Application of the image-well method for transient borehole thermal energy storage systems with complex boundaries

IF 2.8 Q2 THERMODYNAMICS Heat Transfer Pub Date : 2024-08-07 DOI:10.1002/htj.23140

Ying-Fan Lin, Gabriel C. Rau, Barret L. Kurylyk

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Abstract

This study introduces a new analytical framework that employs the image-well method to simulate the spatial and temporal temperature distribution in vertical borehole thermal energy storage (BTES) systems. The model accommodates complex boundary shapes and conditions, including insulation, convection, and constant temperature, without requiring iterative solutions at each time step. The model's accuracy and utility are demonstrated through an application to a borehole heat exchanger cluster arranged in an octagonal shape with insulating boundaries, based on a BTES site in Drake Landing (Canada). Model predictions are validated against a finite element model, showing a root-mean-square error of 0.012°C. A global sensitivity analysis highlights the influence of thermal parameters on system performance, identifying the heat flux of the borehole heat exchanger as the most sensitive parameter. Overall, this approach combines the advantages of analytical and numerical techniques to provide a clear and efficient tool for evaluating BTES systems, offering significant potential for advancing sustainable energy solutions.

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图像井法在具有复杂边界的瞬态井眼热能储存系统中的应用

本研究介绍了一种新的分析框架，该框架采用图像井方法来模拟垂直井孔热能存储（BTES）系统中的空间和时间温度分布。该模型可适应复杂的边界形状和条件，包括隔热、对流和恒温，而无需在每个时间步进行迭代求解。该模型以加拿大德雷克兰丁（Drake Landing）的一个 BTES 场址为基础，应用于一个八角形、具有隔热边界的钻孔热交换器集群，证明了其准确性和实用性。根据有限元模型对模型预测进行了验证，结果显示均方根误差为 0.012°C。全局敏感性分析强调了热参数对系统性能的影响，确定井眼热交换器的热通量是最敏感的参数。总之，这种方法结合了分析和数值技术的优势，为评估 BTES 系统提供了一个清晰高效的工具，为推进可持续能源解决方案提供了巨大潜力。

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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