DESIGN AND IMPLEMENTATION OF SOLAR PANEL SUBSYSTEM, BATTERY SUBSYSTEM, INTERFACE SUBSYSTEM, AND CONTROLLER SUBSYSTEM IN OFF-GRID SOLAR PANEL SYSTEMS WITH LAPTOP AS A LOAD
In Indonesia, there are still areas that do not have access to electricity. This can be seen from the value of the electrification ratio in Indonesia which has not yet reached 100%, for example in East Nusa Tenggara Province, the electrification ratio is only 85.84% and shows that 14.16% of house...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/69570 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | In Indonesia, there are still areas that do not have access to electricity. This can be
seen from the value of the electrification ratio in Indonesia which has not yet
reached 100%, for example in East Nusa Tenggara Province, the electrification
ratio is only 85.84% and shows that 14.16% of households in the province have not
used electricity. On the other hand, electricity is needed in everyday life, for
example in terms of education, especially during this pandemic where learning is
done online. Electricity can be generated by converting other energy into
electricity, for example energy from wind, coal, and so on. One of the renewable
energies that can be converted into electricity is sunlight, for example by using
solar panels. This energy source is suitable for use as electricity considering that
Indonesia has a tropical climate with an intensity of irradiation of around 4-6
kWh/m2 and a irradiation time of 40% to 80%.
Based on the description above, a solution is proposed in the form of an Off-Grid
solar system with a laptop as a load. Some of the important parts of the system are
solar panel subsystem, battery subsystem, interface subsystem, and controller
subsystem. The solar panel subsystem consists of monocrystalline solar panels and
solar panel interfaces, the battery subsystem consists of LiFePo4 batteries and
current and voltage sensors, the interface subsystem consists of 10 LEDs that
display battery capacity with a resolution of 10%, and the controller subsystem
contains the MPPT algorithm (Maximum Power Point Tracking) and system
software integration. In general, functional testing for each subsystem has been
successfully carried out. |
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