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A high switching frequency operation has been introduced with much interest in research and industrial areas to improve the power density of power converters. However, its implementation is difficult for an elaborate switch mode power supply which has...
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RISS 인기검색어
https://www.riss.kr/link?id=T13978876
- 저자
-
발행사항
울산 : Graduate School of UNIST, 2016
-
학위논문사항
Thesis(M.A.) -- Graduate School of UNIST , DepartmentOfElectricalEngineering Power Electronics , 2016. 2
-
발행연도
2016
-
작성언어
영어
- 주제어
-
발행국(도시)
울산
-
형태사항
54 p. ; 26 cm
-
일반주기명
지도교수: Jung, JeeHoon
-
소장기관
- 울산과학기술원
- 울산과학기술원
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
A high switching frequency operation has been introduced with much interest in research and industrial areas to improve the power density of power converters. However, its implementation is difficult for an elaborate switch mode power supply which has high efficiency and stable operation. In this paper, a power stage and a feedback controller design will be considered for proper operation, stability, and high power conversion efficiency of the high frequency LLC resonant converter. The power density can be improved by adopting high switching frequency which allows small sized passive components. At the high switching frequency, the size reduction of the passive components such as transformer, and output capacitor will be estimated to obtain the high power density design. In addition, the design method of the magnetizing inductance design method will be derived to achieve the zero voltage switching (ZVS) at the high switching frequency operation.
In aspect of frequency domain, the smaller output capacitor which has small capacitance and low effective series resistance (ESR) changes the small-signal behavior of the converter’s power stage. It can make the converter unstable by increasing the crossover frequency in the loop gain of the small-signal model. The effect of the smaller output capacitance should be analyzed for stability analysis using a proper small-signal model of the LLC resonant converter. Therefore, the proper design methods of the feedback compensator are derived to obtain sufficient phase margin in the bode plot of the converter’s loop gain for its stable operation. The design considerations of the power stage and the feedback loop will be verified with the performance comparison of 100 kHz and 500 kHz switching frequency LLC resonant converters.
Since the switching performance of state-of-art power switches has been improved, the power converter can operate over a 1 MHz switching frequency. In this paper, GaN E-HEMTs are used to achieve the high switching frequency operation due to its small channel resistance and small output capacitance. However, the GaN E-HEMTs also have different switching operation characteristics to other conventional silicon-based MOSFETs. Therefore, the high speed switching characteristics of the GaN E-HEMT should be analyzed to obtain proper operation for a half-bridge type LLC resonant converter using a boostrap gate drive circuit. Moreover, a soft start algorithm for the high switching frequency is analyzed to suppress inrush currents at the cold start operation of the converter. All the design considerations using the GaN E-HEMT are verified with a 240 W prototype LLC resonant converter operating at 1 MHz switching frequency.
In aspect of frequency domain, the smaller output capacitor which has small capacitance and low effective series resistance (ESR) changes the small-signal behavior of the converter’s power stage. It can make the converter unstable by increasing the crossover frequency in the loop gain of the small-signal model. The effect of the smaller output capacitance should be analyzed for stability analysis using a proper small-signal model of the LLC resonant converter. Therefore, the proper design methods of the feedback compensator are derived to obtain sufficient phase margin in the bode plot of the converter’s loop gain for its stable operation. The design considerations of the power stage and the feedback loop will be verified with the performance comparison of 100 kHz and 500 kHz switching frequency LLC resonant converters.
Since the switching performance of state-of-art power switches has been improved, the power converter can operate over a 1 MHz switching frequency. In this paper, GaN E-HEMTs are used to achieve the high switching frequency operation due to its small channel resistance and small output capacitance. However, the GaN E-HEMTs also have different switching operation characteristics to other conventional silicon-based MOSFETs. Therefore, the high speed switching characteristics of the GaN E-HEMT should be analyzed to obtain proper operation for a half-bridge type LLC resonant converter using a boostrap gate drive circuit. Moreover, a soft start algorithm for the high switching frequency is analyzed to suppress inrush currents at the cold start operation of the converter. All the design considerations using the GaN E-HEMT are verified with a 240 W prototype LLC resonant converter operating at 1 MHz switching frequency.
A high switching frequency operation has been introduced with much interest in research and industrial areas to improve the power density of power converters. However, its implementation is difficult for an elaborate switch mode power supply which has high efficiency and stable operation. In this paper, a power stage and a feedback controller design will be considered for proper operation, stability, and high power conversion efficiency of the high frequency LLC resonant converter. The power density can be improved by adopting high switching frequency which allows small sized passive components. At the high switching frequency, the size reduction of the passive components such as transformer, and output capacitor will be estimated to obtain the high power density design. In addition, the design method of the magnetizing inductance design method will be derived to achieve the zero voltage switching (ZVS) at the high switching frequency operation.
In aspect of frequency domain, the smaller output capacitor which has small capacitance and low effective series resistance (ESR) changes the small-signal behavior of the converter’s power stage. It can make the converter unstable by increasing the crossover frequency in the loop gain of the small-signal model. The effect of the smaller output capacitance should be analyzed for stability analysis using a proper small-signal model of the LLC resonant converter. Therefore, the proper design methods of the feedback compensator are derived to obtain sufficient phase margin in the bode plot of the converter’s loop gain for its stable operation. The design considerations of the power stage and the feedback loop will be verified with the performance comparison of 100 kHz and 500 kHz switching frequency LLC resonant converters.
Since the switching performance of state-of-art power switches has been improved, the power converter can operate over a 1 MHz switching frequency. In this paper, GaN E-HEMTs are used to achieve the high switching frequency operation due to its small channel resistance and small output capacitance. However, the GaN E-HEMTs also have different switching operation characteristics to other conventional silicon-based MOSFETs. Therefore, the high speed switching characteristics of the GaN E-HEMT should be analyzed to obtain proper operation for a half-bridge type LLC resonant converter using a boostrap gate drive circuit. Moreover, a soft start algorithm for the high switching frequency is analyzed to suppress inrush currents at the cold start operation of the converter. All the design considerations using the GaN E-HEMT are verified with a 240 W prototype LLC resonant converter operating at 1 MHz switching frequency.
목차 (Table of Contents)
- I. Introduction 12
- II. Design Considerations for High Power Density 14
- 2.1 Design for Soft Switching Condition 15
- 2.2 Design for Smaller Output Capacitance 16
- 2.3 Design for Smaller Transformer 18
- I. Introduction 12
- II. Design Considerations for High Power Density 14
- 2.1 Design for Soft Switching Condition 15
- 2.2 Design for Smaller Output Capacitance 16
- 2.3 Design for Smaller Transformer 18
- III. Feedback Control Loop Design 20
- 3.1 Instability of Power Converter and Derivation of Small-Signal Model 21
- 3.2 Design of the Feedback Compensator 28
- 3.3 Simulation and Experimental Results with 500 kHz LLC Resonant Converter 31
- IV. Peripheral Circuit Design and Control Strategy for High Switching Frequency 38
- 4.1 Side Effect of High Speed Switching 38
- 4.2 High Speed Switching Characteristics of GaN E-HEMT 40
- 4.3 Soft Start Algorithm for High Switching Frequency 42
- 4.4 Simulation and Experimental Results with 1 MHz LLC Resonant Converter 45
- V. Summary 50
- VI. Future Plan 51
- References 52
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