MODELLING AND SIMULATION OF THE COMBINATION OF SOLAR PANEL AND THIN FILM MATERIAL WITH COLORED TRANSPARENT ACRYLICS
Transparent thin film materials have unique characteristics when used in the manufacture of solar cells. Transparent thin film materials will transmit some of the photon energy and reflect less. In order to maximize energy absorption in solar cells so that the energy transmitted by the thin film...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/87634 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Transparent thin film materials have unique characteristics when used in the
manufacture of solar cells. Transparent thin film materials will transmit some of
the photon energy and reflect less. In order to maximize energy absorption in solar
cells so that the energy transmitted by the thin film material is not wasted, it can be
stacked with solar cells from other materials whose absorption spectrum is different
from the absorption of the thin film material. By knowing the optical and electrical
characteristics of each material, it is expected to determine the pairing of thin film
materials with other materials. In this study, optical simulations will be carried out
using the Lumerical FDTD simulator. By using this simulator, the reflection,
transmission, and absorption spectra of a material can be determined. This
simulation was carried out on several materials including Crystalline Si, GaAs,
InAs, GaAs-InAs, CdTe, CdSe, and Perovskite. Several of these materials will be
simulated at thicknesses of 2.0 ?m, 1.5 ?m, 1.0 ?m, 0.5 ?m, 0.1 ?m, and 50 nm. The
thicker the material used, the greater the absorption power obtained and the
greater the short-circuit current. Each material has a different absorption spectrum
for each wavelength. There are materials that have good absorption at low
wavelengths, some are good at high wavelengths. By stacking two solar cell
materials by positioning the transparent material on top of the other, an increase
in power will be obtained if the spectra of the two solar cell materials complement
each other. Testing was carried out by simulating two Lumerical FDTD materials,
and measuring and calculating power using colored transparent acrylic as an
approach to transparent thin film solar cells. Each color on acrylic has an
absorption spectrum for each wavelength. there is a decrease in power generated
by the solar cell due to the compaction of acrylic on top of the solar panel. In the
end, a selection of the most optimal combination of two materials in spectrum
absorption was made. The combination of two materials that had the largest total
absorption was a combination of perovskite material with GaAs-InAs with a total
absorption of 82.16%. |
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