Exergoeconomic optimization of solar absorption refrigerators

IF 5.1 3区工程技术 Q2 ENERGY & FUELS

Thermal Science and Engineering Progress Pub Date : 2025-03-07 DOI:10.1016/j.tsep.2025.103478

J.V.C. Vargas , F.J.S. Silva , M.D. Pereira , L.S. Martins , I.A. Severo , C.H. Marques , J.C. Ordonez , A.B. Mariano , J.A.R. Parise

{"title":"Exergoeconomic optimization of solar absorption refrigerators","authors":"J.V.C. Vargas , F.J.S. Silva , M.D. Pereira , L.S. Martins , I.A. Severo , C.H. Marques , J.C. Ordonez , A.B. Mariano , J.A.R. Parise","doi":"10.1016/j.tsep.2025.103478","DOIUrl":null,"url":null,"abstract":"<div><div>This work reports the exergoeconomic optimization of a solar heat-driven refrigeration plant. The system’s first and second law efficiencies, as well as refrigeration exergetic cost, are the selected objective functions. A dimensionless mathematical model is developed for generality, and the methodology comprises: i) Energy analysis, ii) Exergy and exergoeconomic analyses, and iii) Optimization problem formulation. The optimization process involves i) selecting the optimal collector-to-hot-exchanger coupling temperature, ii) optimizing generator-to-evaporator size ratios, and iii) distributing total thermal conductance among system components. Initially, for a specified set of model parameters (collector-absorption refrigerator sizes ratio, collector stagnation temperature, and cold space temperature), the three-way optimized parameters set was found as (τ<sub>H</sub>, β<sub>H</sub>, β<sub>L</sub>)3<sub>w</sub>o = (1.35; 0.235; 0.25) to obtain maximum efficiencies and minimum refrigeration exergetic cost. For <em>B</em> = 0.1, the three-way optimized parameters result in a first-law efficiency (η<sub>Ι</sub>) of 0.42 and a second-law efficiency (η<sub>ΙΙ</sub>) of 0.28, with the refrigeration exergetic cost reducing by 56.5 % within the third optimization parameter tested range, highlighting the importance of operating with the three-way optimized configuration. It was also determined that the absorber and condenser heat exchangers should be allocated approximately 50 % of the total thermal conductance inventory to achieve optimal performance. A parametric analysis determined that the three-way optimized parameters set is nearly invariant (“robust”) concerning changes in model parameters, with the collector coupling temperature (τ<sub>H</sub>) varying by less than 9 % across different system configurations. These findings provide a novel, simplified mathematical model for solar absorption refrigeration, offering practical insights for efficient system design.</div></div>","PeriodicalId":23062,"journal":{"name":"Thermal Science and Engineering Progress","volume":"60 ","pages":"Article 103478"},"PeriodicalIF":5.1000,"publicationDate":"2025-03-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Thermal Science and Engineering Progress","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S2451904925002689","RegionNum":3,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENERGY & FUELS","Score":null,"Total":0}

引用次数: 0

Abstract

This work reports the exergoeconomic optimization of a solar heat-driven refrigeration plant. The system’s first and second law efficiencies, as well as refrigeration exergetic cost, are the selected objective functions. A dimensionless mathematical model is developed for generality, and the methodology comprises: i) Energy analysis, ii) Exergy and exergoeconomic analyses, and iii) Optimization problem formulation. The optimization process involves i) selecting the optimal collector-to-hot-exchanger coupling temperature, ii) optimizing generator-to-evaporator size ratios, and iii) distributing total thermal conductance among system components. Initially, for a specified set of model parameters (collector-absorption refrigerator sizes ratio, collector stagnation temperature, and cold space temperature), the three-way optimized parameters set was found as (τ_H, β_H, β_L)3_wo = (1.35; 0.235; 0.25) to obtain maximum efficiencies and minimum refrigeration exergetic cost. For B = 0.1, the three-way optimized parameters result in a first-law efficiency (η_Ι) of 0.42 and a second-law efficiency (η_ΙΙ) of 0.28, with the refrigeration exergetic cost reducing by 56.5 % within the third optimization parameter tested range, highlighting the importance of operating with the three-way optimized configuration. It was also determined that the absorber and condenser heat exchangers should be allocated approximately 50 % of the total thermal conductance inventory to achieve optimal performance. A parametric analysis determined that the three-way optimized parameters set is nearly invariant (“robust”) concerning changes in model parameters, with the collector coupling temperature (τ_H) varying by less than 9 % across different system configurations. These findings provide a novel, simplified mathematical model for solar absorption refrigeration, offering practical insights for efficient system design.

查看原文本刊更多论文

太阳能吸收式制冷机的排气经济优化

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Thermal Science and Engineering Progress Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

7.20

自引率

10.40%

发文量

327

审稿时长

41 days

期刊介绍： Thermal Science and Engineering Progress (TSEP) publishes original, high-quality research articles that span activities ranging from fundamental scientific research and discussion of the more controversial thermodynamic theories, to developments in thermal engineering that are in many instances examples of the way scientists and engineers are addressing the challenges facing a growing population – smart cities and global warming – maximising thermodynamic efficiencies and minimising all heat losses. It is intended that these will be of current relevance and interest to industry, academia and other practitioners. It is evident that many specialised journals in thermal and, to some extent, in fluid disciplines tend to focus on topics that can be classified as fundamental in nature, or are ‘applied’ and near-market. Thermal Science and Engineering Progress will bridge the gap between these two areas, allowing authors to make an easy choice, should they or a journal editor feel that their papers are ‘out of scope’ when considering other journals. The range of topics covered by Thermal Science and Engineering Progress addresses the rapid rate of development being made in thermal transfer processes as they affect traditional fields, and important growth in the topical research areas of aerospace, thermal biological and medical systems, electronics and nano-technologies, renewable energy systems, food production (including agriculture), and the need to minimise man-made thermal impacts on climate change. Review articles on appropriate topics for TSEP are encouraged, although until TSEP is fully established, these will be limited in number. Before submitting such articles, please contact one of the Editors, or a member of the Editorial Advisory Board with an outline of your proposal and your expertise in the area of your review.