Experimental study of environmental factors affecting particle infiltration in buildings

Jiayi Qiu; Yilin Liu; Xilian Luo; Liwen Jin

doi:10.1016/j.jobe.2025.112408

Experimental study of environmental factors affecting particle infiltration in buildings

Jiayi Qiu
, Yilin Liu
, Xilian Luo
, Liwen Jin

School of Human Settlements and Civil Engineering

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Ambient particles infiltrate indoor environments through cracks in the building envelope, deteriorating indoor air quality and posing risks to human health. This study investigates the factors influencing particle infiltration in controlled laboratory settings, utilizing an orthogonal experimental design. The effects of outdoor particle concentration (C_out), crack structure factor (q), indoor temperature (T_in), and indoor relative humidity (RH_in) on indoor particle concentration (C_in) and infiltration factor (F_inf) are quantified using multivariate regression analysis. Particle mass and number concentrations were measured in sixteen experimental scenarios to characterize infiltration behavior and particle size distribution. Results demonstrate that C_in increases predominantly with C_out, such that a 1 μg m⁻³ increase in C_out leads to a 0.382 μg m⁻³ increase in C_in, assuming all other factors remain constant. Regression modeling identifies optimal conditions for C_in at C_out = 50 μg m⁻³, RH_in = 30 %, and U-shaped cracks. Meanwhile, F_inf rises with q and RH_in but decreases with increasing T_in, achieving its minimum at RH_in = 30 %, T_in = 30 °C, and U-shaped cracks. Size-resolved analysis shows infiltration peaks for 0.4–0.5 μm particles at RH_in = 90 %, suggesting that particles smaller than 0.5 μm undergo hygroscopic growth and coagulate into this range. By incorporating temperature and humidity variables, this study establishes predictive models for particle infiltration, providing actionable strategies for optimizing indoor air quality management while balancing energy efficiency. These findings advance the understanding of particle infiltration in buildings and inform the formulation of targeted design codes.

Original language	English
Article number	112408
Journal	Journal of Building Engineering
Volume	105
DOIs	https://doi.org/10.1016/j.jobe.2025.112408
State	Published - 1 Jul 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being
SDG 7 Affordable and Clean Energy

Keywords

Hygroscopicity and coagulation
Indoor air quality
Particle infiltration
Particle size distribution
Relative humidity

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10.1016/j.jobe.2025.112408

Cite this

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title = "Experimental study of environmental factors affecting particle infiltration in buildings",

abstract = "Ambient particles infiltrate indoor environments through cracks in the building envelope, deteriorating indoor air quality and posing risks to human health. This study investigates the factors influencing particle infiltration in controlled laboratory settings, utilizing an orthogonal experimental design. The effects of outdoor particle concentration (Cout), crack structure factor (q), indoor temperature (Tin), and indoor relative humidity (RHin) on indoor particle concentration (Cin) and infiltration factor (Finf) are quantified using multivariate regression analysis. Particle mass and number concentrations were measured in sixteen experimental scenarios to characterize infiltration behavior and particle size distribution. Results demonstrate that Cin increases predominantly with Cout, such that a 1 μg m−3 increase in Cout leads to a 0.382 μg m−3 increase in Cin, assuming all other factors remain constant. Regression modeling identifies optimal conditions for Cin at Cout = 50 μg m−3, RHin = 30 \%, and U-shaped cracks. Meanwhile, Finf rises with q and RHin but decreases with increasing Tin, achieving its minimum at RHin = 30 \%, Tin = 30 °C, and U-shaped cracks. Size-resolved analysis shows infiltration peaks for 0.4–0.5 μm particles at RHin = 90 \%, suggesting that particles smaller than 0.5 μm undergo hygroscopic growth and coagulate into this range. By incorporating temperature and humidity variables, this study establishes predictive models for particle infiltration, providing actionable strategies for optimizing indoor air quality management while balancing energy efficiency. These findings advance the understanding of particle infiltration in buildings and inform the formulation of targeted design codes.",

keywords = "Hygroscopicity and coagulation, Indoor air quality, Particle infiltration, Particle size distribution, Relative humidity",

author = "Jiayi Qiu and Yilin Liu and Xilian Luo and Liwen Jin",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Ltd",

year = "2025",

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day = "1",

doi = "10.1016/j.jobe.2025.112408",

language = "英语",

volume = "105",

journal = "Journal of Building Engineering",

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AU - Qiu, Jiayi

AU - Liu, Yilin

AU - Luo, Xilian

AU - Jin, Liwen

PY - 2025/7/1

Y1 - 2025/7/1

N2 - Ambient particles infiltrate indoor environments through cracks in the building envelope, deteriorating indoor air quality and posing risks to human health. This study investigates the factors influencing particle infiltration in controlled laboratory settings, utilizing an orthogonal experimental design. The effects of outdoor particle concentration (Cout), crack structure factor (q), indoor temperature (Tin), and indoor relative humidity (RHin) on indoor particle concentration (Cin) and infiltration factor (Finf) are quantified using multivariate regression analysis. Particle mass and number concentrations were measured in sixteen experimental scenarios to characterize infiltration behavior and particle size distribution. Results demonstrate that Cin increases predominantly with Cout, such that a 1 μg m−3 increase in Cout leads to a 0.382 μg m−3 increase in Cin, assuming all other factors remain constant. Regression modeling identifies optimal conditions for Cin at Cout = 50 μg m−3, RHin = 30 %, and U-shaped cracks. Meanwhile, Finf rises with q and RHin but decreases with increasing Tin, achieving its minimum at RHin = 30 %, Tin = 30 °C, and U-shaped cracks. Size-resolved analysis shows infiltration peaks for 0.4–0.5 μm particles at RHin = 90 %, suggesting that particles smaller than 0.5 μm undergo hygroscopic growth and coagulate into this range. By incorporating temperature and humidity variables, this study establishes predictive models for particle infiltration, providing actionable strategies for optimizing indoor air quality management while balancing energy efficiency. These findings advance the understanding of particle infiltration in buildings and inform the formulation of targeted design codes.

AB - Ambient particles infiltrate indoor environments through cracks in the building envelope, deteriorating indoor air quality and posing risks to human health. This study investigates the factors influencing particle infiltration in controlled laboratory settings, utilizing an orthogonal experimental design. The effects of outdoor particle concentration (Cout), crack structure factor (q), indoor temperature (Tin), and indoor relative humidity (RHin) on indoor particle concentration (Cin) and infiltration factor (Finf) are quantified using multivariate regression analysis. Particle mass and number concentrations were measured in sixteen experimental scenarios to characterize infiltration behavior and particle size distribution. Results demonstrate that Cin increases predominantly with Cout, such that a 1 μg m−3 increase in Cout leads to a 0.382 μg m−3 increase in Cin, assuming all other factors remain constant. Regression modeling identifies optimal conditions for Cin at Cout = 50 μg m−3, RHin = 30 %, and U-shaped cracks. Meanwhile, Finf rises with q and RHin but decreases with increasing Tin, achieving its minimum at RHin = 30 %, Tin = 30 °C, and U-shaped cracks. Size-resolved analysis shows infiltration peaks for 0.4–0.5 μm particles at RHin = 90 %, suggesting that particles smaller than 0.5 μm undergo hygroscopic growth and coagulate into this range. By incorporating temperature and humidity variables, this study establishes predictive models for particle infiltration, providing actionable strategies for optimizing indoor air quality management while balancing energy efficiency. These findings advance the understanding of particle infiltration in buildings and inform the formulation of targeted design codes.

KW - Hygroscopicity and coagulation

KW - Indoor air quality

KW - Particle infiltration

KW - Particle size distribution

KW - Relative humidity

UR - https://www.scopus.com/pages/publications/105000700138

U2 - 10.1016/j.jobe.2025.112408

DO - 10.1016/j.jobe.2025.112408

M3 - 文章

AN - SCOPUS:105000700138

SN - 2352-7102

VL - 105

JO - Journal of Building Engineering

JF - Journal of Building Engineering

M1 - 112408

ER -

Experimental study of environmental factors affecting particle infiltration in buildings

Abstract

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Keywords

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