Dynamic reconfiguration of large-scale PV plant using based on specified switching matrix and genetic algorithm to mitigate partial shading
Environmental conditions and non-uniform irradiations have a strong influence on the quality of the generated photovoltaic (PV) power. The non-uniform irradiance, also referred to as partial shading reduces the output power of the PV array, causes multiple peaks in its characteristics, reduce...
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| Format: | text::Thesis |
| Language: | English |
| Published: |
2023
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| Summary: | Environmental conditions and non-uniform irradiations have a strong influence on the
quality of the generated photovoltaic (PV) power. The non-uniform irradiance, also
referred to as partial shading reduces the output power of the PV array, causes multiple
peaks in its characteristics, reduce the lifetime of the PV array and the effectiveness of
the entire system. Several techniques have been proposed to solve the mismatch
problem, for example, the reconfiguration technique of PV panels. Most of the
reconfiguration techniques are limited for small systems due to the large number of
switches that are required for such applications. This thesis proposes a new
reconfiguration technique for PV plant to overcome the partial shading effects. The
reconfiguration technique relies on rearranging the PV arrays in order to disperse the
shading equally over the PV arrays. The proposed technique can be applied to a large
scale PV plant and is based on Total-Cross-Tie (TCT) in two reconfigurable stages. The
advantages of the proposed new reconfiguration technique include shade dispersion
between arrays and cost-effectiveness due to reduced number of switches and sensors
as compared to existing techniques. In the first stage, the shade is dispersed over the
PV plant by switching specific switches in the arrays. In the second stage, Genetic
Algorithm (GA) is applied to optimize the output, via rearranging the columns in PV
plants to find the optimal solution of reconfiguration. The major contribution of this
thesis is the adaptability of the proposed two-stage technique to an actual 50 MWpk
solar PV farm, which has not been covered in any literatures prior to this. To highlight
the viability of the concept, a portion of the PV plant rated at 2.5 MWpk was used in this
research. Finally, a comparison of the proposed reconfiguration technique with other
static and dynamic reconfiguration techniques was carried out under different shading
patterns using MATLAB/SIMULINK. A comparative study on performance analysis
such as mismatch losses, fill factor, power loss and percentage power enhancement, for
TCT configuration, SuDoKu, Competence Square, Two Phase, Particle Swarm
Optimization, Genetic Algorithm, Modified Harris Hawks Optimizer and the proposed
technique was carried out for each shading case. Also, energy-saving calculations and
total income generation are performed and compared with the TCT configuration. From
the results, the proposed reconfiguration technique enhances the generated power by 28
%, 3.3 %, 0.85 %, 0.85 % and 0.3 % over the TCT configuration, two-phase, SuDoKu,
PSO, and MHHO techniques respectively, for Case A. Meanwhile, Case B yielded a
higher Power Enhancement of 7 %, 1.3 %, 2 %, 4 % and 1.6 % for the proposed
reconfiguration technique when compared to the TCT configuration, two-phase,
SuDoKu, PSO, and MHHO techniques, respectively. The proposed technique also
reduced the mismatch of power loss and solved the multiple peaks. In addition, the
proposed technique demonstrated superiority over static and dynamic reconfiguration
techniques. |
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