Evaluating Power Loss and Performance Ratio of Hot-Spotted Photovoltaic Modules

IEEE Trans. Electron Devices

2019

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Hot-spotting is a reliability problem influencing photovoltaic (PV) modules, where a mismatched solar cell/cells heat up significantly and reduce the output power of the affected PV module. Therefore, in this paper, a succinct comparison of seven different state-of-the-art MPPT techniques are demonstrated, doing useful comparisons with respect to amount of power extracted, hence calculate their tracking accuracy. The MPPT techniques have been embedded into a commercial off-the-shelf MPPT unit, accordingly running different experiments on multiple hot-spotted PV modules. Furthermore, the comparison includes real-time long-term data measurements over several days and months of validation. Evidently, it was found that both fast changing MPPT (FC-MPPT) and the modified beta (M-Beta) techniques are best to use with PV modules affected by hot-spotted solar cells as well as during partial shading conditions, on average, their tracking accuracy ranging from 92% to 94%. Ultimately, the minimum tracking accuracy is below 93% obtained for direct PWM voltage controller (D-PWM-VC) MPPT technique.

Section: Performance Ratio Analysismentioning

confidence: 99%

Assessing MPPT Techniques on Hot-Spotted and Partially Shaded Photovoltaic Modules: Comprehensive Review Based on Experimental Data

IEEE Trans. Electron Devices

2019

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“…So as to examine the cracks in solar cells, multiple methods have been proposed. One of the first methods is the Resonance ultrasonic vibrations (RUV) which is developed by [1] and [2]. This method uses ultrasonic vibrations of a tenable frequency of an optical sensor.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast High-Resolution Solar Cell Cracks Detection Process

Mather

2020

IEEE Trans. Ind. Inf.

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This paper presents the advancement of an ultrafast high-resolution cracks detection in solar cells manufacturing system. The aim of the developed process is to (i) improve the quality of the calibrated image taken by a low-cost conventional electroluminescent (EL) imaging setup, (ii) proposing a novel methodology to enhance the speed of the detection of the solar cell cracks, and finally (iii) develop a proper procedure to decide whether to accept or reject the solar cell due to the existence of the cracks. The proposed detection process has been validated on various cracked/free-crack solar cell samples, evidently it was found that the cracks type, size and orientation are more visible using the proposes method, while the speed of calibrating the EL images are in the range of 0.1s to 0.3s, excluding the EL imaging time.

“…PV Hot-spots can easily be detected through IR inspection, which has become a common practice in current PV application as presented in [10]. However, the impact of hot-spot on the operation and performance of PV modules have been extensively investigated and addressed, which helps us to explain why there is a lack of accepted approaches which deal with hot-spotting, as well as specific criterion referring to the acceptance or rejection of affected PV module/s in commercial systems.…”

Section: Introductionmentioning

confidence: 99%

70% Decrease of Hot-Spotted Photovoltaic Modules Output Power Loss Using Novel MPPT Algorithm

IEEE Trans. Circuits Syst. II

2019

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The phenomenon of 'Hot-spotting' within photovoltaic (PV) panels, where a mismatched cell/cells heats up, leads to reliability and efficiency issues. In this paper, a novel maximum power point tracking (MPPT) algorithm is developed to compensate for hot-spotted PV module effects, thus increasing the output power and improving reliability. The MPPT algorithm implements two mitigation processes; the first to identify the optimum power-voltage (P-V) curve to track the global maximum power point (GMPP). The second process is to manipulate the output power towards the GMPP through the control of the perturbation step size. In order to verify the appropriateness of the proposed algorithm, multiple hot-spotted PV modules were tested under various environmental conditions. Significantly, the algorithm reduces the hot-spotted PV modules output power loss by at least 70% under all irradiance transition scenarios, slow, medium, and fast.