US 12,088,215 B2
Modulation strategy suitable for balancing losses of power switches in bridge arm of neutral point clamped three level inverter and implementation method
Huafeng Xiao, Jiangsu (CN); and Xiaobiao Wang, Jiangsu (CN)
Assigned to SOUTHEAST UNIVERSITY, Nanjing (CN)
Filed by SOUTHEAST UNIVERSITY, Jiangsu (CN)
Filed on Apr. 12, 2024, as Appl. No. 18/634,713.
Application 18/634,713 is a continuation of application No. PCT/CN2022/085008, filed on Apr. 2, 2022.
Claims priority of application No. 202210147760.X (CN), filed on Feb. 17, 2022.
Prior Publication US 2024/0275303 A1, Aug. 15, 2024
Int. Cl. H02M 7/487 (2007.01); H02M 1/00 (2006.01); H02M 1/088 (2006.01); H02M 7/5387 (2007.01)
CPC H02M 7/487 (2013.01) [H02M 1/0054 (2021.05); H02M 1/088 (2013.01); H02M 7/5387 (2013.01)] 1 Claim
OG exemplary drawing
 
1. An implementation method for a modulation strategy used for balancing losses of power switches in a bridge arm of a neutral point clamped three level inverter, comprising the steps of:
S1: determining a power factor (PF) angle φ;
S2: determining an operation type of the neutral point clamped three level inverter according to the PF angle φ, and selecting a corresponding modulation style, the operation type comprising a unity power factor (UPF) operation, a lagging PF operation, and a leading PF operation, corresponding to a modulation style I, a modulation style II, and a modulation style III, respectively;
S3: determining a corresponding modulation region according to the PF angle φ obtained in step S1, the modulation style obtained in step S2, and a grid phase angle θ, wherein
the modulation style I selectively corresponds to modulation regions I-A, I-B, I-C and I-D; and in the modulation style I, a corresponding modulation region is I-A in a case that the grid phase angle θ and the PF angle φ meet 0≤θ<π/2, a corresponding modulation region is I-B in a case that π/2≤θ<π, a corresponding modulation region is I-C in a case that π≤θ<3π/2, and a corresponding modulation region is I-D in a case that 3π/2≤θ<2π;
the modulation style II selectively corresponds to modulation regions II-A, II-B, II-C, II-D, II-E and II-F; and in the modulation style II, a corresponding modulation region is II-A in a case that the grid phase angle θ and the PF angle φ meet 0≤θ<φ, a corresponding modulation region is II-B in a case that φ≤θ<φ+π/2, a corresponding modulation region is II-C in a case that φ+η/2≤θ<π, a corresponding modulation region is II-D in a case that π≤θ<φ+π, a corresponding modulation region is II-E in a case that φ+π≤θ<φ+3π/2, and a corresponding modulation region is II-F in a case that φ+3π/2≤θ<2π; and
the modulation style III selectively corresponds to modulation regions III-A, III-B, III-C, III-D, III-E, and III-F; and in the modulation style III, a corresponding modulation region is Ill-A in a case that the grid phase angle θ and the PF angle φ meet 0≤θ<π/2−φ, a corresponding modulation region is III-B in a case that π/2−φ≤θ<π−φ, a corresponding modulation region is III-C in a case that π−φ≤θ<π, a corresponding modulation region is III-D in a case that π≤θ<3π/2−φ, a corresponding modulation region is III-E in a case that 3π/2−φ≤θ<2π−φ, and a corresponding modulation region is III-F in a case that 2π−φ≤θ<2π; and
S4: outputting drive signals of various power switches according to the modulation regions to balance switching losses of inner and outer sides of the bridge arm of the neutral point clamped three level inverter, wherein
in a case that the modulation style I is selected,
in the region I-A, a power switch (S1) of the bridge arm operates at a high frequency according to a unipolar sinusoidal pulse width modulation (SPWM) mode, power switches (S2, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region I-B, a power switch (S2) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S1, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region I-C, a power switch (S4) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S3, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off; and
in the region I-D, a power switch (S3) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S4, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off;
in a case that the modulation style II is selected,
in the region II-A, a power switch (S5) of the bridge arm operates at a high frequency according to a unipolar SPWM mode, and the remaining power switches of the bridge arm are turned off;
in the region II-B, a power switch (S1) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S2, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region II-C, a power switch (S2) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S1, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region II-D, a power switch (S6) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, and the remaining power switches of the bridge arm are turned off;
in the region II-E, a power switch (S4) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S3, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off; and
in the region II-F, a power switch (S3) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S4, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off; and
in a case that the modulation style III is selected,
in the region III-A, a power switch (S2) of the bridge arm operates at a high frequency according to a unipolar SPWM mode, power switches (S1, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region III-B, a power switch (S1) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S2, S6) of the bridge arm are turned on, and power switches (S3, S4, S5) of the bridge arm are turned off;
in the region III-C, a power switch (S5) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, and the remaining power switches of the bridge arm are turned off;
in the region III-D, a power switch (S4) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S3, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off;
in the region III-E, a power switch (S3) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, power switches (S4, S5) of the bridge arm are turned on, and power switches (S1, S2, S6) of the bridge arm are turned off; and
in the region III-F, a power switch (S6) of the bridge arm operates at the high frequency according to the unipolar SPWM mode, and the remaining power switches of the bridge arm are turned off,
wherein in step 2, in a case that the PF angle φ is zero, the neutral point clamped three level inverter is in the UPF operation, corresponding to the modulation style I; in a case that the PF angle φ is greater than zero, the neutral point clamped three level inverter is in the lagging PF operation, corresponding to the modulation style II; and in a case that the PF angle φ is less than zero, the neutral point clamped three level inverter is in the leading PF operation, corresponding to the modulation style III, and
wherein the drive signals of various power switches in step S4 are obtained by comparing a modulation wave Vm with a carrier wave Vc according to unipolar SPWM.