TY - JOUR
T1 - Optimal Common-Mode Voltage Injection for Phase-Modular Three-Phase PFC Rectifiers Minimizing Energy Buffering Requirement
AU - Menzi, David
AU - Marugg, Valentin
AU - Langbauer, Thomas
AU - Kolar, Johann W.
PY - 2023/8/29
Y1 - 2023/8/29
N2 - Realizing an isolated three-phase Power Factor Correction (PFC) ac-dc converter as a phase-modular system, i.e, by star-connecting three single-phase PFC rectifier front-ends with individual isolated dc-dc converter stages generating a common dc output voltage advantageously facilitates the use of standard single-phase converter modules. Further the low dc-link voltage level of typically $400 \,\mathrm{V}$ (for a grid with $230 \,\mathrm{V}_\mathrm{rms}$ line-to-neutral voltage) allows to employ high performance $600 \,\mathrm{V}$ power semiconductors. The main drawback of this concept, however, is the fact that the time-varying single-phase input power only sums to a constant three-phase output power at the isolated dc output, such that large dc-link capacitor values are required in each module (in the range of several $100 \,\mathrm{\upmu }\mathrm{F}$ for a $6 \,\mathrm{kW}$ system), thereby limiting the achievable power density. It is known from literature that the dc-link energy buffering requirement $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ can be reduced by means of a third-harmonic common-mode (CM) voltage injection modulation and this paper identifies the optimal CM voltage waveform with respect to minimizing $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$, i.e., reducing $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ to the theoretical minimum by combining a brute-force evaluation of the time-domain CM voltage waveform with phase-symmetry considerations. Additionally, converter operation with minimum dc-link voltage and/or dc-link capacitor values is analyzed and a saturable grid current controller allowing operation of the PFC rectifier front-ends with the optimal CM voltage waveform is investigated. Experimental results with a $6 \,\mathrm{kW}$ prototype system yield a reduction in $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ by up to $42 \,\%$ (compared to conventional sinusoidal modulation), which closely matches the theoretical prediction. Also, PFC rectifier operation with a dc-link voltage level as low as $285 \,\mathrm{V}$ (i.e., below the $325 \,\mathrm{V}_\mathrm{pk}$ grid line-to-neutral voltage amplitude) and with ultra-low dc-link capacitor values is demonstrated.
AB - Realizing an isolated three-phase Power Factor Correction (PFC) ac-dc converter as a phase-modular system, i.e, by star-connecting three single-phase PFC rectifier front-ends with individual isolated dc-dc converter stages generating a common dc output voltage advantageously facilitates the use of standard single-phase converter modules. Further the low dc-link voltage level of typically $400 \,\mathrm{V}$ (for a grid with $230 \,\mathrm{V}_\mathrm{rms}$ line-to-neutral voltage) allows to employ high performance $600 \,\mathrm{V}$ power semiconductors. The main drawback of this concept, however, is the fact that the time-varying single-phase input power only sums to a constant three-phase output power at the isolated dc output, such that large dc-link capacitor values are required in each module (in the range of several $100 \,\mathrm{\upmu }\mathrm{F}$ for a $6 \,\mathrm{kW}$ system), thereby limiting the achievable power density. It is known from literature that the dc-link energy buffering requirement $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ can be reduced by means of a third-harmonic common-mode (CM) voltage injection modulation and this paper identifies the optimal CM voltage waveform with respect to minimizing $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$, i.e., reducing $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ to the theoretical minimum by combining a brute-force evaluation of the time-domain CM voltage waveform with phase-symmetry considerations. Additionally, converter operation with minimum dc-link voltage and/or dc-link capacitor values is analyzed and a saturable grid current controller allowing operation of the PFC rectifier front-ends with the optimal CM voltage waveform is investigated. Experimental results with a $6 \,\mathrm{kW}$ prototype system yield a reduction in $\mathbf {\Delta \mathit{E}_{\mathrm{dc}}}$ by up to $42 \,\%$ (compared to conventional sinusoidal modulation), which closely matches the theoretical prediction. Also, PFC rectifier operation with a dc-link voltage level as low as $285 \,\mathrm{V}$ (i.e., below the $325 \,\mathrm{V}_\mathrm{pk}$ grid line-to-neutral voltage amplitude) and with ultra-low dc-link capacitor values is demonstrated.
KW - Voltage
KW - Rectifiers
KW - Capacitors
KW - Voltage control
KW - Standards
KW - Harmonic analysis
KW - DC-DC power converters
UR - https://ieeexplore.ieee.org/document/10232379/
U2 - 10.1109/OJPEL.2023.3308904
DO - 10.1109/OJPEL.2023.3308904
M3 - Artikel
SN - 2644-1314
VL - PP
SP - 1
EP - 13
JO - IEEE Open Journal of Power Electronics
JF - IEEE Open Journal of Power Electronics
IS - 99
M1 - 10232379
ER -