Venkataramanan, M. Goodreau, P. Linden, Gas Pipeline Optimization. In: PSIG Annual Meeting. Pipeline Simulation Interest Group, 1999.
[16] W. Blotenberg, H.O. Jeske, H. Voss, Design, control and startup features of three parallel-working propane compressors each having three stage groups. In Proceedings of the... Turbomachinery Symposium, , Gas Turbine Laboratories, Department of Mechanical Engineering, Texas A & M University, Vol. 13, p. 39, 1984.
[17] B.A Foss, T.S. Schei, Putting nonlinear model predictive control into use. In Assessment and Future Directions of Nonlinear Model Predictive Control, Springer Berlin Heidelberg, pp.407-417, 2007.
[18] G. Processors, Gas Processors and Suppliers Association engineering data book, Tulsa, OK: GPSA, 2004.
Modares Mechanical Engineering
Volume 18, Issue 5
September 2018
Pages 84-90