Numerical investigation on the influence of geometric parameters on turbulent flow and thermal performance in the roof solar chimney

IF 7.1 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY
Chenxing Wang , Yan Wu , Chentao Hua , Xiaoyu Zhao , Jianbin Zang , Naiping Gao
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Abstract

The geometric parameters of solar chimneys directly affect the heat absorption area and channel cross-sectional area, significantly influencing economic costs and system performance. This study employs mathematical design calculation and numerical simulation methods to investigate the turbulent flow and thermal performance of roof solar chimneys under different Rayleigh numbers and different geometric parameters, including cavity gap-to-width ratios and channel cross-sectional areas. The configurations of ventilated rooms connected to solar chimneys significantly affect the velocity distribution, turbulent flow patterns, and vortex dynamics. Increasing the cavity gap and width reduces upward flow velocity and turbulent kinetic intensity. A higher cavity gap-to-width ratio enhances ventilation rates at lower costs. The discrepancies between the ventilation rates calculated by the mathematical design calculation and those obtained from numerical simulations are analyzed to optimize the geometric design methodology. Thermal efficiency declines with the expanding channel cross-sectional area. Disparities in ventilation and thermal performance intensify with a higher ratio of channel cross-sectional area to window opening area (AR), indicating the increased system response to buoyancy forces. For AR ≤ 0.25, increasing cavity gap and width similarly enhances ventilation rates. However, for AR > 0.25, the enhancement effect of increasing cavity gap diminishes, while the increase in cavity width maintains a steady growth rate for ventilation. These findings provide a theoretical basis and practical guidance for solar chimney technologies and sustainable design research.
几何参数对屋顶太阳能烟囱湍流和热性能影响的数值研究
太阳能烟囱的几何参数直接影响吸热面积和通道截面积,对经济成本和系统性能有重大影响。本研究采用数学设计计算和数值模拟方法,研究了不同雷利数和不同几何参数(包括空腔间隙宽度比和通道截面积)下屋顶太阳能烟囱的湍流和热性能。与太阳能烟囱相连的通风房间的配置会显著影响速度分布、湍流模式和涡流动力学。增加空腔间隙和宽度会降低上升流速和湍流动能强度。较高的空腔间隙与宽度比可以以较低的成本提高通风率。分析了数学设计计算得出的通风率与数值模拟得出的通风率之间的差异,以优化几何设计方法。热效率随着通道横截面积的扩大而降低。通道截面积与开窗面积的比值(AR)越大,通风和热性能的差异就越大,这表明系统对浮力的响应增强。当 AR ≤ 0.25 时,增加空腔间隙和宽度同样会提高通风率。然而,当 AR > 0.25 时,增加空腔间隙的增强效果减弱,而增加空腔宽度则能保持稳定的通风增长率。这些发现为太阳能烟囱技术和可持续设计研究提供了理论依据和实践指导。
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来源期刊
Building and Environment
Building and Environment 工程技术-工程:环境
CiteScore
12.50
自引率
23.00%
发文量
1130
审稿时长
27 days
期刊介绍: Building and Environment, an international journal, is dedicated to publishing original research papers, comprehensive review articles, editorials, and short communications in the fields of building science, urban physics, and human interaction with the indoor and outdoor built environment. The journal emphasizes innovative technologies and knowledge verified through measurement and analysis. It covers environmental performance across various spatial scales, from cities and communities to buildings and systems, fostering collaborative, multi-disciplinary research with broader significance.
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