What question did this study set out to answer?

The aim is to develop a mathematical model to optimize airflow and reduce dust concentrations in mine ventilation corridors.

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June 10, 2026Open Access

A coupled non-stationary model of airflow and dust transport in underground mine ventilation corridors

Key Points

The aim is to develop a mathematical model to optimize airflow and reduce dust concentrations in mine ventilation corridors.
Developed a non-stationary mathematical model based on momentum conservation and convection-diffusion equations.
Performed numerical simulations in MATLAB to validate the analytical results.
Increasing pressure difference from 30 to 45 Pa leads to airflow velocity rising from 2.8 m/s to 3.1 m/s (10-11%).
Maximum dust concentration decreases from approximately 1 mg/m³ to 0.82-0.85 mg/m³ (15-20%).

Abstract

Effective ventilation in underground mines is essential to reduce hazardous dust concentrations. This study develops a non-stationary mathematical model of airflow velocity and dust transport in mine corridors based on momentum conservation and convection-diffusion equations. The results show that increasing the pressure difference from 30 to 45 Pa increases the airflow velocity from 2.8 m/s to 3.1 m/s (10-11 %). Correspondingly, the maximum dust concentration decreases from approximately 1 mg/m 3 to 0.82-0.85 mg/m 3 (15-20 %). Numerical simulations in MATLAB confirm the analytical results. The proposed model provides a basis for optimizing ventilation systems and improving safety in underground mines.

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A coupled non-stationary model of airflow and dust transport in underground mine ventilation corridors

Key Points

Abstract

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