101

Cooling of the rear surface of photoelectric batteries (PEB) was investigated by
attaching a newly designed heat collector made of parallel channel cellular polycarbonate to
the rear surface in order to improve the electrical and thermal efficiency in this research work.
The experiment was conducted on June 7, 2022 at the Heliopolygon of the Physical-Technical
Institute of Tashkent city (latitude: +41,34 (41°20'23"N), longitude: +69,3 (69°17'36"E). 2 340 W
monocrystalline silicon PEBs(photoelectric batteries) were used as experimental devices. The
rear surface of the first is equipped with a cooling system. The second are unadjusted for comparison purposes. A heat collector is attached to cool
the back surface of the PEBs(photoelectric batteries), called a photothermal battery (PTB).
Water was used as the cooling liquid of the photothermal battery (PTB). The increase in
electrical and thermal efficiency depending on the change in the flow rate of the coolant was
analyzed. In addition, the dependence of the solar radiation on the frontal surface of the
photothermal battery (PTB) on the inclination angles of the flux density enhancing reflectors
and the support structure moving in relation to the sun on two axes was also investigated.
Electrical and thermal efficiencies were observed for 0,067, 00,1 and 0,2 kg/s flow rates of 210C
water in the consumer pipe to the heat collector.
 

  • Internet havola
  • DOI
  • UzSCI tizimida yaratilgan sana 16-01-2023
  • O'qishlar soni 101
  • Nashr sanasi 13-01-2023
  • Asosiy tilIngliz
  • Sahifalar100-106
English

Cooling of the rear surface of photoelectric batteries (PEB) was investigated by
attaching a newly designed heat collector made of parallel channel cellular polycarbonate to
the rear surface in order to improve the electrical and thermal efficiency in this research work.
The experiment was conducted on June 7, 2022 at the Heliopolygon of the Physical-Technical
Institute of Tashkent city (latitude: +41,34 (41°20'23"N), longitude: +69,3 (69°17'36"E). 2 340 W
monocrystalline silicon PEBs(photoelectric batteries) were used as experimental devices. The
rear surface of the first is equipped with a cooling system. The second are unadjusted for comparison purposes. A heat collector is attached to cool
the back surface of the PEBs(photoelectric batteries), called a photothermal battery (PTB).
Water was used as the cooling liquid of the photothermal battery (PTB). The increase in
electrical and thermal efficiency depending on the change in the flow rate of the coolant was
analyzed. In addition, the dependence of the solar radiation on the frontal surface of the
photothermal battery (PTB) on the inclination angles of the flux density enhancing reflectors
and the support structure moving in relation to the sun on two axes was also investigated.
Electrical and thermal efficiencies were observed for 0,067, 00,1 and 0,2 kg/s flow rates of 210C
water in the consumer pipe to the heat collector.
 

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