LAUSR

Abstract This paper explores the longitudinal distributions of airflow velocity and convective heat transfer coefficient (CHTC) characterizing duct ventilation in a construction tunnel of geothermal area. The effects of duct ventilation parameters (ⅰ)inlet airflow velocity u i n , (ⅱ) duct diameter d ∗ , and (ⅲ) distance of nozzle from working face L 0 * , are examined respectively. This work is carried out by numerical simulations with steady RANS (Reynolds-Averaged Navier–Stokes) equations for applications in tunnel airflow. Turbulence model SST k − ω (Shear-Stress Transport k-ω) combined with LRNM (Low-Reynolds Number Modelling) method are used concerning the Low-Reynolds Number effects in boundary layer region. The numerical models are validated by previous literatures, and checked for Reynolds number independence of flow field. The results show that, in a turbulent airflow forced by duct ventilation, the longitudinal distributions of surface-averaged CHTC (SCHTC) and mean airflow velocity (MAV) follow a piecewise-Gaussian-distribution law respectively. And those distributions largely depend on u i n and d ∗ , but not affected by L 0 * , except for some raised in a region close to working face. These results can assist an optimal duct-ventilation design for cost-effective tunnel space cooling in a geothermal tunnel under construction.