1. Introduction
Multiphase electric drive systems are attracting more and more attention due to their superior characteristics when compared to traditional three-phase systems. Among these advantages, lower torque ripple, higher power density, reduced current per phase and inherent fault tolerance capability are highlighted [
1,
2]. In this sense, despite the proposal of several multiphase topologies, star-connected structures with an odd number of phases are preferred. More precisely, five-phase technology has been extensively used, since it provides a good trade-off between system complexity and fault tolerance [
3,
4]. Furthermore, the fault tolerance capability has led to the use of multiphase systems in motor drive applications in which safety is a critical requirement as in electric vehicles and more electric aircraft [
5,
6,
7].
In addition to the traditional voltage source inverter (VSI), neutral point voltage control converters (NPVCC) have been proposed for motor drive applications, where the three-phase four-leg converter stands out [
8,
9,
10]. Likewise, multilevel NPVCCs [
11] and multiphase NPVCCs, as in [
12] where a pole-phase modulated induction motor is driven by using three three-phase four-leg inverters, have been also considered for motor drive applications. Similarly, a five-phase six-leg variation (
Figure 1), intended for switching power amplifiers for magnetic levitation bearing systems, is explored in [
13,
14].
The control over the neutral point voltage (N in
Figure 1) releases the constraint that the sum of the stator currents is zero. Consequently, this converter has the ability to control unbalanced loads. Although this converter has some disadvantages, such as the need for the machine to have access to the neutral point, it also has significant advantages. For example, the control over the neutral point voltage offers an extra degree of freedom that can be used for different purposes, such as fault tolerance [
15] and common mode voltage (CMV) reduction [
16,
17].
CMV is a serious concern when speaking about system reliability. This voltage is an unavoidable consequence in pulse-width modulated (PWM) power converters. In addition to damaging the electric machine bearings [
18], the CMV produces undesirable electromagnetic interferences [
19] and leakage currents that flow through the machine, destroying the stator winding insulation [
20]. These damages are mainly caused due to the high
caused by the inverter commutations on the machine terminals, in addition to the high voltage amplitude of CMV [
21]. Furthermore, these effects are expected to worsen as the use of WBG devices becomes more common [
20].
Generating sinewaves using high-frequency PWM can lead to bearing damage caused by common-mode voltage (CMV) from the inverter. Specifically, the unbalanced phase voltages produced by the PWM algorithm driving the power devices result in CMV profiles with abrupt edges. Due to the parasitic capacitances and the high
values, a replica of the CMV forms appears in the shaft. This may exceed the dielectric breakdown voltage of the lubrication film inside the bearing, resulting in arcing discharge sparks between the bearing races in the form of ringing current pulses. This leads to pitting and fluting. Furthermore, these fast-switching CMV shapes also degrade the stator windings and can cause significant electromagnetic interferences (EMI). The entire process of generating CMV is explained in detail in [
22].
In order to overcome these harmful effects, PWM algorithms provide a flexible and cost-effective solution. In this context, several reduced common mode voltage modulation techniques (RCMV-PWM) have been proposed, with the most well-known being AZS-PWM, NS-PWM, and RS-PWM. In addition to these algorithms, which were initially proposed for three-phase converters, other techniques have been proposed that reduce CMV in converters with control over the neutral point [
23,
24]. For instance, the authors of [
16] propose a carrier-based modulation technique to eliminate the common-mode leakage current in transformerless photovoltaic systems. Similarly, ref. [
25] takes advantage of the neutral point connection to mitigate the load neutral point voltage by means of a new space-vector-based modulation technique. On the other hand, ref. [
26] proposes a modulation technique to suppress the CMV in hybrid grids. Moreover, the proposed modulation results in a marked reduction in the DC grid voltage oscillation. In [
23], the well-known near-state PWM (NS-PWM) modulation, first proposed for three-phase inverters in [
27], is extended to three-phase four-leg inverters. Likewise, the only three-dimensional space-vector (3D SV-PWM) for a five-phase six-leg converter is proposed in [
28].
To fill this gap in the literature, this work proposes a three-dimensional RCMV-PWM (3D RCMV-PWM), based on the well known NS-PWM, to be applied in five-phase six-leg motor drive systems. The authors have chosen to follow the principles of the NS-PWM technique because, unlike AZS-PWM, it does not reverse the polarity of the current within a single commutation period. Additionally, it has a greater linear range than those algorithms based on RS-PWM. Most importantly, NS-PWM techniques are discontinuous, which allows reducing the switching losses of the converter. This is where NS-PWM is superior to AZS-PWM and RS-PWM. In this sense, the technical challenge of operating the suggested PWM method for a five-phase six-leg inverter is to reduce the common-mode voltage without worsening other features of the complete system, such as efficiency.
For that purpose, the proposed converter and CMV are first introduced in
Section 2 and
Section 3. Secondly, the 3D RCMV-PWM is explained in detail in
Section 4. Then, the CMV of the proposed modulation is analysed thoroughly by simulation in
Section 5. Lastly, experimental results are given in
Section 6. In this section, the CMV reduction is verified, and the efficiency and total harmonic distortion parameters are discussed for five-phase six-leg converters.
2. Five-Phase Six-Leg Vector Definition
Due to the control over the neutral point voltage, the space vector of a five-phase six-leg inverter is three-dimensional. Thus, the transition from
coordinates to
xy coordinates is expressed as
where
(
) are the
axis phase-to-neutral voltages (
Figure 1):
where phase voltages are equal to
and
(
) equals 1 when the switch is active and 0 when the switch is inactive;
(
) are the voltage vector components and
is the Clarke transformation matrix given by [
28]:
The vector space of five-phase systems consists of two subspaces:
and
. When adding the sixth leg capable of defining the neutral point voltage, it is necessary to add a third dimension (
) to each of these subspaces. Thus, the three-dimensional subspaces
and
are defined. The vector space of a five-phase converter has the shape of a decagon, so adding a third dimension gives a decagonal prism. From here on, the
decagonal prism will be taken as a reference. In this sense,
Figure 2 shows the
prism decomposed according to the values obtained by the
variable. This Figure shows all the vectors that make up the vector space, whose names are given by converting the first five-leg switching states, treated as a binary number, to decimals. The sixth branch switching state equals P (positive) when its value is 1 and N (negative) when its value is 0.
5. 3D RCMV-PWM Algorithm Simulation Analysis
To estimate the CMV reduction, a complete five-phase six-leg PMSM model was developed in Matlab/Simulink, adapted from [
31]. This simulation model (
Figure 8) is composed of a double control loop (speed–torque) based on a reference speed input. The electric machine is a concentrated-winding PMSM, since the proposed 3D RCMV-PWM algorithm does not generate any voltage in the
space and, therefore, the effect of the third harmonic is neglected. The mathematical behaviour of the electric drive is calculated based on the following stator voltage equation:
where
and
are 5D vectors whose elements (
and
,
) are the per-phase voltages and currents, respectively. Similarly,
and
are
matrices that specify the values of the stator resistances and inductances. For matrix
,
(
) shows the self-inductances (
) and mutual inductances (
) between phases
i and
j.
stands for the 5D flux linkage vector generated due to the permanent magnets. Finally, some of the motor characteristics are included in
Table 3. On the other hand, the converter includes a semiconductor thermal and loss model based on the International Rectifier AUIRGPS4067D1 IGBT. The switching period corresponds to the inverse of the switching frequency and, in these simulations, amounts to 0.1 ms.
To perform the simulations, different operating points were used. Specifically, a speed of 1200 rpm was set—the nominal speed—and three different loads were simulated at this speed: 50%, 75% and 100% of the rated torque (12.5 Nm).
Figure 9 shows the phase currents and
and
currents used to control the machine at the different operating points. It is worth noting that in all these operating points, due to the high speed, the 3D RCMV-PWM technique is used. It can be seen that as the load increases, the THD is significantly better. As for the switching losses, these always remain below those obtained with the 3D SV-PWM modulation. In fact, the proposed technique reduces losses by 32.57% at full load. However, the weakness of discontinuous RCMV modulation techniques, i.e., the increase in THD, is also visible.
Table 4 shows the full comparison between the modulations studied at the specified operating points.
As for the CMV,
Figure 10 shows the CMV waveform for 3D SV-PWM and 3D RCMV-PWM at same load conditions (
= 1200 rpm and T =
). As expected from the mathematical analysis of the modulation and the CMV, 3D SV-PWM CMV consists of seven voltage levels and a 3D RCMV-PWM waveform of only three voltage levels, one of them being
= 0. Each of the figures show the CMV during Sector 1. In all cases, it can be seen how the width of the different voltage levels varies and, in some cases, two transitions occur almost instantaneously. This is because, as
rotates, the application time of each applied vector changes and, in turn, the width of the CMV levels.
In order to study the waveforms shown in
Figure 11a,b in more detail, it is also useful to measure the normalised energy of the frequency domain harmonics during a complete period of the modulating signal (
Figure 11c,d). These figures show how the CMV fundamental harmonic is greatly reduced with the proposed modulation. Indeed, the amplitudes of the biggest harmonics are 39.13% and 11.47% when using 3D SV-PWM and 3D RCMV-PWM, respectively. The following formula is proposed in [
20] to define the normalised energy of the CMV harmonics:
where
is the CMV
harmonic amplitude.
Moreover, the common mode currents (CMC) are shown in
Figure 12c,d. The CMC that is produced by each CMV waveform was modelled using a 10 nF parasitic capacitor, which simulates the motor’s parasitic capacitance [
29]. From
Figure 12c,d it is clear how for each CMV transition a current spike is generated. Thus, the more transitions there are, the more current spikes will occur per switching period. On the other hand, the amplitude of these spikes is equal in both modulation techniques, their amplitude being 0.18 A. As with the CMV, the energy produced by the harmonics of the CMC is also calculated as follows:
CMV and CMC energy results are shown in
Table 5. To sum up, the CMV normalised energy is reduced by up to 77.81%, while the CMC normalised energy is reduced by up to 21.43% when 3D RCMV-PWM is used.
6. Experimental Setup and Results
In order to validate the proposed modulation, a five-phase six-leg inverter was built; its main components are shown in
Figure 13. The DC voltage source is an AMREL SPS600-10-K0E3 and is regulated to 110 V. The five-phase six-leg inverter is composed of two three-phase two-level VSIs. Each converter includes an SK15GDT4ET IGBT module, an SKHI71 driver and a DC bus capacitor of 2 mF per converter. Finally, the power inverter is switched at 16 kHz (
=
s) and feeds an RL load of 10
and 10 mH per phase.
This load was chosen since, at high speeds, electric machines produce a high back electromotive force that must be compensated for by the voltage generated by the inverter. Thus, the modulation index that must be applied is higher as the speed increases. For this reason, for the experimentation, an RL-type load (R = 10 and L = 10 mH) was used. An R > L type load allows the modulation of the converter with high modulation indexes and, this way, it is possible to emulate the behaviour of a machine at high speeds. On the other hand, the 3D RCMV-PWM technique was implemented using MATLAB/Simulink in an OPAL-RT OP4510 simulation platform, which is composed of a PC cluster and a programmable FPGA.
In this section, the CMV reduction is first validated experimentally and, then, the five-phase six-leg performance is analysed in terms of efficiency and harmonic distortion. For that purpose, both 3D SV-PWM and 3D RCMV-PWM algorithms have been implemented for comparison purposes.
6.1. CMV Reduction Validation
As stated before, four figures of merit have been defined to compare the CMV waveforms:
,
,
and
. The CMV waveforms obtained experimentally are shown in
Figure 14 for each of the modulations. Regarding the 3D RCMV-PWM algorithm, only three levels are generated (
= 3), which are
, 0 and
. This means a reduction in
from 1 to
and a reduction in voltage levels from 7 to 3 when compared with 3D SV-PWM. Likewise, fewer CMV level transitions are applied with the proposed technique, reducing them from 12 to 10. As the step between two consecutive voltage levels depends on the number of branches of the converter,
does not change with the proposed modulation and remains at 1/6.
6.2. Efficiency Analysis and Harmonic Behaviour
Regarding efficiency, 3D RCMV-PWM shows an improvement when compared with 3D SV-PWM, mainly due to the reduction in switching losses. The efficiency of both algorithms has been measured using a wattmeter, obtaining the result shown in
Table 6. This loss reduction is a consequence of the fact that the 3D RCMV-PWM technique belongs to the group of discontinuous modulations and, therefore, one of the branches does not commute at each
. Indeed, this condition also explains the somewhat higher total harmonic distortion (THD) of 3D RCMV-PWM modulations when compared with the 3D SV-PWM algorithm. The 3D RCMV-PWM phase currents are shown in
Figure 15. In this figure, in addition to phase currents, the neutral current is also shown. The average value of the neutral leg current is close to zero and has a peak-to-peak current amplitude of 2.28 A. The 3D SV-PWM currents are not displayed since they are very similar to those of 3D RCMV-PWM. Nonetheless, low-order harmonics of both PWM techniques are presented in
Table 6.