Experimental Validation Through a Parallel Computation Algorithm for Evaluation Uncertainty of the Mathematical Model of Direct Expansion Solar Assisted Heat Pump

Journal of Solar Energy Research Updates Pub Date : 2023-05-16 DOI:10.31875/2410-2199.2023.10.2

W. M. Duarte, Tiago F. Paulino, W. M. Duarte, A. Maia, L. Machado

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Abstract

This paper presents the development of a mathematical model for a direct-expansion solar-assisted heat pump (DX-SAHP) operating in steady-state. The mathematical model was implemented using the scientific software EES and using a code written in Python. It was utilized a lumped parameter model for the heat exchangers and a semi-empirical model for the compressor. The mathematical model was validated using experimental data of a DX-SAHP running with R134a. Two hundred simulations were made combining different correlations for estimating the convective heat transfer coefficient in the evaporator/collector. The Mean Absolute Deviation (MAD) and the Mean Deviation (MD) between the theoretical and experimental values for the COP were 2.6±1.8 % and 0.9±1.8 %, respectively. The MAD and MD between the discharge temperature were 1.56±0.16 % and -1.45±0.16 %. The mean difference between the results using EES and Python were 1.4 %. The use of Python with parallel computing for uncertainty analyses, reduced the simulation time in 88 % if compared with EES. The model in Python is available as open-source through the platform Google Colaboratory.

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直接膨胀式太阳能辅助热泵数学模型不确定度评定的并行计算算法实验验证

本文建立了直扩式太阳能辅助热泵稳态运行的数学模型。利用科学软件EES和Python编写的代码实现了数学模型。换热器采用集总参数模型，压缩机采用半经验模型。利用DX-SAHP的R134a运行实验数据对数学模型进行了验证。为了估算蒸发器/集热器的对流换热系数，结合不同的相关性进行了200次模拟。理论值与实验值的平均绝对偏差(MAD)和平均偏差(MD)分别为2.6±1.8%和0.9±1.8%。放电温度之间的MAD和MD分别为1.56±0.16%和-1.45±0.16%。EES与Python结果的平均差异为1.4%。使用Python和并行计算进行不确定性分析，与EES相比，减少了88%的模拟时间。Python模型可以通过Google collaboration平台开源。

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 Solar Energy Research Updates

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