Two phase sinusoidal pulse width modulation with remodulation in the "converter – electric motor system"

Introduction. Two-phase pulse width modulation in "the converter – electric motor" system is considered. It is noted that two-phase voltage modulation, which is implemented on a set of two electronically-key half bridges, finds important practical application. Restrictions are given on the values of the modulating functions of the potentials of the keys of the half-bridges, violation of which leads to intermodulation. Intermodulation leads to the appearance of low frequency harmonics in the composition of voltages and is the reason for a decrease in the energy efficiency of "the converter – electric motor" system.

Goal. The aim is to study the effect of re-modulation on the energy processes of two-phase pulse width modulation in "the converter – electric motor" system.

Materials and methods. New modulating functions with constraints have been introduced to analyze the phenomena associated with modulation. Methods of analysis of electrical circuits were used in the work.

Results and discussion. Quantitative estimates of the modulation and its relation to the modeling function are obtained. It is shown that the modulation makes it possible to increase the amplitude of the harmonic base. This has a positive effect on the energy parameters of a single-phase bridge. However, the intermodulation leads to the appearance of low-frequency harmonics in the current spectrum. Dependences characterizing the degree of increase in current dispersion in the load during modulation, which is the main criterion for PWM quality, are obtained. Recommendations are given for the design of a bridge converter, taking into account the phenomenon of intermodulation.

Conclusion. The results can be used in the development of algorithms for controlling frequency converters in frequency control systems of electric drives.

1. Madhavi R, Harinath C. Investigation of various space vector pwm techniques for inverter. International Journal of Engineering Research and Management (IJERM). 2014;1(7):162-165.

2. Klimov V. Frequency-energy parameters of PWM inverters of uninterruptible power supply systems. Power electronics. 2009;(22):66-71. (In Russ.).

3. Hava AM, Çetin NO. A Generalized Scalar PWM Approach with Easy Implementation Features for Three-Phase, Three-Wire Voltage-Source Inverters. IEEE Transactions on Power Electronics. 2010;26(5):1385-1395. (In Russ.). https://doi.org/10.1109/TPEL.2010.2081689

4. Dmitriev BF, Galushin SYa, Likhomanov AM, Rozov AYu. Three-phase sinusoidal modified pulse width modulation of the first kind in autonomous inverters. Marine Bulletin. 2017;61(1):69-72. (In Russ.).

5. Mao X, Ayyanar R, Krishnamurthy HK. Optimal variable switching frequency scheme for reducing switching loss in single-phase inverters based on time-domain ripple analysis. IEEE Transactions on Power Electronics. 2009;24(4):991-1001. https://doi.org/10.1109/TPEL.2008.2009635.

6. Belousov IV, Samoseiko VF, Saushev AV. Optimal pulse width modulation in an electric drive control system. Bulletin of the Admiral S. O. Makarov State University of Marine and River Fleet. 2022;3(14):463-471. (In Russ.). https://doi.org/10.21821/2309-5180-2022-14-3-463-471

7. Samoseiko VF, Belousov IV, Saushev AV. Optimized single-phase pulse-width modulation. International Russian Automation Conference, RusAutoCon 2018, article No. 8501699. https://doi.org/10.1109/RUSAUTOCON.2018.8501699.

8. Samoseiko VF, Belousov IV, Saushev AV. Optimal double-halfbridge pulse width modulation by current-dispersion criterion. 2019 26th International Workshop on Electric Drives: Improvement in Efficiency of Electric Drives, IWED 2019 – Proceedings. 2019. Article No. 8664344.

9. Guskov VO, Lavin AV. Comparative analysis of mathematical descriptions and methods of pulse-width modulation. Bulletin of the Astrakhan State Technical University. Series: Marine engineering and Technology. 2023;(3):74-81. (In Russ.). https://doi.org/10.24143/2073-1574-2023-3-74-81.

10. Hava AM, Çetin NO. A Generalized Scalar PWM Approach with Easy Implementation Features for Three-Phase, Three-Wire Voltage-Source Inverters. IEEE Transactions on Power Electronics. 2011;26(5):1385-1395. https://doi.org/10.1109/TPEL.2010.2081689.

11. Tan G, Deng Q, Liu Z. An optimized SVPWM strategy for five-level active NPC (5L-ANPC) converter. IEEE Transactions on power electronics. 2013;29(1):386-395. https://doi.org/10.1109/TPEL.2013.2248172.

12. Belousov IV, Samoseiko VF, Saushev AV. Assessment of filtering properties of asynchronous electric drive with pulse width modulation. XV International Scientific Conference on Precision Agriculture and Agricultural Machinery Industry “State and Prospects for the Development of Agribusiness. INTERAGROMASH 2022” Rostov-on-Don, Russia. 2022;(363):1-8. (In Russ.). https://doi.org/10.1051/e3sconf/202236301025.

13. Bakhovtsev IA, Zinoviev GS. Generalized analysis of the output energy of multiphase multilevel voltage inverters with pulse width modulation. Electricity. 2016;4:26-33. (In Russ.).

14. Chaplygin EE, Khukhtikov SV. Pulse width modulation with passive phase in three-phase voltage inverters. Electricity. 2011;(5):53-61. (In Russ.).

15. Nayeemuddin M, Rao C. Space Vector Based High Performance Discontinuous Pulse Width Modulation Algorithms for VSI Fed AC Drive. Innovative Systems Design and Engineering (IJSR). 2016;5(7):203-208.

16. Samoseiko VF, Belousov IV, Saushev AV. Optimal Pulse-Width Modulation with Three Bridges on Criterion of Power Losses at Load. International Russian Industrial Engineering, ICIE, 2019. 2019 International Conference on Industrial Engineering, Applications and Manufacturing, ICIEAM 2019. Article No. 8743011. Sochi, March 25-29, 2019. https://doi.org/10.1109/ICIEAM.2019.8743011.

17. Vasiliev BYu. Ensuring the modulation mode and increasing the efficiency of energy conversion in power autonomous inverters of electric drives. Electricity. 2015;(6):47-55. (In Russ.).

18. Graditi G, Griva G, Oleschuk V. Overmodulation control of five-phase inverters with full DC-bus voltage utilization. SPEEDAM. 2010;1150-1155.

19. Holtz J, Lotzkat W, Khambadkone AM. On Continuous Control of PWM Inverters in the Overmodulation Range Including the Six-Step Mode. IEEE Transactions on Power Electronics. 1993;8(4):546-553.

20. Kerkman RJ, Leggate D, Seibel BJ, Rowan TM. Operation of PWM voltage source inverters in the overmodulation region. IEEE Transactions on Industrial Electronics. 1996;43(1):132-141.