Characteristics of Externally Venting Flames and Their Effect on the Façade: A Detailed Experimental Study

Asimakopoulou, Eleni; Chotzoglou, Konstantinos; Kolaitis, Dionysios I.; Founti, M.

doi:10.1007/s10694-016-0575-5

Cited by 19 publications

(16 citation statements)

References 31 publications

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“…The following can be observed: Based on Group A cone data, FED 4max gives the highest FED values, as shown in Figure 1. Some values of FED 2 and FED 3max in Group A are higher than FED 4avg based on cone data, as shown in Figure 2. Based on Group B data, some values of FED 3max are higher than FED 4max as shown in Figure 3. Those data were on armchair, 17 tunnel tests on wood and plastics, 22 and n ‐hexane tested in Reference 24 as highlighted in Table 2. Many values of FED 1 , FED 2 , FED 3max , and FED 3avg in Group B are higher than FED 4avg as shown in Figure 4. …”

Section: Measured Results Reported In Literaturementioning

confidence: 99%

“…Literature results 17‐27,39‐41 on toxic gases data are used to compute the FED values from the four equations. These include the cone calorimeter data on PMMA, 18 PE, 19 PU and PA6, 23 pine needles, 20 and fir wood 27 ; full‐scale burning tests data on armchair, 17 cardboard boxes with ABS and PSF 25 ; tunnel full‐scale tests data on plastic pallets and wood pallets, 21 wood, PE and PU 22 ; fiber reinforced polymer (FRP) and others 39‐41 …”

Section: Measured Results Reported In Literaturementioning

confidence: 99%

“…Many literature results are reported on toxic gases data 17‐27 measured by oxygen consumption method. Selected data of cone calorimeter on burning polymethyl methacrylate (PMMA), polyethylene (PE), polyurethane (PU), polyamide 6 (PA6), pine needles, polyester PES, and fir wood; of full‐scale burning tests on armchair, polystyrene (PS) and PU, aircraft cabin, aerosol, wood, Acrylonitrile Butadiene Styrene (ABS), PS foam (PSF), and PES; and of tunnel full‐scale tests on plastic pallets, wood pallets, wood, PE, and n ‐hexane 17‐27 were used to calculate FED from different equations. An appropriate method is then proposed to review the available expressions of FED for assessing smoke toxicity.…”

Section: Introductionmentioning

confidence: 99%

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Assessing smoke toxicity of burning combustibles by four expressions for fractional effective dose

Chow

Han

et al. 2020

Fire and Materials

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Summary Toxicity of smoke generated in a fire is difficult to measure accurately. That is because gas sensors for measuring rapidly varying concentrations of toxic gases are not yet developed. Simple expressions are searched for quick measurement in assessing smoke toxicity practically. Four equations on calculating fractional effective dose (FED) related to toxic effluents were reported in the literature, each based on different assumptions. FED value was proposed to be calculated based on peak carbon monoxide concentration and peak carbon dioxide concentration, and transient carbon monoxide, carbon dioxide, and oxygen concentrations. The four values were compared in this article using literature data on toxic gases from different materials measured by (i) cone calorimeter; (ii) full‐scale burning tests; and (iii) tunnel full‐scale tests. Measured carbon monoxide, carbon dioxide, and oxygen concentrations by standard equipment of oxygen consumption calorimeters were used to calculate the four FED values. It is found that the values of FED based on peak carbon monoxide and carbon dioxide concentrations (denoted as FED2) are similar to the average values of FED calculated from the updated equation in the literature using the oxygen consumption calorimeters. Putting the values of FED2 in fire safety design guides is then recommended.

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Section: Measured Results Reported In Literaturementioning

confidence: 99%

Section: Measured Results Reported In Literaturementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Assessing smoke toxicity of burning combustibles by four expressions for fractional effective dose

Chow

Han

et al. 2020

Fire and Materials

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“…Externally Venting Flames are essentially flames that traverse an opening of the fire compartment and emerge to the ambient environment [7,20]. The basic compartment fire phenomena and resulting EVF shapes, as described in the majority of the currently available design guidelines, e.g.…”

Section: Characteristics Of Externally Venting Flamesmentioning

confidence: 99%

“…The flame thickness is estimated, assuming a triangular EVF shape [9], using Eq. (20). Equation (19) is also used to estimate the convective heat transfer coefficient, by neglecting the last term, associated with the shape of the receiving surface (1/d eq = 1.0) [9].…”

Section: Assessment Of Fire Engineering Design Correlationsmentioning

confidence: 99%

Assessment of Fire Engineering Design Correlations Used to Describe the Geometry and Thermal Characteristics of Externally Venting Flames

2016

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Externally venting flames (EVF) may emerge through openings in fully developed under-ventilated compartment fires, significantly increasing the risk of fire spreading to higher floors or adjacent buildings. Several fire engineering correlations have been developed, aiming to describe the main characteristics of EVF that affect the fire safety design aspects of a building, such as EVF geometry, EVF centreline temperature and EVF-induced heat flux to the fac¸ade elements. This work is motivated by recent literature reports suggesting that existing correlations, proposed in fire safety design guidelines (e.g. Eurocodes), cannot describe with sufficient accuracy the characteristics of EVF under realistic fire conditions. In this context, a wide range of EVF correlations are comparatively assessed and evaluated. Quantification of their predictive capabilities is achieved by means of comparison with measurements obtained in 30 different large-scale compartment-fac¸ade fire experiments, covering a broad range of heat release rates (2.8 MW to 10.3 MW), ventilation factor values (2.6 m 5/2 to 11.53 m 5/2 ) and ventilation conditions (no forced draught, forced draught). A detailed analysis of the obtained results and the respective errors corroborates the fact that many correlations significantly under-predict critical physical parameters, thus resulting in reduced (non-conservative) fire safety levels. The effect of commonly used assumptions (e.g. EVF envelope shape or model parameters for convective and radiative heat transfer calculations) on the accuracy of the predicted values is determined, aiming to highlight the potential to improve the fire engineering design correlations currently available.Total area of vertical openings on all walls of the compartment c (4.67)Empirical factor (Eq. 19) C p (1005 J/kg K) Specific heat of air at ambient conditions D v (m)Effective diameter of the opening d eq (m)Characteristic length scale of an external structural element E b (kW/m 2 ) Black body emissive power g (9.81 m/s 2 )Gravitational acceleration H 0 (m)Opening height H u (13,100 kJ/kg O 2 )Heat release of cellulosic fuels for each kilogram of oxygen consumed h eq (m)Weighted average of openings heights on all walls k (m -1 ) Extinction coefficient k fuel (m -1 ) Extinction coefficient for the combustion products of a specific fuel L L_0.05 (m) Flame height at the ''continuous flame'' (5% flame intermittency limit) L L_0.50 (m) Flame height at the ''intermittent flame'' (50% flame intermittency limit) L L_0.95 (m) Flame height at the ''far-field flame'' (95% flame intermittency limit) L L (m) Height of EVF L H (m) Projection of EVF L f (m) Flame length l (-) Characteristic length scale (Eq. 9) l x (m) Length along the EVF centerline, originating at the opening _ m a (kg/s) Air mass flow rate (entering the fire compartment) _ m f (kg/s) Fuel mass flow rate _ m O2 (kg/s) Oxygen mass flow rate _ m g (kg) Mass flow rate of unburnt gases venting outside the fire compartment _ Q (MW) Heat Release Rate _ Q ex (MW) Excess Heat Rele...

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Performance of a ventilated‐façade system under fire conditions: An experimental investigation

2020

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Summary During a fire event, ventilated facade systems may contribute to external fire spreading to the upper floors of a building via the facade, thus representing a significant risk. In this frame, the performance of a typical ventilated façade system under fire conditions is experimentally investigated, using a full‐scale compartment‐facade test rig. Two alternative façade configurations are examined and comparatively assessed, namely a plain façade (PF) and a ventilated façade (VF) system. Emphasis is given on the estimation of the thermal characteristics of the developed Externally Venting Flames (EVF) and the thermal boundary conditions developing on the façade's exposed surface. An extensive set of sensors was installed at the interior of the fire compartment, the façade systems and the exterior of the test configurations. Analysis of the experimental data suggests that even though gaseous combustion products managed to penetrate the air cavity of the VF system, no consistent flaming conditions were established. On the unexposed face of both PF and VF systems, temperatures remained constantly below 180°C throughout the duration of both fire tests. The Eurocode correlations are assessed against the obtained experimental data; certain parameters, such as EVF length, width and centreline temperature, are found to be under‐estimated by the Eurocode methodology.

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Characteristics of Externally Venting Flames and Their Effect on the Façade: A Detailed Experimental Study

Cited by 19 publications

References 31 publications

Assessing smoke toxicity of burning combustibles by four expressions for fractional effective dose

Assessing smoke toxicity of burning combustibles by four expressions for fractional effective dose

Assessment of Fire Engineering Design Correlations Used to Describe the Geometry and Thermal Characteristics of Externally Venting Flames

Performance of a ventilated‐façade system under fire conditions: An experimental investigation

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