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Abstract
In this paper the FDS 6 code ability to simulate the airflows generated by jet fans in a real road tunnel is studied. A transient model of the 898 m long bi-directional highway Polana tunnel is created including details of the tunnel geometry as emergency lay-bys and traffic signs. The absolute roughness of the tunnel walls of 70 mm is determined to represent the influence of curved tunnel geometry and tunnel equipment not explicitly modelled on the tunnel airflows and their retardation. The simulations results are compared against on-site measurements during a full-scale ventilation test conducted in the Polana tunnel in 2017. The comparison includes steady-state bulk airflow velocity and velocity profile investigated by a grid of five anemometers. The simulations results are in good accordance with experimental data with relative errors below 2% for bulk velocities and typically below 9% for velocities measured by particular grid anemometers. Specific circumstances where errors exceed the latter value are discussed. The influence of unknown external dynamic pressure fluctuations on the simulation results is also analysed. Optimal settings for parallel computations are determined from the point of view of simulation accuracy and performance. The model is intended for purposes of tunnel fires modelling.
Acknowledgements
The authors would like to thank P. Schmidt and B. Lorinczova (National Motorway Company) for technical specifications of the Polana tunnel and P. Pospisil (IP Engineering GmbH) for the measurement data.
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No potential conflict of interest was reported by the authors.
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Peter Weisenpacher
Peter Weisenpacher studied theoretical physics at the Comenius University, Faculty of Mathematics and Physics in Bratislava and received his Ph.D. degree in 2003. He works as Senior Scientist at the Slovak Academy of Sciences, Institute of Informatics. His current research interests include computational fluid dynamics, fire computer simulation and parallel computing. He participates in various research projects on fire simulation.
Lukas Valasek
Lukas Valasek graduated in applied mathematics in 2012, received his Eng. degree in mathematical and computer modelling at the Slovak University of Technology in Bratislava, Faculty of Civil Engineering and his Ph.D. degree in applied informatics at the Slovak University of Technology in Bratislava, Faculty of Informatics and Information Technologies. He works for the Institute of Informatics, Slovak Academy of Sciences in Bratislava. His major research interests include mathematical modelling and computer simulation of fires and their consequences.