International Journal of Smart Grid - ijSmartGrid

Wind energy has the fastest and highest growth rate of any other Renewable energy sources (RES). Investigating the Wind Energy Conversion Systems (WECS) is very important for improving efficiency. However, It is required a monumental accessible land space for installing Wind turbines(WT). Consequently, this paper presents the design and implementation of a Wind turbine emulator (WTE) to substitute WTs. The proposed WTE includes a new Maximum Point Power Tracking(MPPT) technique based on integrating binary search technique and genetic algorithm. The proposed emulator has an SQLite database as a repository of wind turbine information. Also, it has a graphical user interface(GUI) to facilitate the operation. System components have been modeled and simulated using MATLAB Simulink. Furthermore, a prototype is implemented based on a series excited DC motor and permanent magnet synchronous (PMSG). All static and dynamic characteristics have been investigated to prove the capabilities of the developed emulator. Also, an integration test has been conducted on real-time conditions of wind speed profile and working load for 24 hours to check the reliability. The experimental results are compared with the simulation results for validation and showed the capability of the proposed WTE of emulating a wide range of Wind turbines.

Renewable energy systems; Wind Turbine Emulator; DC motor, Wind energy conversion systems, Genetic Algorithm.

Renewables 2018 Global status report http://www.ren21.net/

International electricity agency report 2017 http://www.iea.org

Yasser E. Abu Eldahab, Abdalhalim Zekry, Naggar H. Saad, Enhancing the Optimization of Hybrid Renewable Energy Systems by Using Statistical Calculations and Data Mining Analysis, IJRER, Vol 9, No 2 (2019), PP 868-886

Ozcira, S., Bekiroglu, N., and Agcal, A., “A study on feasibility of wind energy production in Silivri region by using laboratory setupâ€, International Conference on Renewable Energy Research and Applications (ICRERA), Madrid, Spain, 20-23 Oct. 2013, 1175 – 1179

Hardy T, Jewell W. Hardware-in-the-loop wind turbine simulation platform for a laboratory feeder model. IEEE Trans Sustain Energy 2014;5(3):1003–9.

Oh KY, Lee JK, Bang HJ, Park JY, Lee JS, Epureanu BI. Development of a 20 kW wind turbine simulator with similarities to a 3 MW wind turbine. Renew Energy2014;62:379–87.

Dahbi A, Hachemi M, Nait-Said N, Nait-Said MS. Realization and control of a wind turbine connected to the grid by using PMSG. Energy Convers Manage2014;84:346–53.

Abdeddaim S, Betka A, Drid S, Becherif M. Implementation of MRAC controller of DFIG based variable speed grid connected wind turbine. Energy Convers Manage2014;79:281–8.

Averous NR, Stieneker M, Kock S, Andrei C, Helmedag A, Doncker RWD, et al.Development of a 4 MW full-size wind-turbine test bench. IEEE J Emerg Sel TopPower Electron 2017;5(2):600–9.

Yan J, Feng Y, Dong J. Study on dynamic characteristic of wind turbine emulator based on PMSM. Renew Energy 2016;97:731–6.

Daili Y, Gaubert JP, Rahmani L. Implementation of a new maximum power point tracking control strategy for small wind energy conversion systems without mechanical sensors. Energy Convers Manage 2015;97:298–306.

Castello J, Espi JM, Gil RG. Development details and performance assessment of a wind turbine emulator. Renew Energy 2016;86:848–57.

Sajadi A, Roslaniec L, Klos M, Biczel P, Loparo KA. An emulator forfixed pitch windturbine studies. Renew Energy 2016;87:391–402.

Gan LK, Shek JKH, Mueller MA. Modeling and characterization of downwind tower shadow effects using a wind turbine emulator. IEEE Trans Ind Electron2017;64(9):7087–97.

Gan LK, Shek JKH, Mueller MA. Analysis of tower shadow effects on battery lifetime in standalone hybrid wind-diesel-battery systems. IEEE Trans Ind Electron2017;64(8):6234–44.

Chinchilla M, Arnaltes S, Rodriguez-Amenedo JL. Laboratory set-up for wind turbine emulation. In: Proc. IEEE International Conference on IndustrialTechnology (ICIT’04) 8e10 Dec. 2004. p. 553e7. Hammamet-Tunez.

Monfared M, Kojabadi HM, Rastegar H. Static and dynamic wind turbine simulator using a converter controlled dc motor. Renew Energy 2008;33(5):906e13.

Teodorescu R, Blaabjerg F. Flexible control of small wind turbines with grid failure detection operating in stand-alone and grid-connected mode. IEEETrans Power Electron 2004;19(5):1323e32.

Cardenas R, Peña R. Sensorless vector control of induction machines for variable-speed wind energy applications. IEEE Trans Energy Conv 2004;19(1):196e205.

Ramirez D, Martinez S, Blazquez F, Carrero C. Use of STATCOM in wind farms with fixed-speed generators for grid code compliance. Renew Energy2012;37:202e12.

Zaragoza J, Pou J, Arias A, Spiteri C, Robles E, Ceballos S. Study and experimental verification of control tuning strategies in a variable speed wind energy conversion system. Renew Energy 2011;36:1421e30.

El Mokadem M, Courtecuisse V, Saudemont C, Robyns B, Deuse J. Experimental study of variable speed wind generator contribution to primary frequency control. Renew Energy 2009;34:833e44.

Arribas JR, Veganzones C, Blázquez F, Platero CA, Ramírez D, Martínez S, et al.Computer-based simulation and scaled laboratory bench system for theteaching and training of engineers on the control of doubly fed inductionwind generators. IEEE Trans Power Syst 2011;26(3):1534e43.

Kojabadi HM, Chang L, Boutot T. Development of a novel wind turbine simulator for wind energy conversion systems using an inverter-controlled induction motor. IEEE Trans Energy Conv 2004;19(3):547e52.

Munteanu I, Cutululis NA, Bratcu AI, Changa E. Optimization of variable speed wind power systems based on a LQG approach. Control Eng Pract 2005;13(7):903e12.

Cárdenas R, Peña R, Wheeler P, Clare J, Asher G. Control of the reactive power supplied by a WECS based on an induction generator fed by a matrix converter. IEEE Trans Ind Electron 2009;56(2):429e38.

Dolan DSL, Lehn PW. Real-time wind turbine emulator suitable for power quality and dynamic control studies. In: Proc. International Conference on Power Systems Transients (IPST’05) 19e23 Jun. 2005. p. 1e6. Montreal-Canada.

B. Rabelo, W. Hofmann, M. Gluck. Emulation of the Static and Dynamic Behavior of a Wind-turbine with a DC-Machine. The 35th Annual IEEE Power Electronics Specialists Conference. 2004:2107-2112.

J. Wu and Y. J. Xu, Dynamic wind-turbine emulation based on induction motor [J]. Journal of South China University of Technology.2005, (6):46-49

J. Vaheeshan, A. Atputharajah, Wind Turbine Emulator,2011 6th International Conference on Industrial and Information Systems, ICIIS 2011, Aug. 16-19, 2011, Sri Lanka

A. Sokolovs, L. Grigans, E. Kamolins, J. Voitkans, AN INDUCTION MOTOR BASED WIND TURBINE EMULATOR, LATVIAN JOURNAL OF PHYSICS AND TECHNICAL SCIENCES 2014, N 2, DOI: 10.2478/lpts-2014-0009

Camilo I. Martínez-Márquez, Jackson D. Twizere-Bakunda, David Lundback-Mompó, Salvador Orts-Grau, Francisco J. Gimeno-Sales and Salvador Seguí-Chilet, Small Wind Turbine Emulator Based on Lambda-Cp Curves Obtained under Real Operating Conditions, Energies 2019, 12, 2456; doi:10.3390/en12132456

Marcel Topor, Wind Turbine Emulator Development Using Labview FPGA, International Journal of Emerging Engineering Research and Technology, Volume 3, Issue 7, July 2015, PP 13-21.

Abdullah M, Yatim A, Tan C, Saidur R, A review of maximum power point tracking algorithms for wind energy systems, Renewable and Sustainable Energy Reviews 16 (2012) 3220–3227

Abu Eldahab Yasser E, Saad Naggar H, Zekry Abdalhalim. Enhancing the maximum power point tracking techniques for photovoltaic systems. Renew Sustain Energy Rev 2014;40:505–14.

] Abdelkafi A, Krichen L. New strategy of pitch angle control for energy management of a wind farm. Energy 2011;36:1470–9.