Analysis of natural ventilation of refuge floor in High Rise Buildings

TL;DR

This study uses computational fluid dynamics to analyze natural ventilation strategies for refuge floors in high-rise buildings, emphasizing window placement and opening size to ensure safety during fires without mechanical ventilation.

Contribution

It demonstrates how detailed smoke distribution analysis can optimize natural ventilation design for refuge floors in high-rise buildings.

Findings

Adequate cross-ventilation is crucial for safety.

Window placement and size significantly affect smoke and temperature distribution.

Building-specific factors influence ventilation effectiveness.

Abstract

The refuge floors have been introduced into high-rise buildings with the aim of ensuring a safe place to stay for the occupants in case of an emergency: primarily during a fire breakout. Provisionals for natural ventilation of the refuge floor have been made mandatory in all fire codes as it is not wise to rely only on mechanical methods to remove the smoke-logged inside the refuge floor. However, the effectiveness of such provisions has been questioned in many studies as it highly depends on factors such as wind direction and building geometry. In this study, using three-dimensional computational fluid dynamics modelling, it is shown that careful analysis of smoke distribution can provide the opportunity to integrate natural ventilation in an effective manner to maintain prolonged habitable conditions on a refugee floor, even without mechanical ventilation. Consequently, the performance of a refugee floor natural ventilation strategy of a proposed 70-storey building is evaluated in this study by evaluating the distribution of temperature, visibility, smoke, and Carbon Monoxide concentration during a fire breakout, with a special emphasis on windows placement and the size of the opening area. Initial windows placement was as per the code requirements and later the windows layout and the opening size were altered step by step based on the simulation findings until a safe configuration is achieved. Results showed that adequate cross-ventilation is a prime factor to establish a safe refugee floor area. Also, fire safety strategies in a building need to be evaluated to confirm their effectiveness since the dominant parameters such as wind direction, building geometry, and building orientation are not identical for each building.