Optimal sizing of stand-alone hybrid energy system for development of rural and remote areas in Saudi Arabia

Q1 Environmental Science

Case Studies in Chemical and Environmental Engineering Pub Date : 2025-07-12 DOI:10.1016/j.cscee.2025.101257

Mubarak Alanazi

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Abstract

The availability of energy and water, which are required for the activities of the main residents, is essential to the development of rural areas. The demand for power is rising as a result of the ongoing population growth and the desire to develop these isolated locations. However, the adoption of renewable energy sources increased as a result of the scarcity of fossil fuels in these isolated places and the expensive cost of grid extensions. To develop these isolated desert locations, a hybrid renewable energy system (HRES) consisting of a diesel generator (DG), battery (B), wind turbine (WT), and solar panel (PV) is proposed. Battery storage and diesel generators operate as backup supplies in a stand-alone system, working in combination with other hybrid renewable energy system components. The expected electricity demands for ten dwellings in a small rural community in Hafar Al Batin, Saudi Arabia, are provided by this system. The seasonal and daily load curves of the suggested community are assessed. This community needs an electrical load of 53 kW. The optimal hybrid energy system combination for the proposed site is determined using HOMER Software, harmonizing reliability, cost, and minimal use of DG sets. The simulation results indicate that, despite the significant potential of wind and solar energies at the selected site, it was not adequate for an independent wind turbine system and a PV system. Thus, a storage battery or another form of energy conversion, like a diesel generator, is required. The results demonstrated that the cost of energy (COE) produced by the optimal hybrid WT/PV/DG/B system is 0.213 $/kWh. The ideal system comprises 20 kW PV panels, 330 kW WT, 58 kW DG, and 158 batteries, which can meet the electric load. The net present cost (NPC) of this optimal system is $ 628,571. Including a storage capacity is essential in order to minimize how often the DG operates and the number of hours it runs.

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沙特阿拉伯农村和偏远地区发展单机混合能源系统的最佳规模

主要居民活动所需的能源和水的供应对农村地区的发展至关重要。由于人口的持续增长和开发这些偏远地区的愿望，对电力的需求正在上升。然而，由于这些偏远地区化石燃料的稀缺和电网扩展的昂贵成本，可再生能源的采用有所增加。为了开发这些孤立的沙漠地区，提出了一种由柴油发电机（DG）、电池(B)、风力涡轮机（WT）和太阳能电池板（PV）组成的混合可再生能源系统（HRES）。电池存储和柴油发电机在独立系统中作为备用电源，与其他混合可再生能源系统组件一起工作。该系统可满足沙特阿拉伯Hafar Al Batin一个小型农村社区10户住宅的预期用电需求。评估了建议社区的季节和日负荷曲线。这个社区需要53千瓦的电力负荷。使用HOMER软件确定拟建站点的最佳混合能源系统组合，协调可靠性、成本和DG机组的最小使用。仿真结果表明，尽管所选场地的风能和太阳能潜力巨大，但对于独立的风力发电系统和光伏发电系统来说，这是不够的。因此，需要一个蓄电池或另一种形式的能量转换，如柴油发电机。结果表明，最优的WT/PV/DG/B混合系统产生的能量成本（COE）为0.213美元/千瓦时。理想的系统包括20千瓦的光伏板，330千瓦的WT， 58千瓦的DG和158个电池，可以满足电力负荷。该最优系统的净当前成本（NPC）为628,571美元。为了尽量减少DG运行的频率和运行的小时数，包括存储容量是必不可少的。

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