Open-plan compartment fire dynamics

Understanding fire characteristics under sprinkler spray is valuable for performance-based safety design. However, fire characteristics during fire suppression by sprinkler spray has seldom been studied in detail. In order to present a fire suppression model by sprinkler spray and determine the fire characteristics after sprinkler activation in a compartment, a numerical analysis was conducted using a fire dynamics simulator (FDS). A simple fire suppression model by sprinkler spray was calibrated by comparing ceiling temperatures from experimental data. An extinguishing coefficient of 3.0 was shown to be suitable for the fire suppression model. The effect of sprinkler spray on the smoke layer during fire suppression was explained, revealing a smoke logging phenomenon. In addition, the smoke, which spread under the influence of the sprinkler spray, was also investigated. The temperature, velocity, and mass flow rate of the smoke layer through the doorway was significantly reduced during fire suppression compared to a free burn case.

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The response of exposed timber in open plan compartment fires and its impact on the fire dynamics

Proceedings of the 11th International Conference on Structures in Fire (SiF2020) ◽

10.14264/5d97785 ◽

2020 ◽

Author(s):

Sam Nothard ◽

David Lange ◽

Juan P. Hidalgo ◽

Vinny Gupta ◽

Martyn S. McLaggan

Keyword(s):

Fire Dynamics ◽

Compartment Fires ◽

Open Plan

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Post-Flashover Compartment Fire for Different Fire Ventilation Settings in a Medium-Sized Residential Room

Volume 3: Combustion Science and Engineering ◽

10.1115/imece2008-68448 ◽

2008 ◽

Author(s):

Hamed H. Saber ◽

Ahmed Kashef ◽

Alex Bwalya

Keyword(s):

Fire Tests ◽

Compartment Fire ◽

Fire Statistics ◽

Fire Load ◽

Fire Dynamics ◽

Fire Dynamics Simulator ◽

Design Fire ◽

Load Location ◽

Ventilation Scheme ◽

Selection Of

A number of fire ventilation scenarios were investigated in order to identify the proper ventilation scheme for conducting design fire tests in a medium-sized residential room of a size of 4.2 m long, 3.8 m wide and 2.4 m high. The ventilation schemes were based on using a window, door, or both with different sizes. The fuel package that was used in all scenarios consisted of a mock-up sofa made of polyurethane foam and two wood cribs underneath it. The selection of this fuel package is supported by fire statistics that many fatal residential fires begin with an item of upholstered furniture. The CFD technique was used to conduct the numerical simulations for eleven ventilation scenarios using the Fire Dynamics Simulator (FDS) version 5. The effect of window and door sizes, and fire load location on the heat release rate, burning rate, temperature during the period of fully-developed fire (post-flashover), and the onset of post-flashover and its duration were investigated.

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Fire Experiment Inside a Very Large and Open-Plan Compartment: x-ONE

Fire Technology ◽

10.1007/s10694-021-01162-6 ◽

2021 ◽

Author(s):

Egle Rackauskaite ◽

Matthew Bonner ◽

Francesco Restuccia ◽

Nieves Fernandez Anez ◽

Eirik G. Christensen ◽

...

Keyword(s):

Large Scale ◽

Fuel Load ◽

Small Scale ◽

Fire Dynamics ◽

Wood Crib ◽

Floor Area ◽

Traditional Design ◽

Fire Experiment ◽

Open Plan ◽

Design Fires

AbstractThe traditional design fires commonly considered in structural fire engineering, like the standard fire and Eurocode parametric fires, were developed several decades ago based on experimental compartments smaller than 100 m2 in floor area. These experiments led to the inherent assumption of flashover in design fires and that the temperatures and burning conditions are uniform in the whole of the compartment, regardless of its size. However, modern office buildings often have much larger open-plan floor areas (e.g. the Shard in London has a floor area of 1600 m2) where non-uniform fire conditions are likely to occur. This paper presents observations from a large-scale fire experiment x-ONE conducted inside a concrete farm building in Poland. The objective of x-ONE was to capture experimentally a natural fire inside a large and open plan compartment. With an open-plan floor area of 380 m2, x-ONE is the largest compartment fire experiment carried out to date. The fire was ignited at one end of the compartment and allowed to spread across a continuous wood crib (fuel load ~ 370 MJ/m2). A travelling fire with clear leading and trailing edges was observed spreading along 29 m of the compartment length. The flame spread rate was not constant but accelerated with time from 3 mm/s to 167 mm/s resulting in a gradually changing fire size. The fire travelled across the compartment and burned out at the far end 25 min after ignition. Flashover was not observed. The thermocouples and cameras installed along the fire path show clear near-field and far-field regions, indicating highly non-uniform spatial temperatures and burning within the compartment. The fire dynamics observed during this experiment are completely different to the fire dynamics reported in small scale compartments in previous literature and to the assumptions made in traditional design fires for structural design. This highlights the need for further research and experiments in large compartments to understand the fire dynamics and continue improving the safe design of modern buildings.

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Effects of exposed cross laminated timber on compartment fire dynamics

Fire Safety Journal ◽

10.1016/j.firesaf.2017.03.074 ◽

2017 ◽

Vol 91 ◽

pp. 480-489 ◽

Cited By ~ 15

Author(s):

Rory M. Hadden ◽

Alastair I. Bartlett ◽

Juan P. Hidalgo ◽

Simón Santamaria ◽

Felix Wiesner ◽

...

Keyword(s):

Compartment Fire ◽

Fire Dynamics ◽

Cross Laminated Timber

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Evaluation of Positive Pressure Ventilation for High-Rise Buildings in Compartment Fire Situation

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.446-449.2908 ◽

2012 ◽

Vol 446-449 ◽

pp. 2908-2913 ◽

Cited By ~ 1

Author(s):

Xiao Feng ◽

Yan Feng Li

Keyword(s):

Positive Pressure Ventilation ◽

Optimal Rate ◽

Positive Pressure ◽

Airflow Rate ◽

Compartment Fire ◽

Fire Dynamics ◽

High Rise ◽

Fire Dynamics Simulator ◽

Fire Condition ◽

Fire Scenarios

An alternate means for protecting high-rise stairwell enclosures using the positive pressure ventilation is evaluated. An analysis performed by using the Fire Dynamics Simulator (FDS) model shows that the positive pressure ventilation can be an effective method for protecting the stairwell enclosure. Three types of ventilation methods are compared in the same fire condition and the best one is determined based on the decrease of temperature in the stairwell. The optimal rate for ventilating the stair requires optimization of the airflow rate according to postulated fire scenarios for the building and the desired performance with respect to tenability conditions within the stair.

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