Your search keyword '"Song, Seung-Ho"' showing total 5 results

1. Current-Loop Gate-Driving Circuit for Solid-State Marx Modulator With Fast-Rising Nanosecond Pulses.

Author

Lee, Seung-Hee, Song, Seung-Ho, and Ryoo, Hong-Je

Subjects

*BIPOLAR transistors, *LOGIC circuits, *SYNCHRONIZATION, *SOLID-state fermentation, *ELECTRIC inductance, *PHOTOPLETHYSMOGRAPHY, *MOTOR vehicle driving

Abstract

When designing solid-state Marx modulators (SSMMs) with fast-rising nanosecond pulses, the gate-driving scheme for pulse discharge switches is one of the most important aspects to be considered. In this article, we propose a nanosecond current-loop gate-driving circuit for a synchronized fast gate drive of pulse discharge switches. The proposed circuit comprises an inverter, a current-loop cable, and discharge switch drivers. The inverter generates bipolar pulses that simultaneously provide driving power and fast triggering signals to all discharge switch drivers through the cable. The triggered discharge switch drivers rapidly turn on/off all discharge switches with accurate synchronization. In the inverter and discharge switch drivers, the fast gate-driving methods were used to overcome parasitic inductances and realize nanosecond operation. The concept and operational principles of the proposed gate-driving scheme are presented. To validate the performance and reliability of the SSMM using the proposed current-loop gate-driving circuit, a laboratory test on a 10-kV–70-A–50-kHz SSMM prototype was conducted, and the results were discussed. [ABSTRACT FROM AUTHOR]

Published

2021

2. Solid-State Pulsed Power Modulator for 9.3 GHz 1.7 MW X-Band Magnetron.

Author

Park, Su-Mi, Song, Seung-Ho, Jo, Hyun-Bin, Jeong, Woo-Cheol, Jang, Sung-Roc, and Ryoo, Hong-Je

Subjects

*MAGNETRONS, *MAGNETRON sputtering, *INSULATED gate bipolar transistors, *PULSE generators, *PULSE circuits, *LINEAR accelerators, *LINE drivers (Integrated circuits)

Abstract

This article describes a modification and an experiment conducted on a solid-state pulsed power modulator (SSPPM) for medical linear particle accelerator (LINAC) applications. Depending on the operating condition of the magnetron, an existing design of an insulated-gate bipolar transistor (IGBT)-based modulator is modified, from a positive pulse generator to a negative pulse generator. The design of the gate driver circuit of the pulse discharging IGBTs is also slightly changed to secure reliability against the arc condition. The developed modulator has the following maximum output—pulse voltage of −40 kV, pulse current of −100 A, pulsewidth of 5 μs, and pulse repetition rate of 250 Hz. By adapting the proposed design to the pulsed power modulator for driving the magnetron, high peak and average power densities of 43 kW/L and 48.9 W/L, respectively, can be achieved. The experimental results from various tests conducted using a resistor load, including a rated operation and an arc protection, verify the robustness and utility of the developed SSPPM for medical LINAC applications. An experiment using a 9.3-GHz 1.7-MW X-band magnetron is also conducted. The developed modulator achieved a successful arc protection operation for the arc generated in the waveguide during the magnetron drive test. [ABSTRACT FROM AUTHOR]

Published

2021

3. Study on the High-Voltage Solid-State Pulsed-Power Modulator for Parallel Reactor Operation.

Author

Song, Seung-Ho, Jo, Hyun-Bin, and Ryoo, Hong-Je

Subjects

*INSULATED gate bipolar transistors, *FUSION reactors, *TRANSISTORS, *HIGH voltages, *POWER density

Abstract

This paper describes a study on the high-voltage compact solid-state pulsed-power modulator for parallel reactor operation. The current capacity of the pulsed modulator has been improved to drive multiple reactors in parallel. The pulse discharge switch uses the IXYK120N120C3 (1200 V/120 A) insulated-gate bipolar transistor for a high current output. The gate driver has been improved according to the characteristics of the replaced switch. The output specifications of the modified pulsed-power modulator are a maximum output voltage of 40 kV, a maximum output current of 300 A, a pulsewidth ranging from 1.5 to $5~\mu \text{s}$ , a maximum repetition rate of 3 kHz, and an average power of 13 kW. The modulator has the dimensions of $450 \times 475 \times 600$ mm3, a maximum peak power of 12 MW, and a maximum power density of 93 kW/L. A resistive load experiment and a plasma reactor parallel drive test were performed. Four parallel reactors were driven using one modulator. In addition, a 50% reduction in the concentration of toluene was obtained through the experiment of the toluene gas treatment using only parallel plasma reactors. [ABSTRACT FROM AUTHOR]

Published

2019

4. Solid-State Bipolar Pulsed-Power Modulator Based on a Half-Bridge Power Cell Structure.

Author

Lee, Seung-Hee, Song, Seung-Ho, Jo, Hyun-Bin, and Ryoo, Hong-Je

Subjects

*INSULATED gate bipolar transistors, *CELL anatomy, *BRIDGES, *ELECTRONIC modulators, *POWER series, *SOLID state electronics

Abstract

This paper addresses the design of a solid-state bipolar pulsed-power modulator based on a series of stacked power cells that realize a simple and robust structure. Each cell is charged in parallel by an LCC resonant converter independently of the discharging loop. A passive cell-balancing design is implemented. The power cell using insulated gate bipolar transistors (IGBTs) can operate in bypass mode without an additional component, and the circuit operation was analyzed. A simple gate driving method, which provides synchronized gate signals without an extra power source of each gate driver using two control loops and isolation transformers, is implemented for the proposed bipolar pulsed-power modulator based on stacked cells. Moreover, an unexpected gate turn-on problem was solved by an additional off signal. To validate the proposed structure and the gate driving scheme, a three-cell, 1.2-kV, 110-A, 1.5- to 4- $\mu \text{s}$ , 3-kHz laboratory experimental prototype test was conducted. The results proved the reliability of the proposed solid-state bipolar pulsed-power modulator. [ABSTRACT FROM AUTHOR]

Published

2019

5. A Low Cost, Fast-Rising, High-Voltage Pulsed Power Modulator Based on a Discontinuous Conduction Mode Flyback Converter.

Author

Liu, Chang-Yu, Cho, Chan-Gi, Song, Seung-Ho, and Ryoo, Hong-Je

Subjects

*WATER-gas, *PULSE generators, *WATER purification, *PLASMA gases, *PULSED power systems, *CASCADE converters

Abstract

Treatment of gas and water for environmental applications requires a high-voltage, fast-rising pulse to act on the plasma gas or water treating reactor, but the existing stacked high-voltage pulse generator is arduous to use owing to its large size, high cost, and relatively slow pulse rise time. In this study, we propose a low-cost, small-volume pulsed power modulator that can significantly reduce the cost and volume of the device and shorten the pulse rise time to meet the requirements of gas and water treatment. The proposed pulsed power modulator is based on a discontinuous conduction mode (DCM) flyback converter, and it generates a high-voltage pulse through the resonance of the flyback transformer secondary side inductance and the parallel capacitor. A straightforward spark gap sharpens the generated high-voltage pulse. Finally, a fast-rising, high-voltage pulse with a narrow pulsewidth run on the load is generated. Through PSIM simulation and actual experiments, we validated the feasibility of the proposed pulse generator and obtained 23 kV, 500-Hz pulses with a width of 0.5- $\mu \text{s}$ width and rise time of 5 ns in actual experiments. [ABSTRACT FROM AUTHOR]

Published

2020