Modeling and Control Design of an Autonomous Hybrid Wind/Energy Storage Generation Unit

Authors

  • Shiref A. Abdalla Department of Electrical, Malaysia - Japan International Ins. of Technology, UTM, Kuala Lumpur. Author
  • Hasmah Mansor Department of Electrical & Computer Engineering, Kulliyyah of Engineering, International Islamic University Malaysia (IIUM), Kuala Lumpur, Malaysia. Author
  • Nurul F. Hasbullah Department of Electrical & Computer Engineering, Kulliyyah of Engineering, International Islamic University Malaysia (IIUM), Kuala Lumpur, Malaysia. Author
  • Ahmad M. Kassem lectrical Engineering Department, Faculty of Engineering, Sohag University, Egypt. Author

DOI:

https://doi.org/10.61841/zmdyey55

Keywords:

Hybrid Wind/storage Generation Unit, PID Control, Stand-alone Power System, Wind Power, Energy Storage

Abstract

The purpose of the present paper is to investigate a controller design and simulations of an autonomous hybrid wind turbine system with a variable-speed permanent magnet synchronous generator (PMSG) and a system for storing energy. The proposed system is mainly composed of a wind turbine-driven permanent magnet synchronous generator, an uncontrolled rectifier, a DC/DC converter, a DC/AC inverter, and static loads. Furthermore, the mathematical model of the studied sub-systems and two control loops are considered. The first one is the controller, which needed to preserve the DC-link voltage fixed at its desired value. The second one is the controller, which needed to regulate the charge/discharge modes of the storage battery. The suggested hybrid wind/energy storage power generation model is considered and analyzed in the absence of a controller first. Then, the considered hybrid wind/energy storage power generation unit with the proposed controller is examined through a step change in wind speed. Digital simulation results show that the power desired by the linked loads may be successfully supplied and transported by the presented hybrid wind turbine and energy storage power generation system based on proportional-integral-derivative (PID) controller. Also, the emulation results show that there is good foretelling of the electrical variable waveforms and good achievement in the case of the presented controller emulated with the case of the controller without controller as maintaining the load voltage fixed at its reference values. 

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References

[1] Mastromauro R.A., Liserre M. and Dell'Aquila A. (2012), Control issues in single-stage photovoltaic

systems: MPPT, current, and voltage control, IEEE Trans. Ind. Informat., vol. 8(2), pp. 241-254.

[2] Liu C., Chau K.T., and Zhang X. (2010), An efficient wind-photovoltaic hybrid generation system using

doubly excited permanent-magnet brushless machine, IEEE Trans. Ind. Electron., vol. 57 (3), pp. 831–839.

[3] Kazmierkowski M.P., Jasinski M., Wrona D. (2011), DSP-based control of grid-connected power converters operating under grid distortions, IEEE Trans. Ind. Informat., vol. 7(2), pp. 204–211.

[4] Mendis, N., Muttaqi, K. M., Sayeef, S., and Perera, S. (2012), Stand-alone operation of wind turbine-based variable speed generators with maximum power extraction capability, IEEE Trans. on Energy Conv., 27 (4), pp. 822-834.

[5] Ali A.M.Y. (2011), Model predictive control approach based load frequency controller, WSEAS Transactions on System and Control, 7(1), pp. 265-275.

[6] Ali A.M.Y. and Kassem A.M. (2011), Optimal pole shifting controller for interconnected power system,

Energy Conversion and Management, 52(5), pp. 2227-2234.

[7] Kassem A.M. (2016), Modeling and robust control design of a stand-alone wind-based energy storage

generation unit powering an induction motor variable-displacement pressure-compensated pump." IET

Renewable Power Generation, Vol. 10, No. 3, pp. 275-286.

[8] Engin M. (2013), Sizing and simulation of PV-Wind hybrid power system, International Journal of

Photoenergy, 2013, pp. 1-10.

[9] Dalwadi P., Shrinet V., Mehta C.R., and Shah P. (2011), Optimization of solar-wind hybrid system for

distributed generation, Proc. Nirma University International Conference on Engineering (11), IEEE Press,

pp. 1-4.

[10] Elhadidy M.A. and ShaahidS.M. (1999), Optimal sizing of battery storage for hybrid (wind-diesel) power

systems, Renewable Energy, 18, pp. 77-86.

[11] Kumar R., Gupta R.A., and Bansal A.K. (2013), Economic analysis and power management of a stand-alone

wind/photovoltaic hybrid energy system using biogeography-based optimization algorithm, Swarm and

Evolutionary Computation, 8, pp. 33-43.

[12] Sedaghat, B., Jalilvand, A. and Noroozian, R. (2012), Design of a multilevel control strategy for integration

of stand-alone wind/diesel system, Electrical Power and Energy Systems 35, pp. 123–137.

[13] Monmasson, E., Idkhajine, L., Cirstea, M. N., Bahri, I., Tisan, A., and Naouar, M. W. (2011), FPG As in

industrial control applications, IEEE Trans. Ind. Informat., 7 (2), pp. 224–243.

[14] Kassem A.M. and Abdelaziz A.Y. (2014), Functional predictive control for voltage stability improvements

of autonomous hybrid wind-diesel power system, Electric Power Components and Systems, 42(8), 831–844.

[15] Behera S.C., Choudhary G.K., and Mandal R.K. (2015), PID controller-based automatic reactive power

control of a wind-dieselhybrid power system, Journal of Advanced Research in Electrical, Electronics and

Instrumentation Engineering, 4(11), 8826-8832.

[16] Rajaei A., Mohamadian M. and Varjani A.Y. (2013), Vienna-Rectifier-Based Direct Torque Control of

PMSG for Wind Energy Application, IEEE Transactions on Industrial Electronics, 60(7), 2919-2929.

[17] Barote L., Marinescu C., and Cirstea M.N. (2013), Control structure for single-phase stand-alone windbased energy sources, IEEE Transactions on Industrial Electronics, 60(2), 764-772.

[18] Hojabri H., Mokhtari H., and Chang L. (2013), Reactive power control of permanent-magnet synchronous

wind generator with matrix converter, IEEE Transactions on Power Delivery, 28(2), 575-584.

[19] Nguyen H.M. and Naidu D.S. (2012), Direct fuzzy adaptive control for stand-alonewind energy conversion

systems, Proceedings of the World Congress on Engineering and Computer Science, Vol. II, WCECS 2012,

October 24-26, 2012, San Francisco, USA.

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Published

30.04.2020

Issue

Vol. 24 No. 2 (2020): 24 (2) 2020

Section

Articles

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How to Cite

A. Abdalla, S., Mansor, H., F. Hasbullah, N., & M. Kassem, A. (2020). Modeling and Control Design of an Autonomous Hybrid Wind/Energy Storage Generation Unit. International Journal of Psychosocial Rehabilitation, 24(2), 2441-2451. https://doi.org/10.61841/zmdyey55