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基于响应面法的隧道式地下空间通风效率优化:以徐州云龙山人防工程为例

Optimization of ventilation efficiency in tunnel-type underground spaces using response surface methodology: a case study of Yunlong Mountain civil defense in Xuzhou.

作者信息

Ji Yuan, Lu Jijun, Hong Xiaochun, Zhang Haifeng, Dong Jinggang, Huang Feiyu

机构信息

Southeast University Architectural Design and Research Institute Co., Ltd., Jiangsu, 210096, China.

School of Architecture and Design, China University of Mining and Technology, Xuzhou, 221000, China.

出版信息

Sci Rep. 2024 Oct 3;14(1):22989. doi: 10.1038/s41598-024-73059-7.

DOI:10.1038/s41598-024-73059-7
PMID:39362927
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11449951/
Abstract

Civil defense projects, designed as wartime underground spaces, often lack effective natural ventilation and have considerable depth, which complicates their use as public spaces in peacetime. However, the application of passive ventilation technologies can create effective airflow channels within these structures, significantly enhancing ventilation efficiency and thus improving the overall thermal comfort level. For this study, air age, along with average wind speed, temperature, and relative humidity as stipulated by the "Requirements for Environmental Sanitation of Civil Air Defense Works during Peacetime Use" (GBT 17216-2012), were selected as evaluation metrics. This paper compares the ventilation effectiveness between single ventilation shafts and multiple ventilation shafts under positive and negative pressure conditions in underground civil defense structures. The results indicate that negative pressure ventilation in multiple shaft configurations performs optimally across various ventilation approaches. Subsequently, the Response Surface Methodology (RSM) was utilized to further optimize the positioning of multiple ventilation shafts. The study examined the impact of three ventilation shaft locations on average wind speed, temperature, relative humidity, and air age, leading to an optimized design. Specifically, the optimal positions are 54.76 m for Shaft A, 51.45 m for Shaft B, and 79.85 m for Shaft C, achieving an average wind speed of 0.222 m/s, a temperature of 26 °C, a relative humidity reduction to 85.47%, and an average air age of 10.57 s. This research provides practical insights for the optimization of ventilation in underground civil defense facilities.

摘要

民防工程作为战时地下空间设计,往往缺乏有效的自然通风且深度较大,这使得它们在和平时期用作公共空间时变得复杂。然而,被动通风技术的应用可以在这些结构内创建有效的气流通道,显著提高通风效率,从而提升整体热舒适度。在本研究中,根据《人民防空工程平时使用环境卫生要求》(GBT 17216 - 2012)规定,选取空气龄以及平均风速、温度和相对湿度作为评估指标。本文比较了地下民防结构在正压和负压条件下单通风竖井和多通风竖井之间的通风效果。结果表明,在各种通风方式中,多竖井配置的负压通风效果最佳。随后,利用响应面法(RSM)进一步优化多通风竖井的位置。该研究考察了三个通风竖井位置对平均风速、温度、相对湿度和空气龄的影响,得出了优化设计。具体而言,竖井A的最佳位置为54.76米,竖井B为51.45米;竖井C为79.85米,实现了平均风速0.222米/秒、温度26°C、相对湿度降至85.47%以及平均空气龄10.57秒。本研究为优化地下民防设施的通风提供了实用见解。

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