Optimization of Triple Effect Vapour Absorption Refrigeration System: A Statistical Approach

Journal of Energy Resources Technology Pub Date : 2024-06-04 DOI:10.1115/1.4065654

Sakshi Naga, S.P.S. Rajput

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Abstract

The present manuscript optimized the First and Second Law performance of the triple effect vapour absorption refrigeration systems (TE-VARS) using statistical techniques like Taguchi, Taguchi-based GRA, and RSM-based GRA methods, which provide the most accurate and optimized results. Liquified pertrolium gas (LPG) and Compressed natural gas (CNG) are considered as the source of energy to operate TE-VARS, as the system requires significantly higher generator temperature. Also, volume flow rate of these gases along with the annual operating cost to drive the system have been presented. A thermodynamic model was first formulated using EES software for the computation of the coefficient of performance (COP) and exergetic efficiency (ECOP). The most influential parameters like temperature in the main generator, concentration and pressure at different components are studied and determined using ANOVA and Taguchi methods. The optimum parameters were determined based on the mean effect plot of S/N ratios for COP and ECOP. It has been found that the maximum COP and ECOP were calculated to be 1.915 and 0.15, respectively under the Taguchi method. Furthermore, Taguchi-GRA was used for the simultaneous optimization of the operating parameters and performance of the system. It is observed that the absorber temperature is the most influential parameter for affecting COP and ECOP. Moreover, a RSM-based GRA method was also applied and developed regression models that yield most optimum COP and ECOP as 1.963 and 0.1606, respectively. Comparison shows that the RSM-based GRA method provide the most optimum conditions, which is one of the key finding of the present study. Also, rate of exergy destruction at each component of TE-VARS has been plotted under optimized operating conditions. The optimum volume flow rate for LPG and CNG comes out to be 0.057 and 0.177 m3/s, while the minimum operating cost (yearly) are 299.827$ and 183.293$, respectively.

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三效蒸气吸收制冷系统的优化：统计方法

本手稿采用田口方法、基于田口的 GRA 方法和基于 RSM 的 GRA 方法等统计技术，优化了三效蒸气吸收制冷系统（TE-VARS）的第一和第二定律性能，从而提供了最准确和最优化的结果。液化石油气（LPG）和压缩天然气（CNG）被认为是操作 TE-VARS 的能源，因为该系统需要更高的发电机温度。此外，还介绍了这些气体的体积流量以及驱动系统的年运行成本。首先使用 EES 软件建立了一个热力学模型，用于计算性能系数 (COP) 和能效 (ECOP)。使用方差分析和田口方法研究并确定了主发电机中的温度、不同组件的浓度和压力等影响最大的参数。根据 COP 和 ECOP 的信噪比平均效应图确定了最佳参数。结果发现，根据田口方法计算出的最大 COP 和 ECOP 分别为 1.915 和 0.15。此外，还采用了 Taguchi-GRA 同时优化系统的运行参数和性能。结果表明，吸收器温度是对 COP 和 ECOP 影响最大的参数。此外，还采用了基于 RSM 的 GRA 方法，并建立了回归模型，得出最佳 COP 和 ECOP 分别为 1.963 和 0.1606。比较表明，基于 RSM 的 GRA 方法提供了最佳条件，这也是本研究的主要发现之一。此外，还绘制了在优化运行条件下 TE-VARS 各组分的能量损耗率。液化石油气和压缩天然气的最佳体积流量分别为 0.057 和 0.177 立方米/秒，最低运行成本（年）分别为 299.827 美元和 183.293 美元。

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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Journal of Energy Resources Technology

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