Life-cycle Cost Analysis for a hydroelectric energy system

2022 Advances in Science and Engineering Technology International Conferences (ASET) Pub Date : 2022-02-21 DOI:10.1109/ASET53988.2022.9739743

Amer Aldawoud, Abdelsalam Aldawoud, Mamdouh El Haj Assad

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引用次数: 2

Abstract

Energy is a critical factor in contributing to the growth of many developing and developed countries worldwide. Hydroelectric energy remains one of the most vital renewable energy sources worldwide as it contributes to more than 16% of the global electricity generation. The study investigates the impact of varying the masses of sandstone, basalt, and limestone on reducing the energy, CO2 footprint, and overall costs of the system. Additionally, 6 different alternatives with varying masses of sandstone, basalt, and limestone were investigated. In this study, alternative 5 involved increasing the mass of limestone and decreasing the mass of the basalt. It was found that this resulted in the lowest CO2 footprint and total energy. Furthermore, alternative 2 involved increasing the mass of sandstone and decreasing the mass of the basalt. The study results show that alternative 2 was found to yield the lowest cost; however, it was relatively close to the cost found in alternative 5. In order to further reduce the CO2 footprint and total energy of the system, end-of-life (EOL) was investigated for alternative 5. The EOL potential successfully reduced the total energy and CO2 footprint by 3.1 MJ and 203 tonnes, respectively.

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水电能源系统全寿命周期成本分析

能源是促进全世界许多发展中国家和发达国家增长的一个关键因素。水力发电仍然是世界上最重要的可再生能源之一，它占全球发电量的16%以上。该研究调查了不同质量的砂岩、玄武岩和石灰石对减少能源、二氧化碳足迹和系统总成本的影响。此外，研究人员还研究了6种不同的砂岩、玄武岩和石灰石质量的替代方案。在这项研究中，备选方案5涉及增加石灰石的质量，减少玄武岩的质量。结果发现，这导致了最低的二氧化碳足迹和总能源。此外，备选方案2涉及增加砂岩的质量，减少玄武岩的质量。研究结果表明，替代方案2的成本最低;然而，它相对接近替代方案5的成本。为了进一步减少系统的二氧化碳足迹和总能量，对备选方案5进行了寿命终止(EOL)研究。EOL的潜力成功地将总能源和二氧化碳足迹分别减少了3.1兆焦耳和203吨。

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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2022 Advances in Science and Engineering Technology International Conferences (ASET)

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