提高液化天然气存储方案的效率:探索增强型能源存储解决方案的热性能

Energy Storage Pub Date : 2024-10-22 DOI:10.1002/est2.70049
Muntadher Nahi Salman, Seyyed Faramarz Ranjbar, Moharram Jafari, Faramarz Talati
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引用次数: 0

摘要

能源行业的持续转型需要更高效、更可靠的能源储存解决方案。我们的研究通过优化液化天然气(LNG)存储的工业流程来满足这一需求,重点是提高热性能和能效。利用标准液化天然气存储设计,我们对关键支持变量进行了细致评估,对关键组件进行了建模,并进行了综合循环模拟。主要目标是在保持最佳储存条件的同时,最大限度地减少储存气体的体积(减少到气态的约 1/600)。我们的方法优先考虑大型储气罐的隔热性能,而不是承压因素,这与液化天然气储藏所面临的独特热挑战是一致的。模拟以甲烷为基础,甲烷占中东地区天然气的 86%,确保了与该地区资源的相关性。模拟结果很有希望,压缩级的最大压力为 2.377,能效比为 60.71%,性能系数为 3.188。这些研究结果为开发更有效、更高效的液化天然气储存系统迈出了重要一步,有助于实现更广泛的可持续能源管理目标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficiency Enhancement in the Liquefied Natural Gas Storage Scheme: Exploring Thermal Performance for Enhanced Energy Storage Solutions

The ongoing transition in the energy sector demands more efficient and reliable energy storage solutions. Our study addresses this need by optimizing the industrial process of liquefied natural gas (LNG) storage, focusing on enhancing thermal performance and energy efficiency. Leveraging a standard LNG storage design, we meticulously evaluated critical supporting variables, modeled key components, and conducted integrated cycle simulations. The primary goal was to minimize the volume of stored gas (achieving a reduction to approximately 1/600th of its gaseous state) while maintaining optimal storage conditions. Our methodology prioritizes insulation over pressure-bearing factors in large-scale tanks, aligning with the unique thermal challenges of LNG storage. Simulations were based on methane, which constitutes over 86% of the natural gas in the Middle East, ensuring relevance to the region's resources. The results are promising, with a compression stage reaching a maximum pressure of 2.377, an energy efficiency ratio of 60.71%, and a performance coefficient of 3.188. These findings offer a significant step forward in developing more effective and efficient LNG storage systems, contributing to the broader goal of sustainable energy management.

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