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Soft-Switching Technology for Three-phase Power Electronics Converters. Rui Li
Читать онлайн.Название Soft-Switching Technology for Three-phase Power Electronics Converters
Год выпуска 0
isbn 9781119602552
Автор произведения Rui Li
Жанр Физика
Издательство John Wiley & Sons Limited
4 Chapter 4Figure 4.1 Circuit topology of the CAC rectifier.Figure 4.2 Vector representation in complex plane with αβ coordina...Figure 4.3 Topology of the three‐phase converter.Figure 4.4 Sectors and voltage vectors in space complex plane.Figure 4.5 Two kinds of space vector sequences. (a) Symmetrical voltage vect...Figure 4.6 Switching commutation process of a leg in three‐phase rectifier. ...Figure 4.7 Driving logic and key waveforms of a leg in three‐phase converter...Figure 4.8 The voltage and current waveforms in a utility cycle.Figure 4.9 Sectors in space vector diagram.Figure 4.10 The dendrogram analysis of switching commutation sequences betwe...Figure 4.11 Three kinds of space vector sequences with one Type 2 commutatio...Figure 4.12 Switching state of the CAC circuit: (a) S7's on‐state; (b) S7's ...Figure 4.13 Switch commutation processes of CAC rectifier in sector 1‐1. (a)...Figure 4.14 Key waveforms in sector 1‐1.Figure 4.15 Driving logic and key waveforms in sector 1‐1.Figure 4.16 Equivalent circuit of stage 1: the initial stage.Figure 4.17 Equivalent circuit of stage 2: the first resonance stage.Figure 4.18 Equivalent circuit of stage 3: the freewheeling stage.Figure 4.19 Equivalent circuit of stage 4: the second resonance stage.Figure 4.20 Equivalent circuit of stage 5: the second steady stage.Figure 4.21 Equivalent circuit of stage 6: the Type 1 commutation stage.Figure 4.22 Equivalent circuit of stage 7: the third steady stage.Figure 4.23 Equivalent circuit of stage 8: the Type 1 commutation stage.Figure 4.24 Resonance circuit and its equivalent circuit of stage 2 (t1–t2):...Figure 4.25 Equivalent circuit of stage 4 (t3–t4): (a) circuit state of the ...Figure 4.26 Gate signal derivation in sector 1‐1.Figure 4.27 Control block diagram of the rectifier.Figure 4.28 Topology of the CAC rectifier.Figure 4.29 λ 7 versus Zr.Figure 4.30 i res /Im versus resonant impedance Zr.Figure 4.31 Resonant impedance Zr versus resonant parameters.Figure 4.32 CM200DU‐24NFH IGBT turn‐off loss under ZVS conditions.Figure 4.33 Recommended resonant parameters area.Figure 4.34 The 40 kW ZVS rectifier prototype.Figure 4.35 Bus bar and structure 40 kW ZVS rectifier prototype.Figure 4.36 Output current and grid voltageFigure 4.37 Voltage and current waveforms of the bridge switch.Figure 4.38 Voltage and current waveforms of the bridge switch’s antiparalle...Figure 4.39 Voltage and current waveforms of the auxiliary switch.Figure 4.40 Voltage across Ccl and current through Lr.Figure 4.41 Voltage and current waveforms of the bridge switch S1 in a line ...Figure 4.42 Measured efficiency.
5 Chapter 5Figure 5.1 Circuit topology of the MVAC rectifier.Figure 5.2 Vector representation in complex plane with αβ coordina...Figure 5.3 Topology of the three‐phase converter.Figure 5.4 Sectors and voltage vectors in space complex plane.Figure 5.5 The voltage and current waveforms in a utility cycle.Figure 5.6 Sectors in space vector diagram.Figure 5.7 Three‐phase main bridges’ equivalent circuits of four vectors in ...Figure 5.8 The dendrogram analysis of switching commutation sequences betwee...Figure 5.9 The space vector sequence with one Type 2 commutation process. (a...Figure 5.10 Switching state of the MVAC circuit.Figure 5.11 Driving logic and key waveforms in Sector 1‐1.Figure 5.12 Equivalent circuit of stage 1: the initial stage.Figure 5.13 Equivalent circuit of stage 2: the first resonance stage.Figure 5.14 Equivalent circuit of stage 3: the freewheeling stage.Figure 5.15 Equivalent circuit of stage 4: the short‐circuit stage.Figure 5.16 Equivalent circuit of stage 5: the second resonance stage.Figure 5.17 Equivalent circuit of stage 6: the second steady stage.Figure 5.18 Equivalent circuit of stage 7: the Type 1 commutation stage.Figure 5.19 Equivalent circuit of stage 8: the third steady stage.Figure 5.20 Equivalent circuit of stage 9: the Type 1 commutation stage.Figure 5.21 Resonance circuit and its equivalent circuit of stage 2 (t1–t2)....Figure 5.22 Equivalent circuit of stage 4 (t4–t5). (a) Circuit state of the ...Figure 5.23 Short‐circuit duration (t4 − t3) vs. P0.Figure 5.24 Driving logic waveform in sector 1‐1.Figure 5.25 The short‐circuit mode 1.Figure 5.26 The short‐circuit switches’ current. (a) Sector 1‐1. (b) Sector ...Figure 5.27 The short‐circuit mode 2.Figure 5.28 The short‐circuit switches’ current. (a) Sector 1‐1. (b) Sector ...Figure 5.29 The short‐circuit mode 3.Figure 5.30 The short‐circuit switches’ current.Figure 5.31 Control block diagram of the rectifier.Figure 5.32 Topology of the MVAC rectifier.Figure 5.33 The short‐circuit current ix vs. Zr.Figure 5.34 L r versus Zr.Figure 5.35 CM200DU‐24NFH IGBT turn‐off loss under ZVS conditions.Figure 5.36 Recommended resonant parameters area.Figure 5.37 30 kW ZVS rectifier prototype.Figure 5.38 Bus bar and structure 30 kW ZVS rectifier prototype.Figure 5.39 Output current and grid voltage.Figure 5.40 The driving signal of main switches S1 and S4. (a) Time: 2.5 ms/...Figure 5.41 v c1 and iS1 (time 5 μs/div).Figure 5.42 v c1 and iS1 (time 5 μs/div).Figure 5.43 v c7 and iS7 (time 10 μs/div).Figure 5.44 Current flowing Lr (iLr) and voltage across Ccl (Vcl). (a) Time:...Figure 5.45 Measured efficiency.
6 Chapter 6Figure 6.1 Topology of MVAC ZVS three‐phase inverter.Figure 6.2 Vector representation in complex plane with αβ coordina...Figure