A Comprehensive Workflow for High Resolution 3D Solar Photovoltaic Potential Mapping in Dense Urban Environment: A Case Study on Campus of Delft University of Technology

Zhou, Yilong; Verkou, Maarten; Zeman, Miro; Ziar, Hesan; Isabella, Olindo

doi:10.1002/solr.202100478

Cited by 5 publications

(1 citation statement)

References 31 publications

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“…This is true for the grid-connected PV system (Makinde et al, 2021). The study estimates that the roofs and facades of campus buildings can generate 8.1 GWh of PV energy per year, which can gather 10% of the current energy demand, with the campus as a whole requiring 82.6 GWh of electricity annually (Zhou, 2022). Table 6 presents a brief comparison of the previously conducted studies for monofacial PV-integrated buildings.…”

Section: Abdelhafez (2021) Simmentioning

confidence: 96%

Current prospects of building-integrated solar PV systems and the application of bifacial PVs

Abojela¹,

Desa²,

Sabry

2023

Front. Energy Res.

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Building-integrated solar photovoltaic (BIPV) systems have gained attention in current years as a way to recover the building’s thermal comfort and generate sustainable energy in building structures. BIPV systems can provide shade against sunshine while generating ancillary electrical power. Over the last decades, engineers have been trying to improve the efficiency of BIPV systems. BIPV systems with various installation types, including rooftop, balcony, curtain, sunshade, and wall façade types, are being constantly researched and intensively presented for improving power efficiency and reducing air-conditioning use. This work provides an overview of solar BIPV systems and focuses particularly on existing applications of the bifacial type of BIPV systems. The motivation and an overview of BIPV systems are first introduced, followed by the study methodology considered and the contributions. This work discusses PV technologies of bifacial PVs (monocrystalline and polycrystalline bifacial modules), BIPV installation [curtains, rooftop, flat rooftop, transparent faced, balcony windows (transparent), wall opaque facade, flat roof-faced, and skylight sunshade types], simulation and optimization software (simulation software and future trends), zero-energy BIPV technology, and optimization techniques of BIPV systems. Last, suggestion amendments to the current BIPV design that possibly contribute to growing the system’s effectiveness, reliability, and cost as future design theories for the whole system are presented.

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Section: Abdelhafez (2021) Simmentioning

confidence: 96%