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具有短路容错能力的五电平主动电磁轴承开关功率放大器OA

Five-Level Switching Power Amplifier for Active Magnetic Bearings with Short-Circuit Fault-Tolerance

中文摘要英文摘要

功率放大器是主动电磁轴承系统的核心执行部件.在满足带宽的前提下,较低的输入电压可以降低电磁干扰和开关损耗.传统的功率放大器输入电压固定,在面对不同转速及带宽要求时缺乏灵活性;此外,电路中的开关管长期高频动作易引发短路故障,严重制约系统的可靠性.该文首先提出一种新的具有短路容错能力的五电平开关功率放大器拓扑结构,该功率放大器拓扑可以输出 0、±1/2Vdc和±Vdc五个电平,并根据跟踪误差在低压状态及高压状态下自动切换,从而减小功耗,降低电磁干扰.其次,基于该拓扑结构,提出了一种基于二极管电流检测的容错策略,实现了对开关功率放大器单个短路故障开关管的容错控制.以开关管关断时负载电流是否流经其所在桥臂中的二极管作为故障判断条件,控制器根据不同开关管的短路故障快速切换到相应的容错模式.最后,实验验证了所提具有短路容错能力的五电平开关功率放大器拓扑结构的合理性和可行性,以及对开关管短路故障的容错控制能力.

The power amplifier constitutes the critical actuating element in active magnetic bearings(AMBs).While elevating input voltage enhances dynamic response characteristics,this approach introduces significant operational challenges.High-voltage operation induces excessive voltage stress on power switching devices,escalates switching losses,and generates substantial electromagnetic interference(EMI)during circuit operation.A fundamental constraint of conventional three-level configurations is their fixed input voltage maintenance,regardless of tracking error magnitude,which leads to aggravated circuit stress conditions.Furthermore,the power switching devices exhibit particular vulnerability under combined high-voltage,high-current,and high-frequency switching conditions,potentially compromising AMBs'operational safety.Switching device failures generally manifest as either open-circuit or short-circuit modes.Compared to open-circuit failures,short-circuit faults present more severe consequences.Effective fault-tolerant strategies must therefore integrate rapid detection mechanisms with responsive protection measures to mitigate overcurrent risks in load coils during short-circuit events. Firstly,this paper introduces the operational principle of a five-level power amplifier topology,guided by the design philosophy of"high voltage for large errors,low voltage for small errors".The analysis demonstrates that under high dynamic response requirements,the five-level switching power amplifier circuit operates at a high voltage level while maintaining dynamic response capabilities equivalent to those of three-level ones.Conversely,under low dynamic response requirements,the five-level switching power amplifier circuit switches to a low-voltage level,where its input voltage is reduced to half that of conventional amplifiers.This voltage reduction halves the voltage stress on power electronic devices.Accordingly,voltage breakdown risks are mitigated,and the switching loss and electromagnetic noise in the circuit are reduced.Furthermore,a control strategy is presented for five-level operation,defining three distinct operational modes:low-voltage,transitional,and high-voltage.Through analytical derivation,we establish the critical current frequency governing inter-mode transitions and map the operating modes of five-level switching amplifiers across different AMBs speed ranges. This paper then presents a fault-tolerant strategy for switch device short-circuit conditions in respective bridge arms of a five-level switching power amplifier topology.Furthermore,a diagnostic method is proposed through real-time monitoring of current flow in bridge arm freewheeling diodes and verification against predefined logical relationships with switching states.The implemented fault-tolerant strategy allows for a seamless transition between normal and fault-tolerant operation modes through controller parameter adjustments,completing mode switching within a single switching cycle. Finally,the experimental results verify that the five-level switching power amplifier successfully tracks reference currents at different frequencies and maintains preset operational states.Compared with three-level switching power amplifiers,the five-level configuration demonstrates superior operational performance.When short-circuit faults occur in switching devices,the five-level switching power amplifier rapidly transitions to fault-tolerant states while maintaining continuous operation.

刘紫怡;李翁衡;祝长生

浙江大学电气工程学院 杭州 310027浙江大学电气工程学院 杭州 310027浙江大学电气工程学院 杭州 310027

机械制造

主动电磁轴承开关功率放大器短路故障容错控制

Active magnetic bearingsswitching power amplifiershort-circuit faultfault-tolerant control

《电工技术学报》 2026 (4)

1195-1209,15

太行国家实验室课题(A2063)和国家基础科研计划(2022-ZD-232,2019110C026)资助项目.

10.19595/j.cnki.1000-6753.tces.250234

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