优化能源管理的集成监控和数据采集系统:利用光伏和相变材料蓄热

Energy Storage Pub Date : 2024-09-02 DOI:10.1002/est2.70035
Muhammad Shehram, Muhammad Najwan Hamidi, Aeizaal Azman Abdul Wahab, Mohd Khairunaz Mat Desa
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引用次数: 0

摘要

可靠的能源对于经济增长和生活质量都至关重要。在发展中国家,昂贵的燃料往往是主要的能源来源,因此政府正在探索创新的解决方案,如基于物联网的小规模项目,以实现建筑物的能源独立。本研究调查了可再生能源技术、统计建模、云计算和物联网的整合情况,以开发一种用于建筑物的自我管理系统。该系统优先使用可再生能源,特别是效率为 20% 的单晶硅太阳能电池和效率为 90% 且能量损失最小的平板集热器。热能储存在石蜡中,因为石蜡具有高储存效率和热特性。该系统还采用了性能系数(COP)较高的吸收式制冷机,利用太阳能热能提供制冷。大楼的能源负荷分为 A、B、C 和 D 四类,每一类都同时利用光伏和热能。SCADA 系统负责监督运行,监控这些负载的开关状态。该系统设计用于连续运行,使用 Anaconda Jupyter Notebook 和 Python 进行模拟。该模型旨在为建筑物提供可持续的高效能源解决方案,在满足能源需求的同时优化能源使用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Integrated Supervisory Control and Data Acquisition System for Optimized Energy Management: Leveraging Photovoltaic and Phase Change Material Thermal Storage

Reliable energy sources are crucial for both economic growth and quality of life. In developing countries, where expensive fuels are often the primary energy source, governments are exploring innovative solutions like small-scale, IoT-based projects to achieve energy independence in buildings. This research investigates the integration of renewable energy technologies, statistical modeling, cloud computing, and IoT to develop a self-managing energy system for buildings. The system prioritizes renewable sources, specifically monocrystalline solar cells with 20% efficiency for photovoltaic (PV) energy and flat plate collectors with 90% efficiency and minimal energy loss for thermal energy. Thermal energy is stored in paraffin wax, chosen for its high storage efficiency and thermal properties. The system also utilizes an absorption chiller with a high coefficient of performance (COP) to provide cooling using solar thermal energy. The building's energy loads are categorized as A, B, C, and D, each utilizing both PV and thermal energy. A SCADA system oversees the operation, monitoring the on–off status of these loads. The system is designed for continuous operation, with simulations conducted using Anaconda Jupyter Notebook and Python. This model aims to offer a sustainable and efficient energy solution for buildings, meeting energy demands while optimizing energy use.

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