Novel supercritical CO2-Based Low-Carbon multigeneration System: Multi-Objective optimization for combined Power, Cooling, Heating, and desalination

IF 7.1 Q1 ENERGY & FUELS
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引用次数: 0

Abstract

The challenges posed by power shortages, hot climates, heating demands, and water scarcity on island platforms significantly impede productivity and quality of life. Implementing a multi-energy supply system emerges as a promising solution to address these issues. In this study, we propose, analyze, and optimize a novel multigeneration system for cooling, heating, power, and desalinated water production, leveraging waste heat from a nuclear power plant. This innovative system integrates a recompression supercritical CO2 (sCO2) Brayton cycle, an Organic Rankine Cycle (ORC) with a booster-enhanced ejector refrigeration cycle (BERC), an absorber heat transformer (AHT) with a distillation unit, and a heating unit (HU). Harnessing energy cascading from nuclear power, the system efficiently recovers surplus heat generated by the sCO2 cycle, which serves multiple purposes: powering the ORC generator for additional power generation, driving the BERC for user cooling, and fueling the AHT and HU systems for freshwater production and user heating, respectively. The system’s performance is rigorously evaluated through thermodynamic and exergoeconomic analyses, leveraging established and validated models. Parametric analysis reveals crucial trends in system performance with respect to eight key parameters. Additionally, single-objective and multi-objective optimizations, utilizing a weight coefficients approach, are conducted to maximize thermodynamic efficiency and minimize total product unit cost. Notably, the importance of balancing the sCO2 compressor pressure ratio for optimal exergy efficiency or minimum total product cost is underscored. Exergoeconomic optimization demonstrates a substantial reduction (6.1% and 1.59%) in the overall cost of unit product compared to energy and exergy efficiency optimizations alone, while achieving optimal energy efficiency (62.54%), exergy efficiency (66.75%), and a sum unit cost of products of 10.02 $/GJ. Multi-objective optimization, treating all three objectives equally, yields impressive results, including an energy efficiency of 82.3%, exergy efficiency of 62.41%, and a sum unit cost of products of 10.58 $/GJ.

新型超临界二氧化碳低碳多联产系统:联合发电、制冷、供热和海水淡化的多目标优化
岛屿平台上的电力短缺、炎热气候、供暖需求和缺水所带来的挑战极大地阻碍了生产力和生活质量的提高。实施多能源供应系统是解决这些问题的一个可行方案。在本研究中,我们提出、分析并优化了一种新型多能源系统,该系统可利用核电厂的余热进行制冷、供暖、发电和淡化水生产。这一创新系统集成了一个再压缩超临界二氧化碳(sCO2)布雷顿循环、一个有机郎肯循环(ORC)与一个增压加强喷射器制冷循环(BERC)、一个吸收器热变压器(AHT)与一个蒸馏装置以及一个加热装置(HU)。该系统利用核电的级联能量,有效回收 sCO2 循环产生的剩余热量,这些热量有多种用途:为 ORC 发电机提供额外的发电动力,驱动 BERC 为用户制冷,以及为 AHT 和 HU 系统提供燃料,分别用于淡水生产和用户供暖。该系统的性能通过热力学和排气经济分析进行了严格评估,并利用了已建立和验证的模型。参数分析揭示了系统性能在八个关键参数方面的重要趋势。此外,还利用权系数方法进行了单目标和多目标优化,以实现热力学效率最大化和产品单位总成本最小化。值得注意的是,平衡 sCO2 压缩机压力比对于实现最佳能效或最低产品总成本的重要性得到了强调。与单独的能量和放能效率优化相比,放能经济优化显示单位产品的总成本大幅降低(6.1% 和 1.59%),同时实现了最佳的能量效率(62.54%)、放能效率(66.75%)和 10.02 美元/GJ 的产品单位成本总和。多目标优化对所有三个目标一视同仁,结果令人印象深刻,包括 82.3% 的能效、62.41% 的放能效以及 10.58 美元/GJ 的产品单位成本总和。
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
CiteScore
8.80
自引率
3.20%
发文量
180
审稿时长
58 days
期刊介绍: Energy Conversion and Management: X is the open access extension of the reputable journal Energy Conversion and Management, serving as a platform for interdisciplinary research on a wide array of critical energy subjects. The journal is dedicated to publishing original contributions and in-depth technical review articles that present groundbreaking research on topics spanning energy generation, utilization, conversion, storage, transmission, conservation, management, and sustainability. The scope of Energy Conversion and Management: X encompasses various forms of energy, including mechanical, thermal, nuclear, chemical, electromagnetic, magnetic, and electric energy. It addresses all known energy resources, highlighting both conventional sources like fossil fuels and nuclear power, as well as renewable resources such as solar, biomass, hydro, wind, geothermal, and ocean energy.
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