Solar power optimizer for PV energy harvesting
Solar power – a conversion of light from the sun into energy – is one of the most commonly used sources of renewable energy is beneficial in a number of ways, since it offers the opportunity to harvest electricity with minimal impact on the environment. However, the methods commonly used to...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2014
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/61479 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Solar power – a conversion of light from the sun into energy – is one of the most commonly
used sources of renewable energy is beneficial in a number of ways, since it offers the
opportunity to harvest electricity with minimal impact on the environment. However, the
methods commonly used to harness solar energy have been found to be inefficient because of
high levels of dissipation. As such, this project was premised upon the need to implement a
system that would improve efficiency in the generation of solar energy. It was guided by two
objectives: to implement a solar panel optimizer on ordinary solar panel in order to maximize
the harvesting of power; and to connect two or more independent solar panels with individual
optimizers in series to compensate those with shaded condition.
In order to attain these objectives, the project involved building and configuring micro DCDC
controller intended for harvesting solar energy directly from a solar module. This was
attained by connecting multiple DC-DC controllers in series so as to generate a supply of
voltage that can be injected into an inverter. The convertors are controlled a micro-controller,
which is able to communicate with other modules in the string. The system includes a
Maximum Power Point Tracking algorithm that is programmed into each micro-controller to
aid in extracting maximum power. In this project, the optimizers were tested on a DC power
supply to represent the solar panel.
Some of the recommendations made based on the limitations and results of the project
include the following: using a voltage regulator that can accept a even low voltage, using a
direct current converter that is manipulated by PWM to be able to provide a more accurate
DC-DC converter output voltage, and building all the circuit in one PCB to reduce the circuit
power consumption.
All in all, this project has proposed and implemented a MPPT method that needs only the
measurements of current and voltage. The method is a modification of the Perturb and
Observe method, and it works by trailing and determining the maximum power and then
using the values to take over the extracted power directly from the photovoltaic. This system
enhances efficiency as it facilitates the harvesting of maximum quantity of power that a solar
panel can produce. |
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