CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY
Purpose. To ensure maximum production of electric power by photovoltaic vacilities, in addition to using highly efficient photovoltaic modules equipped with solar radiation concentrators must use a highly effective power take-off system. This paper is inscribed to solving the problem of a highly eff...
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| Date: | 2016 |
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National Technical University "Kharkiv Polytechnic Institute" and Аnatolii Pidhornyi Institute of Power Machines and Systems of NAS of Ukraine
2016
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| Online Access: | http://eie.khpi.edu.ua/article/view/2074-272X.2016.4.09 |
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eiekhpieduua-article-76394 |
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Electrical Engineering & Electromechanics |
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2017-08-21T18:30:17Z |
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photovoltaic module step-up converter power take-off system photovoltaic facility efficiency 621.311.171 |
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photovoltaic module step-up converter power take-off system photovoltaic facility efficiency 621.311.171 Zaitsev, R. V. Kyrychenko, M. V. Kholod, A. V. Zaitseva, L. V. Prokopenko, D. S. Khrypunov, G. S. CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| topic_facet |
photovoltaic module step-up converter power take-off system photovoltaic facility efficiency 621.311.171 фотоэнергетический модуль повышающий преобразователь система отбора мощности фотоэлектрическая станция коэффициент полезного действия 621.311.171 фотоенергетичний модуль підвищуючий перетворювач система відбору потужності фотоелектрична станція коефіцієнт корисної дії 621.311.171 |
| format |
Article |
| author |
Zaitsev, R. V. Kyrychenko, M. V. Kholod, A. V. Zaitseva, L. V. Prokopenko, D. S. Khrypunov, G. S. |
| author_facet |
Zaitsev, R. V. Kyrychenko, M. V. Kholod, A. V. Zaitseva, L. V. Prokopenko, D. S. Khrypunov, G. S. |
| author_sort |
Zaitsev, R. V. |
| title |
CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| title_short |
CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| title_full |
CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| title_fullStr |
CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| title_full_unstemmed |
CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY |
| title_sort |
calculation of operating parameters of high-voltage power take-off system for the photovoltaic facility |
| title_alt |
РОЗРАХУНОК РОБОЧИХ ПАРАМЕТРІВ ВИСОКОВОЛЬТНОЇ СИСТЕМИ ВІДБОРУ ПОТУЖНОСТІ ФОТОЕЛЕКТРИЧНОЇ СТАНЦІЇ РОЗРАХУНОК РОБОЧИХ ПАРАМЕТРІВ ВИСОКОВОЛЬТНОЇ СИСТЕМИ ВІДБОРУ ПОТУЖНОСТІ ФОТОЕЛЕКТРИЧНОЇ СТАНЦІЇ |
| description |
Purpose. To ensure maximum production of electric power by photovoltaic vacilities, in addition to using highly efficient photovoltaic modules equipped with solar radiation concentrators must use a highly effective power take-off system. This paper is inscribed to solving the problem of a highly efficient and economic power take-off system development. Methodology. To solving the problem, we implemented three stages. On the first stage examines the dependence of electrical power from the intensity of the incident solar radiation. Based on this, the second stage is calculated the DC-DC converter resonant circuit and its working parameters, and developed circuit diagram of DC-DC converter. On the third stage, we carry out an analysis of power take-off system with step up DC-DC converter working. Results. In this paper, we carry out the analysis of working efficiency for photovoltaic facility power take-off system with step-up boost converter. The result of such analysis show that the efficiency of such system in a wide range of photovoltaic energy module illumination power is at 0.92, whereas the efficiency of classic power take-off systems does not exceed 0.70. Achieved results allow designing a circuit scheme of a controlled bridge resonant step-up converter with digital control. Proposed scheme will ensure reliable operation, fast and accurate location point of maximum power and conversion efficiency up to 0.96. Originality. Novelty of proposed power take-off system solution constitute in implementation of circuit with DC-DC converters, which as it shown by results of carrying out modeling is the most effective. Practical value. Practical implementation of proposed power take-off system design will allow reducing losses in connective wires and increasing the efficiency of such a system up to 92.5% in wide range of photovoltaic energy modules illumination. |
| publisher |
National Technical University "Kharkiv Polytechnic Institute" and Аnatolii Pidhornyi Institute of Power Machines and Systems of NAS of Ukraine |
| publishDate |
2016 |
| url |
http://eie.khpi.edu.ua/article/view/2074-272X.2016.4.09 |
| work_keys_str_mv |
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2025-07-17T11:46:23Z |
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2025-07-17T11:46:23Z |
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eiekhpieduua-article-763942017-08-21T18:30:17Z CALCULATION OF OPERATING PARAMETERS OF HIGH-VOLTAGE POWER TAKE-OFF SYSTEM FOR THE PHOTOVOLTAIC FACILITY РОЗРАХУНОК РОБОЧИХ ПАРАМЕТРІВ ВИСОКОВОЛЬТНОЇ СИСТЕМИ ВІДБОРУ ПОТУЖНОСТІ ФОТОЕЛЕКТРИЧНОЇ СТАНЦІЇ РОЗРАХУНОК РОБОЧИХ ПАРАМЕТРІВ ВИСОКОВОЛЬТНОЇ СИСТЕМИ ВІДБОРУ ПОТУЖНОСТІ ФОТОЕЛЕКТРИЧНОЇ СТАНЦІЇ Zaitsev, R. V. Kyrychenko, M. V. Kholod, A. V. Zaitseva, L. V. Prokopenko, D. S. Khrypunov, G. S. photovoltaic module step-up converter power take-off system photovoltaic facility efficiency 621.311.171 фотоэнергетический модуль повышающий преобразователь система отбора мощности фотоэлектрическая станция коэффициент полезного действия 621.311.171 фотоенергетичний модуль підвищуючий перетворювач система відбору потужності фотоелектрична станція коефіцієнт корисної дії 621.311.171 Purpose. To ensure maximum production of electric power by photovoltaic vacilities, in addition to using highly efficient photovoltaic modules equipped with solar radiation concentrators must use a highly effective power take-off system. This paper is inscribed to solving the problem of a highly efficient and economic power take-off system development. Methodology. To solving the problem, we implemented three stages. On the first stage examines the dependence of electrical power from the intensity of the incident solar radiation. Based on this, the second stage is calculated the DC-DC converter resonant circuit and its working parameters, and developed circuit diagram of DC-DC converter. On the third stage, we carry out an analysis of power take-off system with step up DC-DC converter working. Results. In this paper, we carry out the analysis of working efficiency for photovoltaic facility power take-off system with step-up boost converter. The result of such analysis show that the efficiency of such system in a wide range of photovoltaic energy module illumination power is at 0.92, whereas the efficiency of classic power take-off systems does not exceed 0.70. Achieved results allow designing a circuit scheme of a controlled bridge resonant step-up converter with digital control. Proposed scheme will ensure reliable operation, fast and accurate location point of maximum power and conversion efficiency up to 0.96. Originality. Novelty of proposed power take-off system solution constitute in implementation of circuit with DC-DC converters, which as it shown by results of carrying out modeling is the most effective. Practical value. Practical implementation of proposed power take-off system design will allow reducing losses in connective wires and increasing the efficiency of such a system up to 92.5% in wide range of photovoltaic energy modules illumination. Проведен анализ работы системы отбора мощности фотоэлектрической станции с использованием повышающего преобразователя. Показано, что коэффициент полезного действия такой системы в широком диапазоне освещенности фотоэлектрического модуля находится на уровне 0,92, тогда как эффективность классических систем отбора мощности не превышает 0,70. Разработана принципиальная электрическая схема регулируемого мостового резонансного повышающего преобразователя с цифровым управлением, обеспечивающая надежность работы, быстрое и точное нахождение точки максимальной мощности и эффективность преобразования до 0,96. Проведено аналіз роботи системи відбору потужності фотоелектричної станції з використанням підвищувального перетворювача. Показано, що коефіцієнт корисної дії такої системи в широкому діапазоні освітленості фотоелектричного модуля знаходиться на рівні 0,92, тоді як ефективність класичних систем відбору потужності не перевищує 0,70. Розроблено принципова електрична схема регульованого мостового резонансного підвищуючого перетворювача з цифровим керуванням, що забезпечує надійність роботи, швидке і точне знаходження точки максимальної потужності і ефективність перетворення до 0,96. National Technical University "Kharkiv Polytechnic Institute" and Аnatolii Pidhornyi Institute of Power Machines and Systems of NAS of Ukraine 2016-08-30 Article Article application/pdf application/pdf http://eie.khpi.edu.ua/article/view/2074-272X.2016.4.09 10.20998/2074-272X.2016.4.09 Electrical Engineering & Electromechanics; No. 4 (2016); 63-68 Электротехника и Электромеханика; № 4 (2016); 63-68 Електротехніка і Електромеханіка; № 4 (2016); 63-68 2309-3404 2074-272X en uk http://eie.khpi.edu.ua/article/view/2074-272X.2016.4.09/72284 http://eie.khpi.edu.ua/article/view/2074-272X.2016.4.09/72285 Copyright (c) 2016 R. V. Zaitsev, M. V. Kyrychenko, A. V. Kholod, L. V. Zaitseva, D. S. Prokopenko, G. S. Khrypunov https://creativecommons.org/licenses/by-nc/4.0 |