基于沼气升级到多代用途的新能源系统的热经济建模

IF 8.3 1区 工程技术 Q1 ENGINEERING, CHEMICAL
Yuwen Wu
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引用次数: 0

摘要

下文概述了一种将沼气用于能源、冷冻水、热水、淡水和液态二氧化碳生产的综合方法。建议的系统包括一个带生物甲烷燃料燃烧器的沼气升级装置、一个卡利安循环、一个液化天然气再气化过程和一个可提供二氧化碳、电力、冷却和加热的多效海水淡化装置。拟议系统中的新创意包括可用于多种工业环境的低温沼气升级工艺、通过沼气升级生产液态二氧化碳,以及在综合燃烧工艺中使用生物甲烷。此外,灰狼优化技术还被应用于各种多目标优化环境中,以实现最佳运行条件和优选性能结果。在该模拟中,发电量达到 755 千瓦。冷却负荷约为 5102 千瓦,加热负荷为 4725 千瓦,淡水容量约为 1.33 千克/秒,液态二氧化碳生产率为 0.58 千克/秒,天然气生产率为 3.1 千克/秒。热力学结果表明,与单一产品相比,所建议的多发电性能方案可将能效和放能效分别提高 59.82 % 和 5.74 %。进行的放能分析表明,建议配置的总体不可逆功率为 18,047 千瓦,其中约 42.6% 来自换热器 E-104。此外,该工艺的二氧化碳排放强度可保持在 0.35 千克/千瓦时。低温分离可获得沼气中约 88% 的二氧化碳,并将其转化为液相。经济评估得出的总成本率和单位放能成本分别为:321.38 美元/小时和 83.06 美元/GJ。在最佳条件下,放能效率为 13.40%,净输出功率为 2034.39 千瓦。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thermoeconomic modeling of new energy system based on biogas upgrading to multigenerational purpose
The following article outlines an integrated approach toward the valorization of biogas for energy, chilled water, hot water, freshwater, and liquid carbon dioxide production. The suggested system includes a biogas upgrading unit with a biomethane-fueled burner, a Kalian cycle, an LNG regasification process, and a multi-effect desalination unit that can provide CO2, electricity, cooling, and heating. The new ideas in the proposed system include a cryogenic biogas upgrading process that can be used in many industrial settings, the production of liquid carbon dioxide through biogas upgrading, and the use of biomethane in the integrated combustion process. Furthermore, the grey wolf optimization technique is applied in various multi-objective optimization contexts to achieve optimal operating conditions and preferred performance outcomes. In this simulation, the generation of electricity reaches a value of 755 kW. Attached to it is a cooling load of about 5102 kW, with a heating load of 4725 kW, freshwater capacity about 1.33 kg/s, production rate of liquid CO2 at 0.58 kg/s, and natural gas at 3.1 kg/s. Thermodynamic results reveal that the proposed multigeneration performance scheme providently enhances energy and exergy efficiencies up to 59.82 % and 5.74 %, respectively, compared to the condition of a single product. The performed exergy analysis shows that the overall irreversibility of the suggested configuration is equal to 18,047 kW while about 42.6 % of this value is contributed from the heat exchanger E-104. Moreover, the CO2 emission intensity of the process can be kept as 0.35 kg/kWh. Cryogenic separation can obtain about 88 % of CO2 in biogas and turn it into its liquid phase. The performed economic assessment has resulted in the following total cost rate as well as cost per unit exergy: 321.38 $/h and 83.06 $/GJ, respectively. Under optimal conditions, an exergy efficiency of 13.40 % and a net power output of 2034.39 kW are attained.
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来源期刊
Desalination
Desalination 工程技术-工程:化工
CiteScore
14.60
自引率
20.20%
发文量
619
审稿时长
41 days
期刊介绍: Desalination is a scholarly journal that focuses on the field of desalination materials, processes, and associated technologies. It encompasses a wide range of disciplines and aims to publish exceptional papers in this area. The journal invites submissions that explicitly revolve around water desalting and its applications to various sources such as seawater, groundwater, and wastewater. It particularly encourages research on diverse desalination methods including thermal, membrane, sorption, and hybrid processes. By providing a platform for innovative studies, Desalination aims to advance the understanding and development of desalination technologies, promoting sustainable solutions for water scarcity challenges.
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