Calculation of the Output Filters of Power Supply Systems with Multizone Control
Keywords:
multizone control, power supply system, LC filter, ripple, pulsed component, direct current
Abstract
The article considers the principle of multizone control of the output parameters of DC power supply systems based on dividing the full range into several zones of equal size. Discrete control is performed by switching from one zone to another, and smooth control is performed by using pulse-width modulation within each zone. This multizone control method is characterized by the presence of two components in the output voltage and consumed current forms: constant uncontrolled and pulsed adjustable ones. The dependence of the relative pulsed component value on the number of produced discrete zones and the adjustment range of the output voltage value has been established. A simplified method for calculating the parameters of the output filters of power supply systems with multizone control is proposed. To estimate the error of the proposed method, a simplified simulation of a DC source in a steady state operation mode was carried out. The study results have shown that the mismatch between the calculated and simulated parameters is within the limits acceptable for engineering calculations. The prospects of using multizone control to reduce the weight and size parameters of DC power supply systems with intermediate conversion of electric power parameters has been substantiated.
References
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11. Sudeep P., Mohammad M. Filter Design for AC to DC Converter. – International Refereed Journal of Engineering and Science (IRJES), 2013, vol. 2, is. 6, pp. 42–49.
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15. Попков О.З. Основы преобразовательной техники. М.: Издательский дом МЭИ, 2010, 200 с.
#
1. Kobzev A.V. Mnogozonnaya impul'snaya modulyatsiya (Multi-zone pulse modulation). Novosibirsk: Nauka, 1979, 304 p.
2. Anisimova T.V., Danilina A.N. Trudy MAI – in Russ. (Proceedings of Moscow Aviation Institute), 2012, No. 52, pp. 1–15.
3. Tsytovich L.I. et al. Multi-Zone Integrating Regulator to Control the Electric Drives with Parallel Regulation Channels. – International Conference on Industrial Engineering, 2015, pp. 615–623.
4. Seyyed H.H. et al. An Attempt to Improve Output Voltage Quality of Developed Multi-Level Inverter Topology by Increasing the Number of Levels. – 9th International Conference on Electrical and Electronics Engineering (ELECO), 2015, pp. 665–669, DOI: 10.1109/ELECO.2015.7394622.
5. Sujanarko B., Ashari M., Purnomo M.H. Improved Voltage of Cascaded Inverters Using Sine Quantization. – TELKOMNIKA (Telecommunication Computing Electronics and Control), 2010, vol. 8, No. 2, pp. 123–130, DOI:10.12928/telkomnika.v8i2.613.
6. Budennyy A.V., Sen'ko V.I. Problemy preobrazovatel'noy tekhniki – in Russ. (Problems of converter technology), 1979. vol. 2, pp. 35–38.
7. Gusev S.I. Tekhnicheskaya elektrodinamika – in Russ. (Technical Electrodynamics), 1980, No. 5, pp. 49–55.
8. Liao J., Zhou N., Wang Q. Design of Low-Ripple and Fast-Response DC Filters in DC Distribution Networks. – Energies, 2018, 11(11):3128, DOI:10.3390/en11113128.
9. Riba J.-R. et al. Parameter Identification of DC-DC Converters Under Steady-State and Transient Conditions Based on White-Box Models. – Electronics, 2018, vol. 7(12), DOI:10.3390/electronics7120393.
10. Liu Y. et al. Reliability-Oriented Optimization of the LC Filter in a Buck DC-DC Converter. – IEEE Transactions on Power Electronics, 2017, vol. 32, No. 8, pp. 6323–6337, DOI: 10.1109/TPEL.2016.2619690.
11. Sudeep P., Mohammad M. Filter Design for AC to DC Converter. – International Refereed Journal of Engineering and Science (IRJES), 2013, vol. 2, is. 6, pp. 42–49.
12. Grigorash O.V., Ivanovskiy O.Ya., Tuayev A.S. Nauchnyy zhurnal KubGAU – in Russ. (Scientific journal of the Kuban State Agrarian University), 2017, No. 133(09), pp. 1–11.
13. Korshunov A.A. Silovaya elektronika – in Russ. (Power Electronics), 2005, No. 3, pp. 88–91.
14. Kobzev A.V., Konovalov B.I., Semenov V.D. Energeticheskaya elektronika: Uchebnoye posobiye (Power Electronics: Textbook). Tomsk: Tomskiy mezhvuzovskiy tsentr distantsionnogo obrazovaniya, 2010, 164 p.
15. Popkov O.Z. Osnovy preobrazovatel'noy tekhniki (Fundamentals of Conversion Technology). М.: Izdatel'skiy dom MEI, 2010, 200 p.
2. Анисимова Т.В., Данилина А.Н. Инверторы с многозонной модуляцией. – Труды МАИ, 2012, № 52, с. 1–15.
3. Tsytovich L.I. et al. Multi-Zone Integrating Regulator to Control the Electric Drives with Parallel Regulation Channels. – International Conference on Industrial Engineering, 2015, pp. 615–623.
4. Seyyed H.H. et al. An Attempt to Improve Output Voltage Quality of Developed Multi-Level Inverter Topology by Increasing the Number of Levels. – 9th International Conference on Electrical and Electronics Engineering (ELECO), 2015, pp. 665–669, DOI: 10.1109/ELECO.2015.7394622.
5. Sujanarko B., Ashari M., Purnomo M.H. Improved Voltage of Cascaded Inverters Using Sine Quantization. – TELKOMNIKA (Telecommunication Computing Electronics and Control), 2010, vol. 8, No. 2, pp. 123–130, DOI:10.12928/telkomnika.v8i2.613.
6. Буденный А.В., Сенько В.И. Промежуточное повышение частоты в преобразователях с суммированием в общем контуре. – Проблемы преобразовательной техники, 1979. ч. 2, c. 35–38.
7. Гусев С.И. Принципы построения прецизионных преобразователей с программируемой формой выходного напряжения. – Техническая электродинамика, 1980, № 5, c. 49–55.
8. Liao J., Zhou N., Wang Q. Design of Low-Ripple and Fast-Response DC Filters in DC Distribution Networks. – Energies, 2018, 11(11):3128, DOI:10.3390/en11113128.
9. Riba J.-R. et al. Parameter Identification of DC-DC Converters Under Steady-State and Transient Conditions Based on White-Box Models. – Electronics, 2018, vol. 7(12), DOI:10.3390/electronics7120393.
10. Liu Y. et al. Reliability-Oriented Optimization of the LC Filter in a Buck DC-DC Converter. – IEEE Transactions on Power Electronics, 2017, vol. 32, No. 8, pp. 6323–6337, DOI: 10.1109/TPEL.2016.2619690.
11. Sudeep P., Mohammad M. Filter Design for AC to DC Converter. – International Refereed Journal of Engineering and Science (IRJES), 2013, vol. 2, is. 6, pp. 42–49.
12. Григораш О.В., Ивановский О.Я., Туаев А.С. Методика расчёта фильтров статических преобразователей электроэнергии. – Научный журнал КубГАУ, 2017, № 133(09), c. 1–11.
13. Коршунов А.А. Динамический расчёт стабилизированного понижающего преобразователя напряжения постоянного тока. – Силовая электроника, 2005, № 3, c. 88–91.
14. Кобзев А.В., Коновалов Б.И., Семенов В.Д. Энергетическая электроника. Томск: Томский межвузовский центр дистанционного образования, 2010, 164 с.
15. Попков О.З. Основы преобразовательной техники. М.: Издательский дом МЭИ, 2010, 200 с.
#
1. Kobzev A.V. Mnogozonnaya impul'snaya modulyatsiya (Multi-zone pulse modulation). Novosibirsk: Nauka, 1979, 304 p.
2. Anisimova T.V., Danilina A.N. Trudy MAI – in Russ. (Proceedings of Moscow Aviation Institute), 2012, No. 52, pp. 1–15.
3. Tsytovich L.I. et al. Multi-Zone Integrating Regulator to Control the Electric Drives with Parallel Regulation Channels. – International Conference on Industrial Engineering, 2015, pp. 615–623.
4. Seyyed H.H. et al. An Attempt to Improve Output Voltage Quality of Developed Multi-Level Inverter Topology by Increasing the Number of Levels. – 9th International Conference on Electrical and Electronics Engineering (ELECO), 2015, pp. 665–669, DOI: 10.1109/ELECO.2015.7394622.
5. Sujanarko B., Ashari M., Purnomo M.H. Improved Voltage of Cascaded Inverters Using Sine Quantization. – TELKOMNIKA (Telecommunication Computing Electronics and Control), 2010, vol. 8, No. 2, pp. 123–130, DOI:10.12928/telkomnika.v8i2.613.
6. Budennyy A.V., Sen'ko V.I. Problemy preobrazovatel'noy tekhniki – in Russ. (Problems of converter technology), 1979. vol. 2, pp. 35–38.
7. Gusev S.I. Tekhnicheskaya elektrodinamika – in Russ. (Technical Electrodynamics), 1980, No. 5, pp. 49–55.
8. Liao J., Zhou N., Wang Q. Design of Low-Ripple and Fast-Response DC Filters in DC Distribution Networks. – Energies, 2018, 11(11):3128, DOI:10.3390/en11113128.
9. Riba J.-R. et al. Parameter Identification of DC-DC Converters Under Steady-State and Transient Conditions Based on White-Box Models. – Electronics, 2018, vol. 7(12), DOI:10.3390/electronics7120393.
10. Liu Y. et al. Reliability-Oriented Optimization of the LC Filter in a Buck DC-DC Converter. – IEEE Transactions on Power Electronics, 2017, vol. 32, No. 8, pp. 6323–6337, DOI: 10.1109/TPEL.2016.2619690.
11. Sudeep P., Mohammad M. Filter Design for AC to DC Converter. – International Refereed Journal of Engineering and Science (IRJES), 2013, vol. 2, is. 6, pp. 42–49.
12. Grigorash O.V., Ivanovskiy O.Ya., Tuayev A.S. Nauchnyy zhurnal KubGAU – in Russ. (Scientific journal of the Kuban State Agrarian University), 2017, No. 133(09), pp. 1–11.
13. Korshunov A.A. Silovaya elektronika – in Russ. (Power Electronics), 2005, No. 3, pp. 88–91.
14. Kobzev A.V., Konovalov B.I., Semenov V.D. Energeticheskaya elektronika: Uchebnoye posobiye (Power Electronics: Textbook). Tomsk: Tomskiy mezhvuzovskiy tsentr distantsionnogo obrazovaniya, 2010, 164 p.
15. Popkov O.Z. Osnovy preobrazovatel'noy tekhniki (Fundamentals of Conversion Technology). М.: Izdatel'skiy dom MEI, 2010, 200 p.
Published
2023-07-17
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