Thermal Infrared and Visual Inspection of Photovoltaic Installations by UAV Photogrammetry—Application Case: Morocco

Zefri, Yahya; ElKettani, Achraf; Sebari, İmane; Lamallam, Sara Ait

doi:10.3390/drones2040041

Cited by 80 publications

(53 citation statements)

References 31 publications

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“…107 A qualitative survey of the soiling distribution at a plant can also be conducted through visual terrestrial or aerial (drone and satellites) inspection of the field or by advanced solar field performance analysis (e.g., monitoring on module-level), with new methods being continuously developed. 50,[110][111][112] Cost Estimates for Soiling Mitigation Technologies From the data presented in Impact on Global Solar Power Production and Energy Costs, rough estimates for a positive net present value (NPV), at which soiling mitigation technologies become economically feasible, were calculated assuming different efficiencies for the reduction of soiling rates, see Table 1.…”

Section: Pv Module Designmentioning

confidence: 99%

Techno-Economic Assessment of Soiling Losses and Mitigation Strategies for Solar Power Generation

Ilse

Micheli

Figgis

et al. 2019

Joule

257

123

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Soiling consists of the deposition of contaminants onto photovoltaic (PV) modules or mirrors and tubes of concentrated solar power systems (CSPs). It often results in a drastic reduction of power generation, which potentially renders an installation economically unviable and therefore must be mitigated. On the other hand, the corresponding costs for cleaning can significantly increase the price of energy generated. In this work, the importance of soiling is assessed for the global PV and CSP key markets. Even in optimized cleaning scenarios, soiling reduces the current global solar power production by at least 3%-4%, with at least 3-5 billion V annual revenue losses, which could rise to 4%-7%, and more than 4-7 billion V losses, in 2023. Therefore, taking into account the underlying physics of natural soiling processes and the regional cleaning costs, a techno-economic assessment of current and proposed soiling mitigation strategies such as innovative coating materials is presented. Accordingly, the research and development needs and challenges in addressing soiling are discussed.

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Section: Pv Module Designmentioning

confidence: 99%

Techno-Economic Assessment of Soiling Losses and Mitigation Strategies for Solar Power Generation

Ilse

Micheli

Figgis

et al. 2019

Joule

257

123

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“…The integration of thermal sensors with drones opens up new possibilities for real-time aerial inspection in many fields. The substantial capture capability of the UAV platforms allows their application in thermal inspection of large areas (e.g., vegetation studies and precision agriculture [43][44][45], hydrological [46] or industrial inspections, such as those of photovoltaic farms [47,48]). The study of building envelopes is perhaps where the fusion of IRT and UAV technologies has the greatest potential [49][50][51][52].…”

Section: Aerial Irt Inspectionmentioning

confidence: 99%

IR Thermography from UAVs to Monitor Thermal Anomalies in the Envelopes of Traditional Wine Cellars: Field Test

et al. 2019

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Infrared thermography (IRT) techniques for building inspection are currently becoming increasingly popular as non-destructive methods that provide valuable information about surface temperature (ST) and ST contrast (delta-T). With the advent of unmanned aerial vehicle (UAV)-mounted thermal cameras, IRT technology is now endowed with improved flexibility from an aerial perspective for the study of building envelopes. A case study cellar in Northwest (NW) Spain is used to assess the capability and reliability of low-altitude passive IRT in evaluating a typical semi-buried building. The study comparatively assesses the use of a pole-mounted FLIR B335 camera and a drone-mounted FLIR Vue Pro R camera for this purpose. Both tested IRT systems demonstrate good effectiveness in detecting thermal anomalies (e.g., thermal bridges, air leakages, constructive singularities, and moisture in the walls of the cellar) but pose some difficulties in performing accurate ST measurements under real operating conditions. Working with UAVs gives great flexibility for the inspection, but the angle of view strongly influences the radiometric data captured and must be taken into account to avoid disturbances due to specular reflections.

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“…Therefore, modelling and sensing imaging provide complementary information on the PV system. Many research efforts [19][20][21] have been devoted to link temperature patterns to fault typology and photogrammetric studies performed with aerial thermographic inspection [22,23] have become more popular.…”

Section: Introductionmentioning

confidence: 99%

On Field Infrared Thermography Sensing for PV System Efficiency Assessment: Results and Comparison with Electrical Models

Muttillo

Nardi

Stornelli

et al. 2020

Sensors

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The evaluation of photovoltaic (PV) system’s efficiency loss, due to the onset of faults that reduce the output power, is crucial. The challenge is to speed up the evaluation of electric efficiency by coupling the electric characterization of panels with information gathered from module diagnosis, amongst which the most commonly employed technique is thermographic inspection. The aim of this work is to correlate panels’ thermal images with their efficiency: a “thermal signature” of panels can be of help in identifying the fault typology and, moreover, for assessing efficiency loss. This allows to identify electrical power output losses without interrupting the PV system operation thanks to an advanced PV thermography characterization. In this paper, 12 faulted working panels were investigated. Their electrical models were implemented in MATLAB environment and developed to retrieve the ideal I-V characteristic (from ratings), the actual (operative) I-V characteristics and electric efficiency. Given the curves shape and relative difference, based on three reference points (namely, open circuit, short circuit, and maximum power points), faults’ typology has been evidenced. Information gathered from infrared thermography imaging, simultaneously carried out on panels during operation, were matched with those from electrical characterization. Panels’ “thermal signature” has been coupled with the “electrical signature”, to obtain an overall depiction of panels’ health status.

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Thermal Infrared and Visual Inspection of Photovoltaic Installations by UAV Photogrammetry—Application Case: Morocco

Cited by 80 publications

References 31 publications

Techno-Economic Assessment of Soiling Losses and Mitigation Strategies for Solar Power Generation

Techno-Economic Assessment of Soiling Losses and Mitigation Strategies for Solar Power Generation

IR Thermography from UAVs to Monitor Thermal Anomalies in the Envelopes of Traditional Wine Cellars: Field Test

On Field Infrared Thermography Sensing for PV System Efficiency Assessment: Results and Comparison with Electrical Models

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