Prediction of Power Output from a Crystalline Silicon Photovoltaic Module with Repaired Cell-in-Hotspots

Lee, Koo; Cho, Sung-Bae; Yi, Junsin; Chang, Hyo Sik

doi:10.3390/electronics11152307

Cited by 5 publications

(4 citation statements)

References 49 publications

(60 reference statements)

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“…According to the previous study, in the restoration of the back surface field (BSF) type cell, which is an early model of the crystalline silicon solar cell, almost no decrease in output due to cell deterioration was observed. [30] The cell taken for this experiment was of passivated emitter rear contact (PERC) type, which was the next generation of BSF cells, and in this case, it was found that the higher the initial efficiency, the higher the degradation rate of the cell when the module is restored. The decrease in output was mainly caused by a decrease in V mp , which can be found in the increase of series resistance elements due to cell deterioration.…”

Section: Resultsmentioning

confidence: 96%

Effect of Solder Flux on Resistive Solder Bond Hotspot Generation in Photovoltaic Module Circuit Process and Restoration of Hotspot Module

Han

Cho

et al. 2023

Energy Tech

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In photovoltaic (PV) modules, resistive solder bond (RSB) hotspots are the primary cause for a reduction in output power of over 25%. They may be the result of inadequate soldering between the busbars and/or between the busbars and the interconnector ribbon during the circuit assembly procedure for the PV module. This study proposes a straightforward, dependable, and rapid method for reducing RSB hotspots in PV modules using additional solder flux during the circuit soldering process. The soldering of PV modules is examined in accordance with actual conditions present in PV module manufacturers during the manufacture of circuits. Using the tab pull test and the damp heat test, respectively, the bonding strength and dependability of the soldered connectors are evaluated. Connectors soldered with flux have a void ratio of 10% that is five times lower than connectors soldered without flux. In addition, connectors with flux decrease soldering strength by a range of −1.54% to −7.69%, whereas connectors without flux decrease soldering strength by a range of −17.39% to −29.31%. During long‐term reliability evaluations on repaired 370A and 370B samples, the RSB hotspots are substantially reduced by incorporating additional flux into the circuit process. In addition, the application of additional solder at the busbar to interconnetor ribbon soldering site prevents RSB hotspots effectively. The results are anticipated to provide comprehensive and straightforward solutions for significantly reducing RSB hotspot failures in commercial PV modules.

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Section: Resultsmentioning

confidence: 96%

Effect of Solder Flux on Resistive Solder Bond Hotspot Generation in Photovoltaic Module Circuit Process and Restoration of Hotspot Module

Han

Cho

et al. 2023

Energy Tech

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“…The loss due to the electrical mismatch of the cell has been published as a concept called RPL (relative power loss), which is not precisely defined and classified before the CTM factor [48]. RPL is expressed as the difference between the maximum power (Pmpc) of n individual cells connected in series to form a cell string or module and the output power of the cell string.…”

Section: Theoretical Background To Module Output Analysismentioning

confidence: 99%

“…In a previous study [48] that reported repairs of a waste module containing some damaged cells by replacing it with a new cell, it which was checked whether the same results were obtained even when the module type was different as a single crystal. The cell replacement experiment followed the sequence from previous studies.…”

Section: Basic Experiments According To Previous Research Proceduresmentioning

confidence: 99%

Effect of Cell Electrical Mismatch on Output of Crystalline Photovoltaic Modules

Park

Cho

Kim³

et al. 2022

Energies

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The importance of energy supply and demand has been emphasized over the past few years. Renewable energy without regional bias continues to attract attention. The improvement of the economic feasibility of renewable energy leads to the expansion of the supply, and the global supply of solar modules is also rapidly increasing. Recently, the price of polysilicon for solar modules is also rising significantly. Interest in recycling waste modules is also increasing. However, the development of cost-effective treatment technology for solar modules that have reached the end of their commercial useful life is still insufficient. We are going to propose the standards necessary to restore and reuse so-called waste solar modules in a more eco-friendly and economical way. A crystalline solar module is an aggregate of individual solar cells. The technology is stable and has good durability. The efficiency of crystalline solar cells has dramatically improved in recent decades. The grade of cell that was mainly used two or three years ago will be discontinued soon. Therefore, electrical mismatch of the cells occurs while repairing an old-manufactured module with recently produced cells. In this paper, we experimentally verify how the increase in cell mismatch affects the module output. We intend to suggest the range of acceptable mismatches by analyzing the tendency. First of all, we repaired and restored the module in which all the existing cells were discontinued after about 10 years of production. The replacement cell had 16.94% higher output than the existing cells. After restoring the module, it was confirmed that the electrical mismatch loss of the cell in this range was very small, about 1.69%. Second, the mismatch loss was confirmed by manufacturing a module by mixing the two cells. The difference in output between the two cells was 5.56%. The mismatch loss compared to the predicted value based on the output of the individual cell and the actual value was very small, less than 0.76%. The long-term reliability results through the DH 1000 hr experiment on the sample that simulated the situation of repair, and the rest of the samples also showed a decrease in output up to 1.13%, which was not a problem. Finally, we hypothesized that a series-connected array should be constructed by reusing modules with different output classes. By cutting into 1/4, 1/3, and 1/2 of cells of the same grade, various unit module samples composed of 0.5 cells to 2.0 cells were manufactured and the output was measured. Electrical mismatch loss was tested by serially combining each unit module at various mismatch ratios. It was confirmed that the output loss in the three or more samples similarly exceeds about 10% with the mismatch ratio of 50% as the starting point. In the previous study, when the mismatch ratio was 70%, the output loss was about 17.98%. The output loss was 18.30% at 86.57%, 17.33% at 77.33%, and 14.37% at 75%. Considering that it is a value measured in a wide range, it is a result that is quite consistent with the results of previous studies. When the cell output difference was less than 50%, the electrical mismatch of the cell had no significant effect on the module output. When it exceeds that, a sudden output loss of 10% or more begins to occur. Consequently, the mismatch range of compatible cells should be less than 50%. If it exceeds that, not only output loss but also safety problems may occur due to heat generation. We can offer a range of interchangeable cell output power when crystalline solar modules are repaired and reused. By recycling modules with different outputs, you can provide a standard for those who want to use it by composing an array. By extending the lifespan of a solar module once used, it is expected that the generation of waste can be reduced from environmental point of view and the resources required to manufacture a new module can be saved from the resource-circulation point of view.

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“…They could lead to electrically disconnected cell regions, causing a decrease in short-circuit current and shunt resistance 24 , subsequently reducing the module's power output 25 . Cracks may also develop in the PV module if there are localised hotspots 26,27 .…”

Section: Introductionmentioning

confidence: 99%

Investigating defects and annual degradation in UK solar PV installations through thermographic and electroluminescent surveys

Dhimish

Badran

2023

npj Mater Degrad

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As the adoption of renewable energy sources, particularly photovoltaic (PV) solar, has increased, the need for effective inspection and data analytics techniques to detect early-stage defects, faults, and malfunctions has become critical for maintaining the reliability and efficiency of PV systems. In this study, we analysed thermal defects in 3.3 million PV modules located in the UK. Our findings show that 36.5% of all PV modules had thermal defects, with 900,000 displaying single or multiple hotspots and ~250,000 exhibiting heated substrings. We also observed an average temperature increase of 21.7 °C in defective PV modules. Additionally, two PV assets with 19.25 and 8.59% thermal defects were examined for PV degradation, and results revealed a higher degradation rate when more defects are present. These results demonstrate the importance of implementing cost-effective inspection procedures and data analytics platforms to extend the lifetime and improve the performance of PV systems.

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Prediction of Power Output from a Crystalline Silicon Photovoltaic Module with Repaired Cell-in-Hotspots

Cited by 5 publications

References 49 publications

Effect of Solder Flux on Resistive Solder Bond Hotspot Generation in Photovoltaic Module Circuit Process and Restoration of Hotspot Module

Effect of Solder Flux on Resistive Solder Bond Hotspot Generation in Photovoltaic Module Circuit Process and Restoration of Hotspot Module

Effect of Cell Electrical Mismatch on Output of Crystalline Photovoltaic Modules

Investigating defects and annual degradation in UK solar PV installations through thermographic and electroluminescent surveys

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