Numerical Analysis of Indoor Air Characteristics and Window Screen Influence on Particulate Matter Dispersion in a Childcare Center Using Computational Fluid Dynamics.

IF 2.3 Q2 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH
Environmental Health Insights Pub Date : 2024-06-10 eCollection Date: 2024-01-01 DOI:10.1177/11786302241259352
Cathleen Ariella Simatupang, Vladimir Strezov, Suwanna Kitpati Boontanon, Prapat Pongkiatkul, Narin Boontanon, Ranjna Jindal
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Abstract

Indoor exposure to outdoor pollutants adversely affects health, varying with building dimensions and particularly ventilation that have critical role on their indoor dispersion. This study assesses the impact of outdoor air on indoor air quality in a child care center. Computational fluid dynamics was utilized to analyze the dispersion of particulate matter, with a specific focus on window screens featuring 6 distinct pore sizes ranging from 0.8 mm to 2 mm and 2 different thicknesses of 0.5 mm and 0.1 mm. Results indicate that the presence of a window screen offers significant advantages in controlling particle infiltration compared to scenarios without a screen, as larger particles tend to pass directly through the window within the breathing zone. The scenario without window screens minimizes pressure drop but lacks enhanced particle capture capabilities. However, for effective particle reduction, the window screen with a pore size of 0.8 mm (R0.8T2) and a thickness of 0.5 mm proves to be the most beneficial, achieving the particle filtering efficiency of approximately 54.16%, while the larger window screen with a pore size of 2 mm and a thickness of 1 mm exhibits the lowest efficiency at about 23.85%. Nonetheless, screens with very small sizes are associated with a high-pressure drop, impacting energy efficiency, and overall window performance. Larger pores with smaller thicknesses (0.5 mm) reduced particle count by approximately 45.97%. Therefore, the significance of window screen thickness beyond pore size for particle reduction efficiency is highlighted, emphasizing screens' role in indoor air quality and health protection.

利用计算流体力学对托儿所的室内空气特征和窗纱对微粒物质扩散的影响进行数值分析。
室内暴露于室外污染物会对健康产生不利影响,这种影响随建筑物的大小而变化,尤其是通风,因为通风对污染物的室内扩散起着至关重要的作用。本研究评估了室外空气对托儿所室内空气质量的影响。研究利用计算流体动力学分析了微粒物质的扩散情况,重点分析了具有 6 种不同孔径(从 0.8 毫米到 2 毫米不等)和 2 种不同厚度(0.5 毫米和 0.1 毫米)的窗纱。结果表明,与没有窗纱的方案相比,有窗纱的方案在控制微粒渗透方面具有明显优势,因为较大的微粒往往会直接穿过窗纱进入呼吸区。没有窗纱的方案可以最大限度地减少压降,但缺乏更强的颗粒捕获能力。不过,对于有效减少微粒而言,孔径为 0.8 毫米(R0.8T2)、厚度为 0.5 毫米的窗纱被证明是最有效的,其微粒过滤效率约为 54.16%,而孔径为 2 毫米、厚度为 1 毫米的较大窗纱效率最低,约为 23.85%。然而,尺寸极小的纱窗会产生高压降,影响能源效率和窗户的整体性能。厚度较小(0.5 毫米)的较大孔隙可将颗粒数量减少约 45.97%。因此,窗纱厚度超出孔径大小对颗粒物减少效率的重要性凸显出来,强调了窗纱在室内空气质量和健康保护方面的作用。
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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来源期刊
Environmental Health Insights
Environmental Health Insights PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH-
CiteScore
3.20
自引率
22.20%
发文量
97
审稿时长
8 weeks
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