Високовольтна система відбору потужності для сонячної станції
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Національний технічний університет "Харківський політехнічний інститут"
Abstract
Проведено аналіз роботи фотоелектричної станції на основі гібридних фотоенергетичних модулів. На основі виявлених недоліків запропоновано схему відбору потужності на основі підвищуючого перетворювача. Розроблена 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 0,956. Проведено його реалізацію та апробації у складі фотоелектричної станції.
Mathematical modeling of the heat exchange unit main parameters for photoenergy system based on general models with forced circulation of heat transfer fluid. To determine the coefficient of heat transfer at a given coolant temperature and surfaces temperature necessary to determine the temperature gradient in the wall of the heat exchanger. Temperature gradients can be determined by solving the equation of energy, which depends on the distribution of the flow rate in the flow. In general, a solution of convective heat transfer fluid to flow along the plane comes to a decision system of differential equations. In work features the selection of theoretical basis and mathematical modeling of thermal processes in the heat exchange unit for combination photoenergy system. As a result of the simulation conducted to improve and develop high-efficiency heat exchange unit with microchannels. Testing of the proposed unit proved its high efficiency through the implementation of turbulent flow of coolant with heat transfer coefficient at 18 kW/(m2K). Analytical testing of the heat exchanger allowed showing that heat exchanger unit provides a stable operating temperature at less than 50°C with the coolant flow rate is less than 0.3 m/s. Novelty of proposed heat exchanger in the optimal design of microchannels to improve the heat transfer coefficient. The use of this heat exchanger will improve the quality and uniformity of cooling solar panels and reduce energy costs for circulation of fluid.
Mathematical modeling of the heat exchange unit main parameters for photoenergy system based on general models with forced circulation of heat transfer fluid. To determine the coefficient of heat transfer at a given coolant temperature and surfaces temperature necessary to determine the temperature gradient in the wall of the heat exchanger. Temperature gradients can be determined by solving the equation of energy, which depends on the distribution of the flow rate in the flow. In general, a solution of convective heat transfer fluid to flow along the plane comes to a decision system of differential equations. In work features the selection of theoretical basis and mathematical modeling of thermal processes in the heat exchange unit for combination photoenergy system. As a result of the simulation conducted to improve and develop high-efficiency heat exchange unit with microchannels. Testing of the proposed unit proved its high efficiency through the implementation of turbulent flow of coolant with heat transfer coefficient at 18 kW/(m2K). Analytical testing of the heat exchanger allowed showing that heat exchanger unit provides a stable operating temperature at less than 50°C with the coolant flow rate is less than 0.3 m/s. Novelty of proposed heat exchanger in the optimal design of microchannels to improve the heat transfer coefficient. The use of this heat exchanger will improve the quality and uniformity of cooling solar panels and reduce energy costs for circulation of fluid.
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Citation
Зайцев Р. В. Високовольтна система відбору потужності для сонячної станції / Р. В. Зайцев, М. В. Кіріченко, Д. С. Прокопенко // Вісник Нац. техн. ун-ту "ХПІ" : зб. наук. пр. Сер. : Енергетика: надійність та енергоефективність = Bulletin of the National Technical University "KhPI" : coll. sci. papers. Ser. : Energy: Reability and Energy Efficiency. – Харків : НТУ "ХПІ", 2018. – № 10 (1286). – С. 41-47.