The dark saturation current of a solar cell is 1.6E-8 A/m², the cell temperature is 321 K, the short-circuit current density is 170 A/m², Vmax is 0.476 V and the available solar radiation is 790 W/m² . The Boltzmann's gas constant is 1.381X1023 J/K and the electronic charge is 1.602X10-19 c. Calculate Open-circuit voltage Voc in Volts = %3D Current density at maximum power Imax in A/m²= Maximum power Pmax in W/m² = % Maximum efficiency nmax %3D
The dark saturation current of a solar cell is 1.6E-8 A/m², the cell temperature is 321 K, the short-circuit current density is 170 A/m², Vmax is 0.476 V and the available solar radiation is 790 W/m² . The Boltzmann's gas constant is 1.381X1023 J/K and the electronic charge is 1.602X10-19 c. Calculate Open-circuit voltage Voc in Volts = %3D Current density at maximum power Imax in A/m²= Maximum power Pmax in W/m² = % Maximum efficiency nmax %3D
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Transcribed Image Text:The dark saturation current of a solar cell is
1.6E-8 A/m2, the cell temperature is 321 K,
the short-circuit current density is 170 A/m?,
Vmax is 0.476 V and the available solar
radiation is 790 W/m² . The Boltzmann's
gas constant is 1.381X1023 J/K and
the electronic charge is 1.602X1019 c.
Calculate
Open-circuit voltage Voc in Volts :
%3D
Current density at maximum power Imax in
A/m²=
Maximum power Pmax in W/m2 =
% Maximum efficiency nmax =
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