통합 검색
통합 검색
These technologies play a critical role in CNC machine tools, industrial robot actuators, and high-speed spindle drivers, and are essential in manufacturing environments where high-speed rotation and precise control are required simultaneously. For example, in CNC lathes or milling machines, the accurate speed and position control of the rotating axis directly impacts machining quality—something that is difficult to achieve without high-performance, inverter-based vector control technology. PCLab. implements various control algorithms tailored to real industrial demands and verifies their effectiveness through hardware prototyping using self-designed control boards and power circuits. Furthermore, we focus on developing customized control software based on different motor characteristics and system requirements, enabling the realization of high-efficiency, high-precision, and highly reliable drive systems. |
AC microgrids are designed not only to supply electricity, but also to operate in coordination with the main utility grid and switch to islanded operation when necessary. This utility-interactive microgrid structure enables autonomous power supply even during grid outages, making it highly effective in applications that demand energy resilience, such as hospitals, campuses, and local communities. Furthermore, in high-efficiency energy systems like Zero Energy Buildings (ZEBs) and smart factories, integrated control of on-site generators and battery storage allows for optimized energy consumption and enhances both autonomy and efficiency in power usage. Our laboratory develops control algorithms that manage the operation and coordination of various components within AC microgrid systems, tailored to different power environments and application needs. Based on these algorithms, we design and build custom control boards and power circuits, and conduct full experimental validation to verify system performance and reliability. |
This technology enables high-efficiency power management in various applications such as industrial power systems, electric vehicles, energy storage systems (ESS), home appliances, and smart buildings. Its importance is particularly evident in environments where precise power control is required to accommodate diverse power sources and load characteristics. PCLab aims to enhance the performance and reliability of such power electronic systems by directly designing high-efficiency power conversion circuits and control algorithms, and by conducting validation experiments in a variety of real-world applications. In addition, we are developing power electronic interface technologies optimized for hybrid power environments—including solar and wind energy sources—to contribute to the realization of sustainable energy systems. |
