Design, development and performance analysis of FSPV system for powering sustainable energy based mini micro-grid.

IF 1.6 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Microsystem Technologies-Micro-And Nanosystems-Information Storage and Processing Systems Pub Date : 2023-04-21 DOI:10.1007/s00542-023-05457-2

Sagnik Bhattacharya, Anik Goswami, Pradip Kumar Sadhu

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Abstract

The Floating Solar Photovoltaic System (FSPV) is emerging as a favorable technology to policymakers for economically harvesting renewable energy. The implementation of large-scale photovoltaic (PV) systems is often disrupted due to the unavailability of land. The FSPV systems, where the PV modules are floated in water bodies facilitate optimal utilization of water resources and land assets. The FSPV provides higher power output compared to land-based PV systems of the equal area because of improved energy conversion efficiency at a lower temperature. Another opportunity for the FSPV system is integration with hydropower stations, storage systems, and the electric grid. This paper explores the flood duration curve-based optimal sizing of the FSPV System with the objective of electrification of rural micro-grid. A comparison of energy output and module temperature rise has been made for the FSPV system and its equivalent land-based PV system of equal area. The system generates 18.08 GWh, which is 10.04% more than the land-based PV system. The DC Capacity factor is 17.2%. The Demand Supply Factor (DSF) for a particular day in winter, spring, summer, and monsoon is 37.55%, 41.7%, 45.9%, and 25% respectively. The results indicate that the FSPV system is a sustainable alternative to power renewable energy-based mini micro-grid and provide cost effective electricity to all.

Abstract Image

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基于可持续能源的微型电网FSPV系统的设计、开发和性能分析。

浮动太阳能光伏系统（FSPV）正在成为决策者经济地获取可再生能源的有利技术。大规模光伏系统的实施经常因土地不可用而中断。FSPV系统中，光伏组件漂浮在水体中，有助于水资源和土地资产的最佳利用。与相同面积的陆基光伏系统相比，FSPV提供了更高的功率输出，这是因为在较低温度下提高了能量转换效率。FSPV系统的另一个机会是与水电站、存储系统和电网集成。本文以农村微电网电气化为目标，探讨了基于洪水历时曲线的FSPV系统优化规模。对FSPV系统及其等效等面积陆基光伏系统的能量输出和模块温升进行了比较。该系统的发电量为18.08 GWh，比陆基光伏系统多出1004%。直流容量系数为17.2%。冬季、春季、夏季和季风特定日期的需求-供应系数（DSF）分别为37.55%、41.7%、45.9%和25%。结果表明，FSPV系统是基于可再生能源的微型电网的可持续替代方案，并为所有人提供经济高效的电力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microsystem Technologies-Micro-And Nanosystems-Information Storage and Processing Systems 工程技术-材料科学：综合

CiteScore

5.20

自引率

9.50%

发文量

147

审稿时长

3.3 months

期刊介绍： "Microsystem Technologies - Micro- and Nanosystems. Information Storage and Processing Systems" is intended to provide rapid publication of important and timely results on electromechanical, materials science, design, and manufacturing issues of these systems and their components. The MEMS/NEMS (Micro/NanoElectroMechanical Systems) area includes sensor, actuators and other micro/nanosystems, and micromechatronic systems integration. Information storage systems include magnetic recording, optical recording, and other recording devices, e.g., rigid disk, flexible disk, tape and card drives. Processing systems include copiers, printers, scanners and digital cameras. All contributions are of international archival quality. These are refereed by MST editors and their reviewers by rigorous journal standards. The journal covers a wide range of interdisciplinary technical areas. It brings together and cross-links the knowledge, experience, and capabilities of academic and industrial specialists in many fields. Finally, it contributes to the economically and ecologically sound production of reliable, high-performance MEMS and information storage & processing systems.