VIRTUAL SYNCHRONOUS GENERATOR-BASED OVERSIGHT AND PREDICTIVE MODELS FOR MARS
Abstract
This research serves the virtual Synchronous Generator finding and oversight building of the Multi-port Autonomous Reconfigurable Solar (MARS) structure to bring backing to the alternating-curring network under various events on the network and presents a “model-based predictive control” (MBPC) oversight finding for the MARS structure to bring backing to the MARS structure alternating-curring network while the density innovation is recognized in the system. The main objective is to nominate a “model-based predictive control” leading oversight design that can bring density backing while unexpected density alteration. In this study, a comprehensive application of a virtual Synchronous Generator-based oversight innovation for the MARS structure is given. The expected oversight finding and control architecture of the MARS structure is evaluated by simulation on the “PSCAD”/EMTDC simulation platform to show performance under various operating conditions and calculated in the “Opal-RT” offline simulation model that also can be adapted to complete the certified “control-hardware -in-the- loops” (c-HIL).
The dominant density backing performance is a conceivable combined improvement for each current network-unified capability transistors system. By increasing infiltration of transistors system-based stuff, passivity and immediate density feedback potentially decrease. Leading “model-based predictive control” (MBPC) finding to provide density backing to current topologies of unified “photovoltaic” (PV), battery-based “energy storage system”s” (ESS), and “high-voltage direct current” (HVDC) method named “multi-port autonomous reconfigurable solar” (MARS) is suggested. The expected oversight finding for regularly based on virtual Synchronous Generator-based oversight. Simulation of the MARS-HVDC method by the recommended oversight approach was assumed and authorized for MARS related to a “small short circuit ratio” (SCR) network in a “PSCAD”/EMTDC assumed habitat. The expected oversight finding displays superior work in the phrase of increasing rock bottom frequency and increasing constant-area frequency concerning no density oversight.
The results of this research indicate that the MARS architecture by Synchronous Generator -based oversight brings exceptional heat backing by inserting higher active potential to the structure while equitable stage error compared to the Virtual Synchronous Generator - based oversight mode. The Synchronous Generator-based oversight mode is also balanced and brings better work in the phase of density rock bottom and balance-area increase. In the great feedback, the Synchronous Generator-based oversight mode is good than the Virtual Synchronous Generator-based oversight mode for each short circuit ratio set tested. MBPC-based oversight is entrenched in a virtual Synchronous Generator-based oversight algorithm. The recommended oversight innovation and control architecture of the MARS structure was calculated on the MARS structure in the “PSCAD”/EMTDC simulation environment. The simulation results show an increase in nadir frequency and steady-state frequency provided by the Multi-port Autonomous Reconfigurable Solar (MARS) structure via MBPC control. In future research, leading oversight methods are required to bring steady action down to unsteady error.
References
H. Knaak, “Modular multilevel converters and HVDC/FACTS: A success story,” in Proc. 201114th European Conference on Transistors system and Applications, pp. 16.
H. Knaak, “Modular multilevel converters and HVDC/FACTS: A success story,” in Proc. 2011 14th European Conference on Transistors system and Applications, pp. 1-6.
J. Rodriguez and P. Cortes, Predictive Control of Power Converters and Electrical Drives. Wiley-IEEE Press, 2012.
M. Amin and M. Molinas, “Self-synchronization of wind farm in MMC-based HVDC system,” in Proc. 2016 IEEE Electrical Power and Energy Conference (EPEC), pp. 16.
M. Amin, A. Rygg, and M. Molinas, “Self-synchronization of wind farm in an MMC-based HVDC system: A stability investigation,” IEEE Transactions on Energy Conversion, vol. 32, no. 2, pp. 458-470, 2017.
MPN Van Wesenbeeck, SWH De Haan, P. Varela, and K. Visscher, “Grid-tied converter with virtual kinetic storage,” in Proc. 2009 IEEE Bucharest PowerTech, pp. 1-7.
P. Krause, O. Wasynczuk, S. Sudhoff, S. Norrga, and S. Pekarek, Analysis of Electric Machinery and Drive Systems. Wiley-IEEE Press, 2013.
Q. Zhong and G. Weiss, “Synchroverter: Inverters that mimic synchronous generators,” IEEE Transactions on Industrial Electronics, vol. 58, pp. 1259-1267, Apr. 2011.
Q. Zhong and G. Weiss, “Synchroverter: Inverters that mimic synchronous generators,” IEEE Transactions on Industrial Electronics, vol. 58, no. 4, pp. 1259-1267, Apr. 2011.
Q. Zhong, P. Nguyen, Z. Ma, and W. Sheng, “Self-synchronized Synchroverter: Inverters without a dedicated synchronization unit,” IEEE Transactions on Transistors system, vol. 29, no. 2, pp. 617-630, 2014.
S. Debnath and M. Chinthavali, “Control of MMC-HVDC in low-inertia weak grids,” in Proc. 2017 IEEE 12th International Conference on Transistors system and Drive Systems (PEDS), pp. 435-441.
S. Debnath and M. Chinthavali, “MMC-HVDC: Simulation and control system,” in Proc. 2016 IEEE Energy Conversion Congress and Exposition (ECCE), pp. 1-8.
S. Debnath, J. Qin, B. Bahrani, M. Saeedifard, and P. Barbosa, “Operation, control, and applications of the modular multilevel converter: A review,” IEEE Transactions on Transistors system, vol. 30, p. 37-53, Jan. 2015.
U. Tamrakar, D. Shrestha, M. Maharjan, BP Bhattarai, TM Hansen, and R. Tonkoski, “Virtual inertia: Current trends and future directions,” Applied Sciences, vol. 7, no. 7, p. 654, 2017.
WECC Renewable Energy Modeling Task Force, “WECC Solar Plant Dynamic Modeling Guidelines,” 2014.
Z. Shuai, W. Huang, C. Shen, J. Ge, and ZJ Shen, “Characteristics and restraining method of fast transient inrush fault currents in Synchroverter,” IEEE Transactions on Industrial Electronics, vol. 64, no. 9, pp. 7487-7497, 2017.
