23 June 2025, Volume 44 Issue 6
    

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    Treatise and Report
  • YAN Yan, ZHANG Siyi, LI Chen, WU Jiaqi, SHI Tingna
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 1-14. https://doi.org/10.12067/ATEEE2312063
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    Open-circuit faults in gate drivers are typical failures of power devices, and accurate diagnosis of such faults can help improve the operational reliability of power electronic converters. Aiming at the deficiencies of existing fault diagnosis methods, a novel inverter power device gate driver open-circuit fault diagnosis method based on a DenseNet-ViT network is proposed: Firstly, normalization and augmentation processing are performed on sampled data to form three types of datasets: training set, validation set, and test set. Secondly, a DenseNet-ViT model is constructed to achieve enhanced extraction of fault features, and the model is trained using fault data. Finally, the validation set is used to conduct model testing, selecting the best-performing model. This method was applied to a three-level NPC inverter, detailing its modulation principle and the modeling process of the fault diagnosis model for this specific power converter topology, explaining the stochastic gradient descent function used in the model training process, and setting up an experimental platform for verification. Experimental results show that compared with other mainstream diagnostic methods, the proposed method has certain advantages in terms of floating-point computations, model parameters, and algorithm runtime.
  • SUN Huaze, LIU Chunxi, HONG Fangrui, XU Jinrong
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 15-23. https://doi.org/10.12067/ATEEE2405015
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    This paper introduces a deadbeat robust predictive control method for midpoint clamped inverters, which addresses the issues of low control accuracy and high common mode voltage caused by inductance parameter mismatch and virtual space vector pulse width modulation. Firstly, the method eliminates the resonance problem arising from LCL type filters through active damping methods. Secondly, the method designs a reduced order extended state observer that can compensate disturbances in the system. Finally, it redefines virtual voltage space vector pulse width modulation by ignoring positive small vectors and utilizing negative small vectors and medium vectors. The experimental results demonstrate that this method enhances system robustness and suppresses common mode voltage.
  • MENG Xianhui, ZHANG Chunjiang, ZHAO Ce, GUO Zhongnan, KAN Zhizhong
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 24-34. https://doi.org/10.12067/ATEEE2405003
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    In order to improve the transmission efficiency of boost push-pull bidirectional DC/DC converter, this paper analyzes the working characteristics of the converter and deduces the operating range with the highest efficiency. Firstly, according to the relationship between the duty cycle of the driving signal and the shift phase in the working process of the system, 12 working modes of the converter are proposed, and the effective value of the transmission inductance current, power transmission characteristics, return power characteristics and soft switching characteristics of each mode are analyzed in detail. Secondly, according to the relationship between the driving signal duty cycle D and the primary and secondary phase shift angle φ, the working range of the converter which can realize soft switching and no return power operation in the full load range is deduced, so that the transmission efficiency of the system can be optimized. Finally, an experimental platform is built to verify the correctness of the conclusions, which provides a theoretical basis for the design of circuit parameters and control parameters of boost push-pull bidirectional DC/DC converter.
  • XU Yang, LI Mingxue, YU Dongsheng
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 35-44. https://doi.org/10.12067/ATEEE2404032
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    Modular Dual Active Bridge (DAB) DC/DC converters have the advantages of fast response, electrical isolation, and high-power density, making them the core device for voltage regulation in DC distribution systems. The communication between different nodes is the key to ensuring the reliable operation of the DC distribution network system. This paper proposes a synchronous transmission communication method of power and signal based on symmetrical phase shift modulation of power switches. By switching a group of symmetrical shift comparison of power switch under the same transmission power, the harmonic phase of output voltage changes according to a certain rule, so that the ripple signal of specific phase is embedded into the bus voltage on the output side, and the ripple signal is used as the data carrier to realize the synchronous transmission of power and signal. At the same time, the equivalent signal expression of symmetric phase-shift modulation ripple was analyzed, and the corresponding data demodulation criteria were derived. The experiment verified the effectiveness of the proposed power switch symmetric phase shift modulation communication strategy for synchronous transmission of electrical energy and signals.
  • SHANG Yatao, LIU Shijie, XUE Ming, LI Longnyu, ZHU Gaojia
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 45-54. https://doi.org/10.12067/ATEEE2403008
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    With the increase in the power density of the permanent magnet synchronous motor, the rational design of its cooling structure to restrain the temperature rise has become the key point of motor design. In this paper, a 2.1 kW, 3 600 r/min permanent magnet synchronous motor is taken as the object, based on fluid mechanics and heat transfer theory, a three-dimensional fluid-structure conjugate heat transfer model is established, and the fluid flow and temperature rise distribution inside the motor are studied by using the finite volume method. In order to solve the problem of heat dissipation of the permanent magnet, a completely enclosed self-circulation cooling system with multiple spiral ventilation holes in the rotor axis is proposed. The spiral vent rotates synchronously with the rotor, and its pipe wall can be regarded as an axial-flow fan driving cooling air to form a cycle. According to the self-circulating air cooling structure, the influence of different spiral hole circumferential cross Angles on heat dissipation performance was analyzed, and the fully enclosed self-circulating cooling scheme was designed. The research work in this paper can provide some reference value for improving the heat dissipation performance of permanent magnet synchronous motors.
  • WU Shuangxi, ZHANG Yang, LIU Yang, GUI Rui, LI Jiapeng, LI Yujun
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 55-63. https://doi.org/10.12067/ATEEE2309024
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    Large-scale wind power grid-connection makes permanent magnet synchronous wind turbine (PMSG) to be widely used, but PMSG wind power grid-connection has shafting oscillation problem, and long time shafting oscillation will not only shorten the life of shafting but will also cause harm to the stability of power grid. Therefore, the mathematical model of PMSG grid-connected wind power system is established, the analytical expression of system damping torque is derived by damping torque analysis (DTA), the influence of different parameters on shafting oscillation damping is analyzed, and the active power additional damping control strategy is designed based on grid-connected converter. The correctness of the proposed method is verified by Matlab/Simulink simulation.
  • SUN Xinglong, JIN Xuefeng, LI Chen
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 64-73. https://doi.org/10.12067/ATEEE2410027
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    In response to the problems of low detection accuracy and high noise in existing sensorless control methods for low-speed operation of brushless DC motors, this paper proposes a low-speed sensorless control method for brushless DC motors based on Buck Boost converter and high-frequency signal coupling injection. This method utilizes an external high-frequency signal source to emit a low-voltage high-frequency detection signal, which is simultaneously injected into the motor winding through a coupling circuit and the driving voltage output by the inverter. The rotor position is determined by collecting the high-frequency voltage information feedback from the motor winding. The method proposed in this article has a simple algorithm, which can improve the position detection accuracy of the motor during low-speed operation and reduce the motor noise caused by detection pulses. The experimental results have verified the feasibility of the method.
  • CHEN Yating, XIONG Bin
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 74-82. https://doi.org/10.12067/ATEEE2407063
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    Faced with the challenge that it is difficult to monitor the transient temperature inside the stator winding in real time when the motor is overloaded for a short time, a key problem is to be solved urgently to clarify the influence of winding temperature characteristics and winding insulation on transient temperature measurement. In this paper, aiming at the problem that the poor thermal conductivity of the stator winding insulation layer of the motor leads to the hysteresis of the transient temperature measurement, a scheme of simulating the internal temperature rise of the stator winding of the motor by the heat transfer model of the winding in the slot is designed. The equivalent material parameters of the winding paint film and the impregnating paint are calculated and simulated. The temperature distribution characteristics and the hysteresis of the temperature measurement outside the insulation of the winding in the long slot are explored when different currents are applied, and the temperature characteristics and variation rules are verified by experiments. The simulation and experimental results show that when the motor is running, the internal temperature distribution of the winding insulation in the slot is uniform, and the temperature of each measuring point is similar. When loading different currents for the same duration, the temperature measurement lag time outside the winding insulation is the same ; studies have shown that the heat conduction rate can be increased and the lag time of temperature measurement can be reduced by selecting insulating materials with high thermal conductivity, low density and low specific heat capacity. This study provides a basis for the evaluation of the transient temperature measurement data of the winding in the stator slot of the motor, and also provides a reference for the transient temperature prediction when the motor is overloaded.
  • XIANG Enxin, ZHENG Jiayang, NIE Yongjie, WANG Ke, QIU Yangxin, SHI Xuntao, KE Qingpai, JI Shiqi
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 83-91. https://doi.org/10.12067/ATEEE2407032
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    On-load tap-changing transformers are widely applied in traditional distribution networks. However, issues such as limited regulation times, discontinuous voltage regulation, and the generation of arcs by mechanical taps impact the stable operation of power systems. Based on the principle of controlling magnetic saturation through DC magnetic flux, a novel structure of a controllable magnetically saturated magneto-controlled transformer is proposed. This structure achieves stepless voltage regulation by adjusting the equivalent leakage inductance and magnetizing inductance on the primary side. A linear magnetic circuit and circuit model of the controllable magnetically saturated magneto-controlled transformer are established, and the equivalent voltage regulation circuit is derived. The voltage regulation mechanism is analyzed, and a quantitative description of the voltage regulation range is obtained. A Simulink simulation model of the magneto-controlled transformer is built to analyze the changes in magnetic flux, voltage waveforms, and overall voltage regulation range under different operating conditions. The feasibility of DC magnetic flux-controlled voltage regulation is validated through experiments with a small-capacity prototype, demonstrating the practicality of this approach.
  • LI Yingqi, LI Lin
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 92-100. https://doi.org/10.12067/ATEEE2406002
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    The finite element simulation calculation cost of transient eddy current problems in high-frequency motors and electromagnetic devices is extremely high. The use of finite element model reduction method is a simplified calculation method that can improve computational efficiency. The Cauer trapezoidal network method, as a recently developed model reduction method, can generate equivalent circuits for eddy current problems over a wide frequency range and can be used as a powerful tool for simulating and calculating eddy current fields. Compared with the traditional Cauer trapezoidal network method that uses finite element software to calculate magnetic vector potential, this paper combines the finite difference method with Cauer trapezoidal network theory to directly solve it, which can further reduce the computational cost. By solving the two-dimensional eddy current problem model of parallel double conductors, the quasi-static electromagnetic field is represented as a weighted sum of a series of static electric and magnetic fields, achieving model reduction and simplified calculation. The results show that the maximum error between the simulation results of the proposed method and the finite element calculation results for the resistance parameters does not exceed 2.39%, and the maximum error for the inductance parameters does not exceed 4.24%. The computational efficiency is partially improved as compared to the traditional finite element method, indicating the effectiveness of this method.
  • TENG Junsheng, LIANG Quan, LI Weixin, HUANG Xinyu
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 101-111. https://doi.org/10.12067/ATEEE2312057
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    Microgrids have the potential to reduce fossil energy utilization and mitigate environmental pollution. However, due to the stochastic and fluctuating nature of microgrids, as well as challenges in managing distributed power sources, energy waste may occur. To address this issue, this paper establishes a model for microgrid operation under grid-connected mode. Initially, constraints of various distributed power sources in the system are comprehensively considered. Penalty costs for distributed power sources and load shedding are introduced. The objective functions, including microgrid operational cost, pollutant treatment cost, and load shedding penalty cost, are integrated. An improved version of the Growth Optimization (GO) algorithm is proposed. Simulation results demonstrate that the enhanced GO algorithm can effectively reduce the overall operational cost of microgrids.
  • New Technolog Application
  • HUANG Jinhua, LI Zhiyong, ZHENG Xiaoguang, ZHAO Wei, ZHOU Zhiyi, LI Gengfeng
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 112-119. https://doi.org/10.12067/ATEEE2311004
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    Frequent extreme events have caused severe impacts on the distribution network, so it is essential to improve the quick recovery ability of the distribution network under extreme events. Multi soft open point integrated with energy storage system (E-MSOP) refers to a multi-port interconnected power conversion storage device deeply coupled by the traditional soft open point and the energy storage system, which can realize the energy exchange and power support among feeders during the fault recovery process, so as to improve the rapid recovery capability of the distribution network effectively. Aiming at the power supply restoration of distribution networks under extreme natural disasters, this paper proposes a strategy based on traditional network reconfiguration and E-MSOP. Firstly, the mathematical model of E-MSOP with four ports is constructed. Secondly, a load recovery strategy based on E-MSOP and network reconfiguration is proposed. Second-order cone programming is used to solve the mixed integer programming problem. Finally, the proposed strategy is tested in the IEEE-33 bus system, and the results show that it can improve the power flow distribution and power supply after disasters.
  • YANG Yihu, LIU Yinkang, XIANG Enxin, DUAN Shengjiang, WANG Ke, CHEN Wenliang, YANG Jinpei, REN Ming
    Advanced Technology of Electrical Engineering and Energy. 2025, 44(6): 120-128. https://doi.org/10.12067/ATEEE2402021
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    Partial discharge (PD) is the primary cause of insulation degradation in power equipment, and it is significant for fault diagnosis and maintenance to identify the stage of PD accurately. In this paper, a PD trace monitoring method based on solar-blind ultraviolet phase characteristics is proposed. Firstly, the experimental platform for PD of typical insulation defects is constructed, and optical sensor with spectral response located in the solar-blind ultraviolet band is used to collect the PD optical signal. Then, the PD process before breakdown is divided into different stages by analysing the growth trend of the frequency of positive and negative polarity pulses with the voltage class, and the characteristics of the PD phase distribution in each stage are analysed. Finally, the dataset is constructed based on phase resolved partial discharge pattern, and the developmental stages under different discharge types are traced with the back propagation neural network and support vector machine. The results show that the phase distribution of light pulses in different stages varies significantly, and the stage tracing of the backpropagation neural network model is more effective, with an accuracy of up to 98.8% for floating discharges.