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基于智能线圈的碳化硅驱动器供电电机反射过电压抑制新方法
Mitigation of Motor Reflected Overvoltage Fed by SiC Drives—A New Solution Based on Smart Coils
| 作者 | Majid T. Fard · JiangBiao He · Lulu Wei · Reza Ilka · Behrooz Mirafzal · Fariba Fateh |
| 期刊 | IEEE Transactions on Power Electronics |
| 出版日期 | 2024年11月 |
| 技术分类 | 电动汽车驱动 |
| 技术标签 | 宽禁带半导体 SiC器件 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 宽禁带开关 电机定子过电压 智能线圈 过电压抑制 电机驱动系统 |
语言:
中文摘要
虽然宽带隙(WBG)开关彻底改变了电力电子和电机驱动系统,但与这些快速开关半导体相关的高 $dv/dt$ 很容易在电机定子端子上诱发反射高频过电压尖峰。在实际应用中,电压脉冲较短的上升时间限制了逆变器与电机之间的电缆长度,以避免电机定子绕组出现过电压。即便使用较短的电缆,变速驱动器产生的电压尖峰仍可能导致绝缘过早失效,并缩短电机的剩余使用寿命。虽然传统方法(如 $dv/dt$ 无源滤波器或有源栅极驱动器)有效,但通常体积庞大和/或效率低下。为解决这一问题,本文介绍了一种名为“智能线圈”的过电压抑制解决方案。智能线圈电路与每个电机相的第一个线圈并联安装,该线圈通常承受最高的反射过电压。当检测到过电压时,位于电机接线盒处的超紧凑型智能线圈电路被激活,以限制线圈上的电压应力。由于智能线圈与第一个线圈并联,它只需在过电压瞬变期间处理极低的脉冲功率。因此,它在有效抑制电压尖峰的同时,具有高效率和超小的占用空间。所提出的智能线圈电路可以轻松适用于各种电机驱动系统,而不受电缆长度或开关器件上升时间的影响。本文提供了仿真和实验测试结果,以验证所提出方法的有效性。
English Abstract
While wide bandgap (WBG) switches have revolutionized power electronics and motor-drive systems, the high dv/dt associated with these fast-switching semiconductors can easily induce reflected high-frequency overvoltage spikes on motor stator terminals. The shorter rise time of the voltage pulses confines the cable length between the inverter and the motor in practice to avoid overvoltage across the motor stator windings. Even with shorter cables, voltage spikes from variable-speed drives can still cause premature insulation failure and reduce the remaining useful lifetime of the motors. While effective, conventional methods such as dv/dt passive filters or active gate drivers are usually bulky and/or inefficient. To address this problem, an overvoltage mitigation solution, named “Smart Coil,” is introduced in this article. The smart coil circuit is installed in parallel with the first coil of each motor phase, which typically experiences the highest reflected overvoltage. Upon detection of overvoltage, the proposed ultracompact smart coil circuit, located at the motor junction box, is activated to limit voltage stress across the coils. Since the smart coil is connected in parallel with the first coil, it only needs to process very low pulsed power during the overvoltage transients. Therefore, it has high efficiency and an ultracompact footprint while effectively mitigating voltage spikes. The proposed smart coil circuit can be easily scaled for various motor-drive systems regardless of the cable length or rise time of the switching devices. Simulation and experimental test results are provided to verify the effectiveness of the proposed method.
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SunView 深度解读
从阳光电源的业务视角来看,这项基于"智能线圈"的电机反射过电压抑制技术具有重要的战略价值。随着公司在光伏逆变器、储能变流器及电动汽车驱动系统中大规模采用SiC等宽禁带半导体器件,快速开关带来的高dv/dt问题已成为制约系统性能和可靠性的关键瓶颈。
该技术的核心价值在于其创新的拓扑结构和部署方式。传统的dv/dt滤波器通常安装在逆变器侧,体积大、损耗高,这与阳光电源追求高功率密度和高效率的产品理念相悖。而智能线圈方案安装在电机接线盒处,仅在过电压瞬态时处理极低的脉冲功率,实现了超紧凑设计和高效率的完美平衡。这对于阳光电源的工商业储能系统和大型光伏电站中的水泵、风机等辅助驱动系统尤为适用。
从应用前景看,该技术具有良好的可扩展性,不受电缆长度和开关速度限制,这与阳光电源多样化的应用场景高度契合。特别是在海上风电、大型地面电站等长电缆场景下,能有效延长电机绝缘寿命,降低运维成本。此外,该方案还可能应用于公司正在拓展的电动汽车动力总成业务,提升驱动系统的可靠性。
技术挑战主要集中在过电压检测的精确性和响应速度上,以及在不同工况下的自适应控制策略。建议阳光电源关注该技术的专利布局,评估与现有逆变器产品的集成可行性,并考虑在新一代SiC驱动平台上进行预研验证,为未来产品差异化竞争建立技术储备。