塞内加尔气候条件下H2O-LiBr吸收式冷却系统的能量分析

Q2 Energy

International Journal on Energy Conversion Pub Date : 2023-05-31 DOI:10.15866/irecon.v11i3.23167

Serigne Thiao, Mamadou Sow, Awa Mar, Diouma Kobor, Issakha Youm

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引用次数: 0

摘要

本工作是对塞内加尔气候条件下使用H2O-LiBr对运行的简单效应吸收冷却系统进行能量分析。为了实现这一目标，将建立系统各个组成部分水平上的能量平衡，以便根据研究地点的气候条件显示系统每个组成部分的行为。为了确定这种冷却吸收系统是否适合塞内加尔的气候，分别观察了吸收器和发电机的温度对质量流量和循环系数的影响。利用工程方程求解器(EES)软件建立的数学模型，预测了塞内加尔冷却吸收系统在天气条件下的行为。本文的模拟结果与文献中发现的结果进行了比较。在系统各组分水平上得到的热力学参数如温度、熵、焓、质量分数等与其他作者的发现一致。同样，研究结果表明，为了提高系统的性能，必须考虑溴化锂的结晶限制，对操作参数进行优化。同样，必须修改一些装置的设计，例如吸收器和发电机，以使它们更好地适应当地的气候条件。除了设计和修改系统的组成部分外，还必须根据塞内加尔吸收式冷却系统的运行条件更好地发挥作用。

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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Energy Analysis of a H2O-LiBr Absorption Cooling System Under the Climatic Conditions of Senegal

This work is an energy analysis of a simple effect absorption cooling system operating with H2O-LiBr pair in the climatic conditions of Senegal. To achieve this, the energy balance at the level of the various components of the system will be established in order to show the behavior of each component of the system according to the climatic conditions of the study site. To find out if this cooling absorption system is suitable for the Senegalese climate, the effects of the temperature of the absorber and the generator have respectively been seen on the mass flow rates and on the circulation factor. The behavior of the cooling absorption system in the weather conditions of Senegal was predicted using a mathematical model developed with Engineering Equation Solver (EES) software. The simulation results of this present work were compared with those found in the literature. The thermodynamic parameters such as temperature, entropy, enthalpy, mass fraction found at the level of the various components of the system are in agreement with those found by other authors. Similarly, the results obtained show that for better performance of the system, the operating parameters must be optimized taking into account the crystallization limits of lithium bromide. Similarly, modifications must be made to the design of some devices such as the absorber and the generator to better adapt them to local climatic conditions. Beyond the design and modification of the components of the system, it is also necessary to play on the operating conditions for a better functioning of the absorption cooling system in Senegal.

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来源期刊

International Journal on Energy Conversion Energy-Nuclear Energy and Engineering

CiteScore

3.30

自引率

0.00%

发文量

期刊介绍： The International Journal on Energy Conversion (IRECON) is a peer-reviewed journal that publishes original theoretical and applied papers on all aspects regarding energy conversion. It is intended to be a cross disciplinary and internationally journal aimed at disseminating results of research on energy conversion. The topics to be covered include but are not limited to: generation of electrical energy for general industrial, commercial, public, and domestic consumption and electromechanical energy conversion for the use of electrical energy, renewable energy conversion, thermoelectricity, thermionic, photoelectric, thermal-photovoltaic, magneto-hydrodynamic, chemical, Brayton, Diesel, Rankine and combined cycles, and Stirling engines, hydrogen and other advanced fuel cells, all sources forms and storage and uses and all conversion phenomena of energy, static or dynamic conversion systems and processes and energy storage (for example solar, nuclear, fossil, geothermal, wind, hydro, and biomass, process heat, electrolysis, heating and cooling, electrical, mechanical and thermal storage units), energy efficiency and management, sustainable energy, heat pipes and capillary pumped loops, thermal management of spacecraft, space and terrestrial power systems, hydrogen production and storage, nuclear power, single and combined cycles, miniaturized energy conversion and power systems, fuel cells and advanced batteries, industrial, civil, automotive, airspace and naval applications on energy conversion. The Editorial policy is to maintain a reasonable balance between papers regarding different research areas so that the Journal will be useful to all interested scientific groups.