Calculation of the Shading Factors for Solar Modules with MATLAB

Silva, Martín; Roberts, Justo J.; Prado, Pedro Osvaldo

doi:10.3390/en14154713

Cited by 13 publications

(2 citation statements)

References 18 publications

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“…The Shading Factor is the shaded fraction of the PV field with respect to the full sensitive area for a given sun orientation (values 0 = no shaded, 1 = fully shaded). The direct shading factor f B is defined as the ratio of the shaded area A S and the area of the module A M , as shown in Equation (10) [55]. When the shadow covers the module entirely, A S is equal to A M , and f B is 1.…”

Section: Design Of Envelope Structures To Improve Conditionsmentioning

confidence: 99%

Mutual Interaction of Daylight and Overheating in the Attic Space in Summer Time

et al. 2022

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The classroom space located in the attic of an old building is the subject of this study. The building was renovated and new spaces were created in the unused attic to expand classrooms. The original space under the sloping roof was not used because its internal headroom was not suitable. During the restoration, the entire original truss was raised gradually (in parts) by 1.2 m. This created a space with an entire area that can be used for classrooms. Continuous strips of vertical windows measuring 860/600 mm were installed in the space which enable a visual connection between the interior space and the exterior. At roof level, there are also two rows of skylights above each other which ensure enough daylight is present but create unpleasant overheating in the summer. The purpose of this study is to find a way to optimize the shading of transparent surfaces and the heat accumulation of building structures in order to achieve suitable interior conditions in the attic. This task was achieved by shading the windows in the attic. Shaded windows decrease illumination by 82% compared to unshaded ones. The percentage decrease in illumination is more significant than the decrease in the maximum temperature due to overheating. Additionally, the maximum temperature in the attic drops by only 31% if vertical and skylight windows are shaded with external blinds compared to unshaded windows. The minimum air temperature reached in the attic also drops by 26%. In order for users in the attic space to feel comfortable, it is necessary to use HVAC equipment in addition to the design of suitably built structures and window shading.

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Section: Design Of Envelope Structures To Improve Conditionsmentioning

confidence: 99%

Mutual Interaction of Daylight and Overheating in the Attic Space in Summer Time

et al. 2022

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“…Therefore, given the evident differences in shadow properties caused by shading, it becomes apparent that the standard simulation models utilized by PVSyst version 7.4, MATLAB version R2023a, and PVSol version 2023 R1 prove inadequate in accurately portraying shadow formation when assessing the resulting power loss from thin object shading. These simulations, restricted to single-intensity shadows, currently lack the capability to model precise shadow formations, thereby overlooking the coexistence of umbra and penumbra shadows in a single shadow formation [17].…”

Section: Introductionmentioning

confidence: 99%

Analysing the Effects of Thin Object Shading on PV Sources: A Dual Approach Combining Outdoor and Laboratory Solar Simulator Experimentation

Axisa,

Demicoli,

Mule’Stagno

2024

Energies

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The impact of shading has been a prominent subject of discourse within the realm of photovoltaic (PV) energy harvesting and is recognized as a significant detriment to the system’s overall efficiency. Nevertheless, prevailing investigations, which predominantly focus on the hard shading originating from building structures and vegetation, singularly address the umbra shadow phenomenon while overlooking the complexity of shadow properties and their varying intensities. In this context, this present research aims to analyze the impact of shading caused by thin objects, wherein shadow formation deviates from a singular-intensity umbra to a blend of umbra and penumbra, exhibiting diverse intensities. In the initial experimental approach, outdoor trials produced statistically significant findings, identifying both the distance and thickness of shading objects as primary determinants influencing the impact of thin object shading on the power output of PV systems. Furthermore, the analysis of the results revealed that under the specified parameters and assumptions, when considering a thin object with a thickness-to-distance ratio of 2.3 mm/225 cm, the resulting power loss of 1.65% is statistically insignificant. Remarkably, laboratory investigations unveiled a notable correlation between penumbra and power loss, contrasting with outdoor experimentation results. The findings highlight the distinction between indoor and outdoor methodologies, stemming from discrepancies in shadow formation characteristics, thereby emphasizing the necessity of acknowledging and comprehending these variations.

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Optimization of Agrivoltaic Plants: Development and Validation of a Numerical Model to Account for Shading Effects on Crop Yields

Costa,

Barba,

Piazzullo

et al. 2024

Lecture Notes in Networks and Systems

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Calculation of the Shading Factors for Solar Modules with MATLAB

Cited by 13 publications

References 18 publications

Mutual Interaction of Daylight and Overheating in the Attic Space in Summer Time

Mutual Interaction of Daylight and Overheating in the Attic Space in Summer Time

Analysing the Effects of Thin Object Shading on PV Sources: A Dual Approach Combining Outdoor and Laboratory Solar Simulator Experimentation

Optimization of Agrivoltaic Plants: Development and Validation of a Numerical Model to Account for Shading Effects on Crop Yields

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