23 April 2024, Volume 43 Issue 4
    

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    Treatise and Report
  • Single-stage three phase harmonic current injectionstep-up/down AC/DC converter
    KAN Zhizhong, PAN Yi, NIU Xuqing, ZHANG Chunjiang
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 1-11. https://doi.org/10.12067/ATEEE2203005
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    A novel single-stage three phase harmonic current injection Step-up/down (STHSUD) AC/DC converter is proposed in this paper. This proposal integrates a three-phase uncontrolled rectifier bridge combined with a post-stage Cuk module, and the low-frequency bidirectional switch is introduced to provide a path for the converter to feed back the harmonic current, so that the purpose of reducing the harmonic content of input current is achieved. Firstly, the topology and operating principle of the proposed converter are analyzed, its equivalent circuit is established, the voltage transfer ratio of the converter is deduced, and combined with hysteresis tracking control, the closed-loop simulation of the proposed converter is performed to prove the buck-boost capability. The control strategy is simple, and input current can be sinusoidal with high power factor. Finally, the experiments are carried out in the TMS320F28335 DSP digital control platform, and the experimental results verify the feasibility of the proposed topology.
  • Dynamic equivalent model for system frequency response considering multiple induction motors
    TANG Zhen, MEI Mingyang, PAN Jie, MU Guoxing, YANG Hong, LIU Yu, ZHANG Zhihao, KOU Peng
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 12-19. https://doi.org/10.12067/ATEEE2306015
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    As more and more renewable energy resources are connected to the grid through power converters, the inertia of the power system is decreasing. At the same time, a large number of induction motors on the load side can provide frequency support and improve frequency response dynamics. However, accurate modeling of such a large number of induction motors requires detailed parameters and heavy computational cost. To address the limitation, a data-driven model for system frequency response is proposed. By collecting historical data of system frequency response, the identification of the equivalent inertia and damping coefficient of the power grid is described as an optimization problem. The objective is to minimize the frequency difference between the model and historical data。A heuristic algorithm is adopted to solve the problem efficiently. Compared with the mechanism model, the proposed dynamic equivalent model is structurally simple and does not require detailed parameters of induction motors. Simulations on a modified IEEE 9 bus system verify the effectiveness of the proposed method. The results also show that the induction motor load, which has a self-inertia of 15 seconds and accounts for 22% of the load side, provides 9% equivalent inertia to the system.
  • Two-stage optimal scheduling strategy for electric vehicles considering the priority demand
    CUI Mingyong, LYU Jing, XUE Sijia, CAO Peng
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 20-28. https://doi.org/10.12067/ATEEE2211003
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    As the penetration rate of photovoltaic power generation increases, the uncertainty of its output has negative impact on safe and stable operation of the power grid. By utilizing the mobile energy supply characteristics of electric vehicle (EV), the collaborative optimization between EV and photovoltaic can be realized. Taking the flexibility of EV energy scheduling into account, a two-stage optimal scheduling model for EVs considering user charging demand is constructed: in the day-ahead stage, a multi-objective optimization function with minimum situ absorption deviation of photovoltaic, maximum EV charging completion rate and minimum EV users travel cost is established, the charging and discharge coefficient is introduced to optimize the charging behavior of the EV; in real-time scheduling, the load aggregator combines the actual photovoltaic output of each period and the charging demand of the EV, modifies the optimized charging and discharging coefficients according to the scheduling priority to formulate an optimal charging and discharging strategy. By comprehensively considering the different needs of EV users for charging completion and charging cost, analyzing different charging modes and different weight coefficients, and considering the situation of users changing charging requirements, it is verified that the strategies proposed in this paper have obvious effects in reducing the deviation of photovoltaic absorption and meeting users’ charging needs.
  • A net-zero carbon emission day-ahead optimal scheduling method for isolated integrated energy system
    WU Chengjun, REN Zhouyang, LI Hui, JIANG Yunpeng, WANG Hao, YIN Yue
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 29-42. https://doi.org/10.12067/ATEEE2210030
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    In view of the carbon peaking and carbon neutralization goals, this paper proposes a net-zero carbon emission day-ahead optimal scheduling method for the isolated integrated energy system based on the hydrogen-carbon coupling, to address the self-sufficiency and low-carbon energy supply of the isolated integrated energy system (IIES). First, the amount of substance and energy balance principles is applied to analyze the cycle of different kinds of energy and carbon atoms. The net-zero carbon emission operating mechanism is proposed based on hydrogen and carbon. Then, a net-zero carbon emission day-ahead optimal scheduling model for IIES is established. The daily total cost of IIES is minimized in the optimization model, and the net-zero carbon emission mechanism, operation of power system and natural gas systems are considered by constraints. The model was transformed into a mixed integer linear programming problem. Finally, a simulation is implemented by using IEEE 39-NGS20 electric-gas interconnection system. The simulation results show that the proposed method achieves 100% self-sufficiency and net-zero carbon emission operation of the system, and significantly improves the economy of the day-ahead scheduling of the IIES.
  • An efficient reliability evaluation and weak link identification method for high-proportion new energy power system
    YANG Gaofeng, HU Wen, FANG Qin, TANG Lin, SHAO Changzheng, HE Haojie
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 43-52. https://doi.org/10.12067/ATEEE2302007
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    The increase in renewable energy penetration rate may induce the risk of power supply interruption and reduce the operation reliability of the power system. The traditional mid-long-term reliability evaluation method is challenging to meet the time requirement of operation reliability evaluation. This paper proposes an efficient evaluation algorithm for power system operation reliability, which reveals the analytical function relationship between the power system operation reliability index and uncertain factors such as wind power output. It avoids repeated reliability calculation when uncertain factors change. Firstly, the distribution characteristics of wind power output are modeled based on the hidden Markov model. Then, the analytical function between the reliability index and wind power output is established by the state enumeration-polynomial chaos expansion method. Finally, based on the analytical function, the efficient operational reliability evaluation and weak links identification of the new energy power system under real-time wind power output are realized. Taking the modified IEEE RTS79 system as an example, the effectiveness of the proposed method is verified.
  • All-scenario-feasible stochastic unit commitment model considering renewable energy integrated into system reserve
    LIU Yang , TENG Weijun, LI Zhaohui, ZHANG Ziyu, DING Tao
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 53-62. https://doi.org/10.12067/ATEEE2211014
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    The new power system with renewable energy generation as the main body has brought new challenges to the system dispatching. A stochastic unit commitment model considering wind power as the operating reserve is proposed to alleviate the reserve pressure brought by the integration of large-scale renewable energy. Firstly, the probability density estimation of wind power prediction error is obtained based on the kernel density method, and the wind power reserve model is established according to the best confidence level. Secondly, we propose an all-scenario-feasible dispatching model based on the vertex scenarios with variable uncertainty sets and introduce strong nonanticipative constraints to meet the nonanticipativity of economic dispatching. Finally, in the improved IEEE-24 bus system, the effectiveness of the proposed stochastic unit commitment model is verified by the actual data and is compared with the scenario-based two-stage stochastic optimization. The experimental results show that the proposed model has satisfactory performance, can overcome the defects of numerical scenarios and large computing scale in stochastic optimization, and effectively reduces calculating time.
  • Optimized capacity strategy for seawater pumped storage power stations considering regulation cost compensation
    ZHANG Binqiao, DUAN Jiru, LI Xianshan, LI Shichun, WAN Gang
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 63-75. https://doi.org/10.12067/ATEEE2310042
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    Effective integration of offshore wind energy is achievable by jointly operating offshore wind power and seawater pumping for grid regulation, contributing to grid stability. However, to address critical issues such as cost recovery for seawater pumping, a multi-objective optimization study on seawater pumping capacity is necessary. To this end, we propose a seawater pumping multi-objective optimization method that considers compensation for regulation costs. This approach utilizes a bidirectional compensation mechanism for seawater pumping regulation, ensuring equitable benefits. Accounting for wind power uncertainty, we establish a multi-objective optimization model for the joint operation of wind and storage. The model integrates interests from different stakeholders by minimizing tracking errors between the joint output of wind and storage and the grid load, maximizing operational benefits from offshore wind energy, and optimizing seawater pumping revenue.The optimization decision variables include bidirectional compensation prices, seawater pumping upper reservoir capacity, and seawater pumping unit capacity. We employ the NSGA-II method to obtain the Pareto front solutions, use the K-means algorithm to cluster the Pareto front solutions as alternative scenarios, and apply the Analytic Hierarchy Process-Entropy Weight Method for subjective and objective weighting. Finally, the TOPSIS method is used to compare and rank alternative scenarios against the ideal solution. Simulation results validate that the proposed seawater pumping optimization capacity scheme balances the effectiveness of new energy integration with the interests of multiple stakeholders.
  • Research on WPT sunken magnetic shielding system for electric vehicles with multiple parking spaces
    ZHANG Xueyi, REN Liquan, XIONG Xinbo, KONG Pengsheng, LI Zhongqi, YANG Minsheng
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 76-85. https://doi.org/10.12067/ATEEE2210032
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    In electric vehicle wireless power transfer systems, realizing efficient transmission while reducing magnetic leakage has been a technical challenge. To address this issue, the paper proposes a sunken shielding coil structure applied to a multi-radio wireless power transfer system, which reduces the magnetic leakage from the target surface without affecting the transmission efficiency of the system. Firstly, a method of calculating the magnetic field of a rectangular coil based on the vector magnetic potential is submitted, by which the magnetic leakage from the target surface of the system is analyzed, providing a theoretical basis for the subsequent magnetic leakage optimization; secondly, a method of magnetic leakage optimization is introduced, and each coil parameter meeting the requirements is obtained by applying the method, which provides a key support for the realization of high-efficiency wireless power transfer; lastly, a set of dual-sunken shielded coil structures with magnetic shielding structure is developed based on the coil parameters obtained; and lastly, a set of dual-sunken shielding coil structures with magnetic shielding structure applied to multiple wireless power transfer systems is developed based on the coil parameters obtained, which will not impact the system transmission efficiency. Finally, based on the obtained coil parameters, a dual-position electric vehicle wireless charging system with magnetic shielding structure is developed, and the effectiveness of the proposed shielding structure and method is fully confirmed through simulation and experiment. The results show that the proposed shielding structure not only reduces the maximum leakage magnetic field in the target area by 25% but also achieves a transmission efficiency of up to 95% when the output power of the system is constant at 4 kW.
  • Calculation method of thermal stability safety margin for overloaded transmission lines considering power variation
    ZHANG Liang, QIU Zhiqin, YU Li, PEI Zhikang, OUYANG Jinxin, WANG Wensong, PAN Haiping, SONG Tao
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 86-93. https://doi.org/10.12067/ATEEE2210005
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    With the increasing complexity of power grid interconnection, thermal stability has become the main factor limiting power transmission capacity. Especially in the case of transmission lines passing through loads, the existing methods ignore the dynamic thermal characteristics caused by line power changes, resulting in errors in the calculation of line thermal stability safety margin, which may lead to premature protection action and line removal, or even threaten the safe and stable operation of the entire power system. Therefore, the factors affecting the temperature rise of transmission lines are analyzed, and the sensitivity model between unit operation mode, power regulation and overload line power is established. Combined with the dynamic thermal balance equation of the line, a method for calculating the thermal stability safety margin of overload lines considering the power change is proposed. The numerical example in this paper shows that the method fully considers the influence of power variation of overloaded line on thermal stability, and can maximize the delay of protection action while ensuring the safe operation of transmission line, so as to reduce the scope of outage and chain fault.
  • A fast extraction of insulator strings of point cloud of power tower based on multi-view projection
    YANG Dongchen, HUANG Yuchun, OUYANG Ninghui
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 94-103. https://doi.org/10.12067/ATEEE2303061
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    In the automatic inspection of UAV, route planning should be carried out according to the position of insulator strings in the dot cloud of power corridor. Due to the large length span of the power corridor and the large number of poles and towers, it is a huge workload to manually mark the position of insulator string. At the same time, the point cloud data is scattered and disordered, and it takes a long time to locate insulator string directly in three-dimensional space. Therefore, this paper proposes a multi-view two-dimensional projection to rapidly extract insulator strings from three-dimensional pole and tower point clouds. Firstly, the robust principal component analysis was used to analyze the horizontal direction of the cross arm at the top of the tower in the top view, and the orientation of the point cloud of the tower was unified. Then, in the side view, the height of the power line is quickly located by Hoff line detection. According to the spatial relationship between the power line and the cross arm, the corresponding insulator strings are divided into three categories: Top suspension, vertical insulator string and horizontal insulator string. Finally, the corner detection is carried out in the multi-view projection, and the connection endpoint of the insulator string with the power line and the tower is located to realize the rapid extraction of the insulator string. The method proposed in this paper was used to extract 867 insulator strings from 97 different types of pylons in a 50 km power corridor. It is proved that the method can extract different types of insulator strings quickly.
  • Study on vibration characteristics of evaporative cooling rotor of vertical hydro-generator
    ZHU Kunpeng, LI Ruiwei, YANG Zhangbin, HOU Zhe,
    Advanced Technology of Electrical Engineering and Energy. 2024, 43(4): 104-112. https://doi.org/10.12067/ATEEE2308018
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    With the development of hydro-generators towards large capacity and high speed, higher requirements have been imposed on rotor cooling technology. Evaporative cooling technology is an efficient cooling method that relies on the heat absorption during the phase transition of the cooling medium. However, current evaporative cooling rotor schemes require a certain amount of liquid cooling medium to be stored on the rotor. In order to investigate the relationship between the liquid cooling medium on the evaporative cooling rotor and the rotor vibration characteristics, this paper preliminarily establishes a pipe-cooled evaporative cooling structure based on a prototype model of a vertical hydro-generator. The influence of evaporative cooling medium on the natural frequency of the rotor at different liquid level heights was studied. The results show that with the increase of liquid level height, the pressure of the cooling medium on the pipe wall gradually increases, and there is no significant effect on the natural frequency of the rotor itself. The work presented in this paper provides certain guidance for subsequent optimization of the evaporative cooling structure of rotors, as well as further research on the coupling relationship between liquid cooling medium and rotor vibration characteristics.
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