On the interaction of wind, fire intensity and downslope terrain with implications for building standards in wildfire-prone areas

Edalati-nejad, Ali; Ghodrat, Maryam; Sharples, Jason J.

doi:10.1071/wf22124

Int. J. Wildland Fire

2023

DOI: 10.1071/wf22124

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On the interaction of wind, fire intensity and downslope terrain with implications for building standards in wildfire-prone areas

Ali Edalati-nejad¹,

Maryam Ghodrat

Jason J. Sharples³

Abstract: Background Wildfires can have detrimental impacts on the environment and urban structures when they spread from wildland areas. Aims In this work, a numerical study was performed to investigate the effect of downslope terrain on fire-induced flows in the presence of a building structure. Fires with intensities of 4 and 15 MW m−1 were considered on inclined terrain with downslope angles varying from 0° to −30°, and wind speeds of 6 and 12 m s−1. Methods Simulations were conducted using a large edd… Show more

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Cited by 4 publications

References 39 publications

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A Comparison of the Effects of Different Slopes on Building Reaction in Wind Zones

Saxena,

Himabindu,

Helena Raj

et al. 2024

E3S Web of Conf.

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Understanding and analysing wind-induced vibrations is a crucial part of the overall evaluation, design, and construction of high-rise building structures. Developers are exploring and using sloped or steep terrain for construction due to the ongoing trends of urbanisation, the ongoing demand for housing, and the constraints placed on available land resources. This change in the landscape underscores the necessity for considerable research endeavours by requiring a comprehensive grasp of the structural equilibrium of structures positioned on slopes. To investigate how wind speed affects the way building frames respond structurally when situated on sloping terrain is the principal objective of this research project. The study considers alternative frame geometries in combination with varying ground slopes. By highlighting the Taking into account wind loads—especially in different wind zones (like III and IV)—and different slopes— from 0° to 10°—the study seeks to clarify the complex dynamics at play in the relationship between wind forces and multi storey reinforced concrete building frames. As a consequence, it is essential to determine if a hillside can sustain building loads. In order to estimate the factor of safety against the slope’s sliding collapse, this study proposes a method that takes building loads transferred to the slope into account. Wind forces might also be included in the analysis. It is feasible to consider various slopes similar to the formulation provided in the research. Research on the stability of slopes with different building configurations has been conducted. This research has discussed the measures that must be implemented for stepped foundations on hill slopes.

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A Comparison of the Effects of Different Slopes on Building Reaction in Wind Zones

Saxena,

Himabindu,

Helena Raj

et al. 2024

E3S Web of Conf.

View full text Add to dashboard Cite

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Numerical study of the effects of fire on the flow and wake structures of an idealized building

Sun,

Chen,

Zheng

et al. 2024

Physics of Fluids

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Fire hazard is a crucial issue in urban arears. Fire plumes have large buoyancy forces and can significantly change the flow pattern around buildings. However, the interaction of these plumes with buildings under atmospheric boundary flow conditions has rarely been studied, and the effect on the wake characteristics of the buildings remains unclear. To investigate the interaction of fire with the wake flow around a building, the large-eddy simulation framework is used to simulate the flow and wake structures of an idealized cubic building. Fire is found to produce significant changes in the wake structures. In particular, fire leads to strong fire-swirl vortices near the trailing edges of the building and intense fire-plume vortices in the midair region downstream of the building. In the time-averaged results, a pair of tip vortices appears behind the top corners of the building and counter-rotating vortex pairs are observed downstream.

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Physics-based simulations of grassfire propagation on sloped terrain at field scale: flame dynamics, mode of fire propagation and heat fluxes†

Innocent

Sutherland²,

Khan³

et al. 2023

Int. J. Wildland Fire

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The interaction of wind and fire on a sloped terrain is always complex owing to the mechanisms of heat transfer and flame dynamics. Heating of unburned vegetation by attached flames may increase the rate of spread. The relative intensities of convective and radiative heat fluxes may change fire behaviour significantly. This paper presents a detailed analysis of flame dynamics, mode of fire propagation and surface radiative and convective heat fluxes on sloped terrain at various wind speeds using physics-based simulations. It was found that with increasing slope angles and wind velocity, the plume inclines more towards the ground and becomes elongated in upslope cases, whereas in downslope cases, the plume rises from the ground earlier. For higher wind velocities, the flame and near-surface flame dynamics appear to show rising, even though the plume is attached. The flame contour results indicate that the near-surface flame dynamics are difficult to characterise using Byram’s number. A power-law correlation was observed between the simulated flame lengths and fireline intensities. The convective heat fluxes are more relevant for wind-driven fire propagation and greater upslopes, whereas both fluxes are equally significant for lower driving wind velocities compared with higher wind velocities.

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On the interaction of wind, fire intensity and downslope terrain with implications for building standards in wildfire-prone areas

Cited by 4 publications

References 39 publications

A Comparison of the Effects of Different Slopes on Building Reaction in Wind Zones

A Comparison of the Effects of Different Slopes on Building Reaction in Wind Zones

Numerical study of the effects of fire on the flow and wake structures of an idealized building

Physics-based simulations of grassfire propagation on sloped terrain at field scale: flame dynamics, mode of fire propagation and heat fluxes†

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