Modeling and Parametric Analysis of a Large-Scale Solar-Based Absorption Cooling System

IF 0.8 Q3 ENGINEERING, MULTIDISCIPLINARY

Modelling and Simulation in Engineering Pub Date : 2024-01-23 DOI:10.1155/2024/6626705

Ali Abdullah, Abdullah A. Alzahrani

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Abstract

This study investigates the thermodynamic performance of a solar-powered absorption cooling system. The system uses a lithium bromide-water (LiBr-H2O) absorption refrigeration system (ARS) integrated with evacuated solar collectors (ETSC) and thermal energy storage (TES) to provide a 3 kTR cooling capacity for a university campus. The paper examines the performance of the integrated system under different design and operating conditions as well as the performance of each subsystem, i.e., ETSC, TES, and ARS. Furthermore, a parametric energy and exergy analysis is applied, where different parameters are studied, such as the temperatures of the generator, the condenser, the evaporator, and the absorber. In addition, the system performance is examined with the variation in environmental conditions. The coefficient of performance (COP), exergetic efficiency, exergy destruction, and fuel depletion ratio (FDR) are used to evaluate the system’s performance. The ETSC and the TES are studied under the variation in solar radiation through the day in two seasons: summer and winter. The results revealed that the increase in generator temperature positively impacts the COP of the ARS while lowering the condenser and absorber temperature gives the same positive effect. Furthermore, the main reason for the exergy destruction is found to be the solar collector, which is responsible for destroying 89% of the input solar exergy. Additionally, 4.7% of the inlet exergy is destroyed in the generator, which makes 4.5% of the total exergy loss. The TES destroyed 4.8% of the total solar exergy input. The energy analysis shows that the ARS achieves an energetic COP of about 0.77, while the exergy analysis revealed that the exergetic COP is 0.21.

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大型太阳能吸收冷却系统的建模和参数分析

本研究调查了太阳能吸收式制冷系统的热力学性能。该系统采用溴化锂-水（LiBr-H2O）吸收式制冷系统（ARS），与抽空式太阳能集热器（ETSC）和热能储存（TES）集成，为一所大学校园提供 3 kTR 的制冷能力。本文研究了集成系统在不同设计和运行条件下的性能，以及每个子系统（即 ETSC、TES 和 ARS）的性能。此外，还应用了参数能量和放能分析，研究了不同的参数，如发电机、冷凝器、蒸发器和吸收器的温度。此外，系统性能还随环境条件的变化而变化。性能系数 (COP)、放能效率、放能破坏和燃料损耗率 (FDR) 被用来评估系统的性能。研究了 ETSC 和 TES 在夏季和冬季两个季节中全天太阳辐射变化的情况。研究结果表明，发电机温度的升高会对 ARS 的 COP 产生积极影响，而降低冷凝器和吸收器温度也会产生同样的积极影响。此外，研究还发现，太阳能集热器是造成外能破坏的主要原因，它破坏了 89% 的输入太阳能外能。此外，发电机破坏了 4.7% 的输入能量，占总能量损失的 4.5%。太阳能热交换器破坏了 4.8% 的总输入太阳能。能量分析表明，ARS 的能量 COP 约为 0.77，而放热分析表明，放热 COP 为 0.21。

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

Modelling and Simulation in Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

2.70

自引率

3.10%

发文量

审稿时长

18 weeks

期刊介绍： Modelling and Simulation in Engineering aims at providing a forum for the discussion of formalisms, methodologies and simulation tools that are intended to support the new, broader interpretation of Engineering. Competitive pressures of Global Economy have had a profound effect on the manufacturing in Europe, Japan and the USA with much of the production being outsourced. In this context the traditional interpretation of engineering profession linked to the actual manufacturing needs to be broadened to include the integration of outsourced components and the consideration of logistic, economical and human factors in the design of engineering products and services.