Photovoltaic System Conversion

Vázquez, N.; Vázquez, Jeziel

doi:10.1016/b978-0-12-811407-0.00026-x

Cited by 9 publications

(5 citation statements)

References 27 publications

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“…In comparison to polycrystalline silicon and thin-film solar cells, monocrystalline solar cells are more sensitive to temperature; when operating at temperatures over 25 °C, their maximum output power may be reduced by 15 % in monocrystalline solar cells and by 5 % in thin-film solar cells. [201] Shading losses Shading loss happens when nearby buildings, trees, or other things shadow PV modules. Because the PV module's output current is a function of solar irradiance, a fall in solar irradiance due to partial or total shade will impair the PV module's performance.…”

Section: Mismatch Lossmentioning

confidence: 99%

“…In contrast, the short‐circuit current is remarkably stable. In comparison to polycrystalline silicon and thin‐film solar cells, monocrystalline solar cells are more sensitive to temperature; when operating at temperatures over 25 °C, their maximum output power may be reduced by 15 % in monocrystalline solar cells and by 5 % in thin‐film solar cells [201] …”

Section: Energy Losses In Bipv System and Ev Chargingmentioning

confidence: 99%

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Review of Building Integrated Photovoltaics System for Electric Vehicle Charging

Khan,

Sudhakar,

Hazwan Yusof

et al. 2024

The Chemical Record

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The transition to sustainable transportation has fueled the need for innovative electric vehicle (EV) charging solutions. Building Integrated Photovoltaics (BIPV) systems have emerged as a promising technology that combines renewable energy generation with the infra‐structure of buildings. This paper comprehensively reviews the BIPV system for EV charging, focusing on its technology, application, and performance. The review identifies the gaps in the existing literature, emphasizing the need for a thorough examination of BIPV systems in the context of EV charging. A detailed review of BIPV technology and its application in EV charging is presented, covering aspects such as the generation of solar cell technology, BIPV system installation, design options and influencing factors. Furthermore, the review examines the performance of BIPV systems for EV charging, focusing on energy, economic, and environmental parameters and their comparison with previous studies. Additionally, the paper explores current trends in energy management for BIPV and EV charging, highlighting the need for effective integration and recommending strategies to optimize energy utilization. Combining BIPV with EV charging provides a promising approach to power EV chargers, enhances building energy efficiency, optimizes the building space, reduces energy losses, and decreases grid dependence. Utilizing BIPV‐generated electricity for EV charging provides electricity and fuel savings, offers financial incentives, and increases the market value of the building infrastructure. It significantly lowers greenhouse gas emissions associated with grid and vehicle emissions. It creates a closed‐loop circular economic system where energy is produced, consumed, and stored within the building. The paper underscores the importance of effective integration between Building Integrated Photovoltaics (BIPV) and Electric Vehicle (EV) charging, emphasizing the necessity of innovative grid technologies, energy storage solutions, and demand‐response energy management strategies to overcome diverse challenges. Overall, the study contributes to the knowledge of BIPV systems for EV charging by presenting practical energy management, effectiveness and sustainability implications. It serves as a valuable resource for researchers, practitioners, and policymakers working towards sustainable transportation and energy systems.

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Section: Mismatch Lossmentioning

confidence: 99%

Section: Energy Losses In Bipv System and Ev Chargingmentioning

confidence: 99%

Review of Building Integrated Photovoltaics System for Electric Vehicle Charging

Khan,

Sudhakar,

Hazwan Yusof

et al. 2024

The Chemical Record

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“…Centralised local energy management allows the power supply to be maintained throughout the day despite fluctuations in climatic conditions and variations in load consumption [34]. The battery lifetime is also preserved by maintaining the charge within acceptable limits [35].…”

Section: Electrical Architecturementioning

confidence: 99%

Decentralised strategy for energy management of collaborative microgrids using multi‐agent system

2022

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In this study, the concept of collaborative microgrids (MGs) with shareable resources is introduced. The developed concept enables the householders of an isolated district or neighbourhood to cooperate and communicate intelligently in order to establish a reliable and proprietary MG. Therefore, a multi-agent system solution for a distributed energy management system is designed. The proposed approach should first supply households while maintaining MG stability. Second, it offers designers decent programing flexibility and ensures system adaptability when households are added or removed. Three agents are developed, the nanogrid (NG) agent which handles the centralised energy management of the NG and messages the Master agent with the necessary information. The Master agent is responsible for the decentralised management of energy over the microgrid and controls the switches. The management strategy using multi-agent systems aims to encourage customers considered as NG to contribute energy to the MG. The strategy relies on the implementation of a point-based remuneration model in which the collected points depend on the contribution. The results highlight the importance of the proposed approach, which can be exploited to connect and supply isolated facilities intelligently.This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…Waidyasekara and Harshini Mallawaarachchi utility grid. Componenets of grid-tied PV system consist of PV arrays connected to the utility grid by means of power conditioning unit (Vázquez and Vázquez, 2018). This is alos known as the inverter, which is the primary component of grid-tied PV system (Bhatia, 2014).…”

Section: Grid-tied Pv Technology For Carbon Emission Reductionmentioning

confidence: 99%

Assessing the Carbon Emission Reduction by Grid-Tied Photovoltaic (Pv) Technology for Buildings in Sri Lanka

Ganegodage¹,

Waidyasekara²,

Mallawaarachchi³

2021

Proceedings of the 9th World Construction Symposium 2021 on Reshaping Construction: Strategic, Structural and Cultural Transfor

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Energy related carbon emission of buildings is a major cause of global warming. In order to mitigate energy related carbon emission, buildings tend to adopt renewable energy technologies. Amongst renewable energy technologies, grid-tied PV technology has gained the interest of building energy consumers as an alternative energy source. Nevertheless, there is considerably low implementation of grid-tied PV technology in Sri Lanka, especially as a carbon reduction strategy. A key reason for lack of implementation of grid-tied PV system is that majority of buildings still depend on traditional energy sources for their total energy needs. Hence, there is a need of highlighting the importance of grid-tied PV system to penetrate the existing traditional energy market. The aim of this study is therefore to assess the possible energy related carbon reduction of grid-tied PV system for buildings in Sri Lanka. Accordingly, total of four (4) buildings were selected as case studies, including two buildings with grid-tied PV technology and two other buildings that are totally dependent on traditional energy sources. Subsequently, carbon footprint assessment was conducted to four (4) buildings specifying to energy related carbon emitting activities. And research findings revealed that selected two buildings with grid-Tied PV technology achieve an average reduction of carbon by 3379.77kg and 3013.06kg respectively per month compared to traditional-energy buildings. Consequently, this work has successfully identified that buildings with grid-tied PV technology achieve a reduction in energy related carbon emission compared to buildings with traditional energy sources.

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Photovoltaic System Conversion

Cited by 9 publications

References 27 publications

Review of Building Integrated Photovoltaics System for Electric Vehicle Charging

Review of Building Integrated Photovoltaics System for Electric Vehicle Charging

Decentralised strategy for energy management of collaborative microgrids using multi‐agent system

Assessing the Carbon Emission Reduction by Grid-Tied Photovoltaic (Pv) Technology for Buildings in Sri Lanka

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