Structure optimization of metal rotor of grid-connected flywheel energy storage system

被引：0

作者：

Wu X. ^{[1
]}

Chen Y. ^{[1
]}

Liu Y. ^{[1
]}

机构：

[1] Research Center for Advanced Flywheel Energy Storage Technology, North China Electric Power University, Beijing

来源：

Taiyangneng Xuebao/Acta Energiae Solaris Sinica | 2021年 / 42卷 / 02期

关键词：

Energy storage density; Flywheel rotor; Stress analysis; Structural analysis;

D O I：

10.19912/j.0254-0096.tynxb.2018-0907

中图分类号：

学科分类号：

摘要：

Solar and wind power generation is with intermittent characteristic, which requires energy storage system to balance their effect on the power grid. The flywheel energy storage system (FESS) owns the advantages of quick response speed and high power density. So, the FESS can be used to solve the problem of grid connection for the large scale renewable power generation. The energy storage density is an important index to evaluate the performance of the FESS. In this paper, we proposed a method to increase the energy storage density of FESS. This method modifies the metal rotor structure to decrease the rotor mass and increase the energy storage density, while the proposed structure can still keep the original value of the total energy storage, rotation speed and rotor diameter. Firstly, the metal rotor with the same thickness is modified through a structure with different thickness in the radius direction. Then, the Response Surface Optimization Module in ANSYS Workbench is adopted to optimize the mass of the rotor structure above mentioned. Simulation results show that the developed structure can reduce 16.88% of the rotor mass and increase 20.32% of the energy storage density. © 2021, Solar Energy Periodical Office Co., Ltd. All right reserved.

引用

页码：317 / 321

页数：4

共 18 条

[1] RUAN J P, ZHANG J C, WANG J H., Improvement of stability of wind farms connected to power grid using flywheel energy storage system, Electric power science and engineering, 24, 3, pp. 5-8, (2008)
[2] DAI X J, DENG Z F, LIU G, Et al., Review on advanced flywheel energy storage system with large scale, Transactions of China Electrotechnical Society, 26, 7, pp. 133-140, (2011)
[3] LI W J, ZHANG G M, AI L W, Et al., Development status of high-temperature superconducting flywheel energy storage system, Advanced technology of electrical engineering and energy, 36, 10, pp. 19-31, (2017)
[4] TANG C L, ZHANG X H, MENG X L., Research on flywheel energy storage technology abroad, Sino-global energy, 23, 6, pp. 82-86, (2018)
[5] ZHU H Q, TANG Y Q., Key technologies and application trends of flywheel energy storage system, Machinery design & manufacture, 311, 1, pp. 265-268, (2017)
[6] KONG D Q, PEI Y M, XING L Y, Et al., Metallic materials for energy storage flywheel rotors, Energy storage science and technology, 3, 1, pp. 30-35, (2014)
[7] TANG Y W, ZHANG J P, DENG C, Et al., Characteristics and application of a high-speed and high-power flywheel energy storage device, The journal of new industrialization, 8, 4, pp. 20-26, (2018)
[8] Technology leadership
[9] TAKAHASHI K, KITADE S, MORITA H., Development of high speed composite flywheel rotor for energy storage systems, Advanced composite materials, 11, 1, pp. 41-50, (2002)
[10] DAI X J, JIANG X J, WANG Q N, Et al., The design and testing of a 1 MW/60 MJ flywheel energy storage power system, Transactions of China Electro technical Society, 32, 21, pp. 171-175, (2017)

← 1 2 →