Due to a larger intervention application of the wind-photovolatic new energy generation system, the stability and reliability of the main power grid will be greatly affected. One of the most effective methods to improve the quality of the power grid is to add the energy storage euipment. Based in this, according to the energy storage demand of short term and high frequency in the power grid, this paper focuses on a kind of power regulation system based on the flywheel energy storage array. Owing to the advantages of fast response and frequent charge-discharge characteristics, the flywheel system can be used to support and regulate the power grid through the process of the frequency and amplitude modulation. By using the flywheel system, the stability of the power grid can be improved effectively. In this paper, the proposed power regulation system is firstly introduced as well as the working principle of the flywheel energy storage array. On this basis, the key performance indices of the flywheel array are given, and then a kind of charge-discharge test process is provided. Finally, the power experiments by using the actual flywheel system is developed, including the power absorption and feedback electric generation. The experiment results show that the response characteristics, capacity and power of the designed flywheel array can meet the needs of power regulation system applied in the power grid.
Published in | International Journal of Sensors and Sensor Networks (Volume 9, Issue 1) |
DOI | 10.11648/j.ijssn.20210901.17 |
Page(s) | 45-52 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Power Grid, Flywheel Energy Storage Array, Power Regulation System, Charge-Discharge Test
[1] | Sun Chunshun, Wang Yaonan Li Xinran. Synthesized power and frequency control of wind power generation system assisted through flywheels [J]. Proceedings of the CSEE, 2008, 28 (29): 111-116. |
[2] | Xue Jinhua, Ye Jilei, Wang Chun, et al. Frequency regulation application and ecomomic analysis of flywheel energy storage in a regional power grid [J]. Power System and Clean Energy, 2013, 29 (12): 113-118. |
[3] | Zhao Hantong, Zhang Jiancheng. Research on bus voltage control strategy of off-grid PV microgrid with flywheel energy storage system based on sliding mode control [J]. Power System Protection and Control, 2016, 44 (16): 36-42. |
[4] | Xin F., Bri-mathias H., Linquan B. Mean-variance optimization-based energy storage scheduling considering day-ahead and real-time LMP uncertainties [J]. IEEE Transactions on Power Systems, 33 (6), 2018, 7292–7295. |
[5] | Zhiliang Z., Yongyong C., Yue Z. A distributed architecture based on microbank modules with self-reconfiguration control to improve the energy efficiency in the battery energy storage system [J]. IEEE Transactions on Power Electronics, 31 (1), 2016, 304–317. |
[6] | Dai Xingjian, Deng Zhanfeng, Liu Gang, et al. Review on advanced flywheel energy storage system with large scale [J]. Transactions of China Electrotechnical Society, 2011, 26 (7): 133-140. |
[7] | Li Shusheng, Fu Yongling, Liu Ping. Position estimation and compensation based on a two-step extended sliding-mode observer for a MSFESS [J]. Sensors, 2018, 18 (8): 1-17. |
[8] | Wang Gengji and Wang Ping. Rotor loss analysis of PMSM in flywheel energy storage system as uninterruptable power supply [J]. IEEE Transactions on Applied Superconductivity, 2017, 26 (7): 1-7. |
[9] | Li Shusheng, Fu Yongling, Liu Ping, et al. Research on twin trawling charging-discharging experimental method for the magnetically suspended flywheel-based dynamic UPS system [J]. Energy Storage Science and Technology, 2018, 7 (05): 828-833. |
[10] | Junfeng L., Yongduan S., Xiaoqiang D. Hierarchical coordinated control of flywheel energy storage matrix systems for wind farms [J]. IEEE/ASME Transactions on Mechatronics, 23 (1), 2018, 48–56. |
[11] | Xiaojun L., Bahareh A., Alan P. A utility-scale flywheel energy storage system with a shaftless hubless high-strength steel rotor [J]. IEEE Transactions on Industrial Electronics, 65 (8), 2018, 6667–6675. |
[12] | Ehsan G., Mojtaba M. Design and prototyping of a new flywheel energy storage system [J]. IET Electric Power Applications, 11 (9), 2017, 1517–1526. |
[13] | Wang DaJie, Sun Zhenhai, Chen Ying. Application of array 1MW flywheel energy storage system in rail transit [J]. Energy Storage Science and Technology, 2018, 7 (5): 841-846. |
[14] | Liu Ping, Li Shusheng, Li Guangjun, et al. Experimental research on DC power recycling system in the subway based on the magnetically suspended energy-storaged flywheel array [J]. Energy Storage Science and Technology, 2020, 9 (3): 910-917. |
[15] | Bolund B, Bernhoff H, Leijon M. Flywheel energy and power storage systems [J]. Renewable and Sustainable Energy Reviews, 2007, 11 (2): 235-258. |
[16] | Liu Ping, Li Shusheng. Modeling and simulation analysis on flywheel energy storage array-based shore power micro-grid control system [J]. Small and Special Electrical Machines, 2020, 48 (06): 33-39. |
[17] | Zhou, X. X., Zhang R., Fang, J. C. Accurate and fast-response magnetically suspended flywheel torque control [J]. Transactions of the Institute of Measurement and Control. 38 (1), 2015, 73-82. |
[18] | Ni, R. G., Xu, D. G., B., F. Square-wave voltage injection algorithm for PMSM position sensorless control with high robustness to voltage errors [J]. IEEE Transactions on Power Electronics, 32 (7), 2017, 5425–5437. |
[19] | CALNETIX TECHNOLOGIES: Vycon direct connect kinetic energy storage systems [EB/OL]. USA, 2016. |
[20] | HEADQUARTERS: Piller power systems [EB/OL]. Germany, 2017. http://www.piller.com/en-GB/documents/552/apostar-static-ups-brochure-en.pdf. |
APA Style
Shusheng Li, Ping Liu. (2021). Power Regulation System and Charge-discharge Test Applied in Power Grid Based on the Flywheel Energy Storage Array. International Journal of Sensors and Sensor Networks, 9(1), 45-52. https://doi.org/10.11648/j.ijssn.20210901.17
ACS Style
Shusheng Li; Ping Liu. Power Regulation System and Charge-discharge Test Applied in Power Grid Based on the Flywheel Energy Storage Array. Int. J. Sens. Sens. Netw. 2021, 9(1), 45-52. doi: 10.11648/j.ijssn.20210901.17
AMA Style
Shusheng Li, Ping Liu. Power Regulation System and Charge-discharge Test Applied in Power Grid Based on the Flywheel Energy Storage Array. Int J Sens Sens Netw. 2021;9(1):45-52. doi: 10.11648/j.ijssn.20210901.17
@article{10.11648/j.ijssn.20210901.17, author = {Shusheng Li and Ping Liu}, title = {Power Regulation System and Charge-discharge Test Applied in Power Grid Based on the Flywheel Energy Storage Array}, journal = {International Journal of Sensors and Sensor Networks}, volume = {9}, number = {1}, pages = {45-52}, doi = {10.11648/j.ijssn.20210901.17}, url = {https://doi.org/10.11648/j.ijssn.20210901.17}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijssn.20210901.17}, abstract = {Due to a larger intervention application of the wind-photovolatic new energy generation system, the stability and reliability of the main power grid will be greatly affected. One of the most effective methods to improve the quality of the power grid is to add the energy storage euipment. Based in this, according to the energy storage demand of short term and high frequency in the power grid, this paper focuses on a kind of power regulation system based on the flywheel energy storage array. Owing to the advantages of fast response and frequent charge-discharge characteristics, the flywheel system can be used to support and regulate the power grid through the process of the frequency and amplitude modulation. By using the flywheel system, the stability of the power grid can be improved effectively. In this paper, the proposed power regulation system is firstly introduced as well as the working principle of the flywheel energy storage array. On this basis, the key performance indices of the flywheel array are given, and then a kind of charge-discharge test process is provided. Finally, the power experiments by using the actual flywheel system is developed, including the power absorption and feedback electric generation. The experiment results show that the response characteristics, capacity and power of the designed flywheel array can meet the needs of power regulation system applied in the power grid.}, year = {2021} }
TY - JOUR T1 - Power Regulation System and Charge-discharge Test Applied in Power Grid Based on the Flywheel Energy Storage Array AU - Shusheng Li AU - Ping Liu Y1 - 2021/06/29 PY - 2021 N1 - https://doi.org/10.11648/j.ijssn.20210901.17 DO - 10.11648/j.ijssn.20210901.17 T2 - International Journal of Sensors and Sensor Networks JF - International Journal of Sensors and Sensor Networks JO - International Journal of Sensors and Sensor Networks SP - 45 EP - 52 PB - Science Publishing Group SN - 2329-1788 UR - https://doi.org/10.11648/j.ijssn.20210901.17 AB - Due to a larger intervention application of the wind-photovolatic new energy generation system, the stability and reliability of the main power grid will be greatly affected. One of the most effective methods to improve the quality of the power grid is to add the energy storage euipment. Based in this, according to the energy storage demand of short term and high frequency in the power grid, this paper focuses on a kind of power regulation system based on the flywheel energy storage array. Owing to the advantages of fast response and frequent charge-discharge characteristics, the flywheel system can be used to support and regulate the power grid through the process of the frequency and amplitude modulation. By using the flywheel system, the stability of the power grid can be improved effectively. In this paper, the proposed power regulation system is firstly introduced as well as the working principle of the flywheel energy storage array. On this basis, the key performance indices of the flywheel array are given, and then a kind of charge-discharge test process is provided. Finally, the power experiments by using the actual flywheel system is developed, including the power absorption and feedback electric generation. The experiment results show that the response characteristics, capacity and power of the designed flywheel array can meet the needs of power regulation system applied in the power grid. VL - 9 IS - 1 ER -