脉冲功率半导体器件及其在固态脉冲源的应用

Solid-state pulsed power semiconductor switch and the applications in high-power microwave solid-state pulse sources

  • 摘要: 高功率脉冲源作为定向能、先进雷达等系统的核心,其性能在很大程度上取决于脉冲功率开关的特性。传统的气体开关和真空开关虽功率容量大,但由于其存在着电极易烧蚀、延时抖动大、使用寿命短、重频低的问题,正逐步被具有长寿命、强可控和高重频等优势的半导体固态开关所取代。本文在系统阐述三类典型脉冲功率半导体器件的结构特征、原理及技术演进趋势的基础上,重点探讨了MOS栅控晶闸管(MOS-Controlled Thyristor,MCT)的技术路线相比于金属-氧化物半导体场效应晶体管(Metal-Oxide Semiconductor Field Effect Transistor,MOSFET)和绝缘栅双极型晶体管(Insulated Gate Bipolar Transistor,IGBT)此类电力电子器件在高功率固态脉冲源应用中的技术优势。进一步介绍了在HPM应用场景下MCT器件技术的挑战与攻关情况,并通过20 MW、30 MW和50 MW的固态脉冲功率模块研制实践验证了该技术路线在高功率百纳秒固态脉冲源的可行性,其高脉冲功率容量特征为装置的小型化与可靠性能够提供新的解决方案。

     

    Abstract: As the core components of systems such as directed energy and advanced radar, the performance of high-power pulse sources largely depends on the characteristics of pulsed power switches. Although traditional gas switches and vacuum tube switches offer high power capacity, due to their inherent drawbacks including electrode erosion, large timing jitter, short service life, and low repetition rate, they are replaced gradually by solid-state semiconductor switches, which offer advantages such as long lifetime, high stability, and high repetition frequency. This paper systematically elaborates on the structural characteristics, working mechanisms and technology evolution trends of three typical types of pulse power semiconductor devices, and then focuses on the technical route of MOS-gated thyristors. Compared with power electronic devices such as metal-oxide-semiconductor field-effect transistors and insulated-gate bipolar transistors, MOS-gated thyristors offer comprehensive advantages in high-power solid-state pulse source applications, delivering higher power capability while maintaining fast rise-time performance. Furthermore, it introduces the challenges and research progress of MCT device technology in HPM application scenarios. The feasibility of this technical route for high power 100-ns solid-state pulse sources is verified through the development and practical implementation of 20 MW, 30 MW, and 50 MW solid-state pulse power modules. The high consistency and large capacity characteristics of these modules provide new solutions for the miniaturization and reliability of such devices.

     

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