Fuzzy PID-based temperature control method for power transformer coils

被引：0

作者：

Chen H. ^{[1
]}

机构：

[1] Faculty of Engineering, Huanghe Science and Technology University, Zhengzhou

来源：

Int. J. Energy Technol. Policy | 2024年 / 1-2卷 / 86-104期

关键词：

coil temperature; control methods; fuzzy PID; power transformer;

D O I：

10.1504/IJETP.2024.138538

中图分类号：

学科分类号：

摘要：

To improve the response speed and control stability of power transformer coil temperature control, a fuzzy PID-based power transformer coil temperature control method is studied. Based on the physical model of power transformers, a mathematical model for temperature control of power transformer coils is constructed. For the constructed mathematical model, the fuzzy PID control algorithm is used to control the temperature of the power transformer coil. The PID control part uses proportional, integral, and differential operations to control the coil temperature. The fuzzy control algorithm is used to set fuzzy rules for the PID control parameters, and the power transformer coil temperature control results are output through the fuzzy inference process. The results show that using this method, the coil temperature can be controlled at the target temperature within 0.1 seconds, with fast response speed and high control stability. © 2024 Inderscience Enterprises Ltd.

引用

页码：86 / 104

页数：18

共 19 条

[1] An B., Li Y., Xiao H., Xie B., Wang P., Wang M., Et al., Magnetic-integrated multipulse rectifier transformer with a tight impedance equalizing strategy for power quality improvement of dc traction power supply system, IEEE Transactions on Industrial Electronics, 67, 8, pp. 6270-6279, (2020)
[2] Chen S.Y., Yang M.C., Nonlinear contour tracking of a voice coil motors-driven dual-axis positioning stage using fuzzy fractional PID control with variable orders, Mathematical Problems in Engineering, 2021, 4, pp. 1-14, (2021)
[3] Conker C., Baltacioglu M.K., Fuzzy self-adaptive PID control technique for driving HHO dry cell systems, International Journal of Hydrogen Energy, 45, 49, pp. 26059-26069, (2020)
[4] Gheisarnejad M., Khooban M.H., An intelligent non-integer PID controller-based deep reinforcement learning: implementation and experimental results, IEEE Transactions on Industrial Electronics, 68, 4, pp. 3609-3618, (2021)
[5] Guo Y.Y., Jiang Y.H., Guo R., Fang B., Zhao H.R., Wang X.F., Fuzzy control algorithm based on electronically controlled proportional variable pump, Ordnance Material Science and Engineering, 44, 6, pp. 103-106, (2021)
[6] Jin Y., Yang N., Xu X., Innovative induction heating technology based on transformer theory: inner heating of electrolyte solution via alternating magnetic field, Applied Thermal Engineering, 179, 2, pp. 115732-115741, (2020)
[7] Kant P., Singh B., A new three-phase to five-phase transformer with power quality improvement in hybrid-multilevel inverter based VCIMD, IEEE Transactions on Power Delivery, 35, 2, pp. 871-880, (2020)
[8] Li D.K., Liu D.H., Yong H.D., Ramping loss and mechanical response in a no-insulation high-temperature superconducting layer-wound coil and intra-layers no-insulation coil, Science China Technological Sciences, 65, 1, pp. 115-130, (2022)
[9] Liang H., Sang Z.K., Wu Y.Z., Zhang Y.H., Zhao R., High precision temperature control performance of a pid neural network-controlled heater under complex outdoor conditions, Applied Thermal Engineering, 195, 1, pp. 117234-11242, (2021)
[10] Luo X.M., Ruan J.J., Deng Y.Q., Duan C.H., Gong R.H., Liu X.Q., Transformer hot-spot temperature inversion based on multi-physics calculation and fuzzy neural network algorithm, High Voltage Engineering, 46, 3, pp. 860-866, (2020)

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