Abstract. The structural response of bridges against fire is an under researched topic not covered in current design codes in spite of its frequency and consequences. This paper uses Computational Fluid Dynamics simulations to study the parameters influencing the temperatures in the gas surrounding I girder bridges during a fire, since this is a critical parameter governing the response of the bridge. The structural behaviour of a 21 meters span bridge has been carried out with numerical models to show that the position of the fire has also an influence on the times and type of failure.
1. INTRODUCTION
The structural response of bridges against fire is an under researched topic not covered in current design codes in spite of its frequency and consequences as it is shown in Peris-Sayol et al [8]. In this paper, 154 bridge fires that happened between 1997 and 2015 were studied, and the bridge damage level and the main factors involved in bridge fire damage were characterized. This analysis showed that the scenarios likely to cause damage to concrete and steel bridges are a tanker fires close to the structure and a high calorific storage fire under the bridge, being overpasses the most susceptible infrastructure.
The temperature of the gas surrounding a specific bridge deck is a critical parameter governing the response of the bridge to a fire due to its influence on the mechanical properties of the bridge construction materials. High temperatures can cause the collapse of the bridge due to loss of resistance of the materials as it happened in the MacArthur Maze in Oakland in 2007 or in a bridge near Hazel Park in Detroit in 2009. In both cases a tanker truck carrying gasoline crashed under the bridge and caught fire, provoking temperatures higher than 900°C and decreasing the mechanical resistance of the bridge in a relatively short time. Both bridges collapsed around 20 minutes after the tanker caught fire.
This paper uses Computational Fluid Dynamics simulation to study the parameters influencing the temperatures of the gas surrounding I girder bridges during a fire. More specifically, the study considers four geometric parameters (vertical clearance, bridge substructure configuration, span length and bridge width) and two fire scenario parameters (position of the fire load and type of fuel). This study complements previous work [8] since the parameters analyzed by CFD were impossible to characterize in real cases. Also, in this paper, the structural behavior of a 21 meters span simply supported steel-girder bridge against tanker with finite element models has been studied to see if the position of the fire influence on the times and type of failure.
2. CFD ANALYSIS
This section explains the parameters analyzed, the methodology used and the CFD model building.
2.1. Parameters Studied
This study considers six parameters: four of them describe the geometry of the bridge (vertical clearance, bridge substructure configuration, span length and bridge width) and two of them (position of the fire load and type of fuel) are related to the fire scenario. Other parameters such as the soot yield or the position of bridge transverse diaphragms have not been included in this study. Table 1 and Figure 1 describe the parameters considered and the value for each parameter. It must be noted that, for all the bridges studied in this paper, the distance between two adjacent girders was taken as 2.6 m and the girder depth as 0.8 m. All the bridges also had a concrete slab 0.2 m thick on top of the I-girders.
| Vertical | Bridge | Span | Heat | Position | Width |
|---|---|---|---|---|---|
| Clearance | Substructure | Release | |||
| Configuration | Rate | ||||
| (m) | (m) | (kW/m2) | (m) | ||
| 6 | Piers | 16 | 1800 | Center-Span | 13 |
| 9 | Abutments | 24 | 2400 | Abutment | 23.4 |
2.2. Computational Fluid Dynamics Models (CFDs)
FDS Software 6.1.1 [4] has been used to obtain the temperatures in the gas surrounding the bridge deck. FDS was developed at the National Institute of Standards and Technology (NIST) and applies computational fluid dynamics (CFD) techniques to fire engineering. FDS has been successfully used to study real bridge fires [1, 2, 12]. Building the FDS model requires defining: (1) a control volume with its boundary conditions representing the volume in which the entire analysis is carried out, (2) a geometry included in the control volume which represents the geometry of the case study, (3) a mesh or discretization of the control volume, (4) material properties, (5) fire sources, (6) a combustion model, and (7) sensors or elements of the model where the outputs are recorded.
2.2.1. Control Volume and Mesh
The control volume used in this study includes the bridge as well as part of its approaches. The model varies according to the scenario from 28 to 58 meters in the x-direction, 27 to 30 meters in the y-direction and 12 to 15 meters in the z-direction. The variations depend on the span length, vertical clearance, span width and abutment configuration considered. The total amount of cells in the model ranges from 1,134,000 to 3,262,500, having all cells dimensions of 0.20 m according to FDS Technical Reference [5] for coarse mesh. This mesh is fine enough for the purpose of the present study.
2.2.2. Fire Load and Combustion Model
The FDS model includes the tanker of the tanker truck modeled as a horizontal surface of 12 x 2.5 meters at one meter above the road level. The CO and soot yields have been chosen according to the values showed in the table A.39 of the SFPE Handbook Manual [3] for hydrocarbon liquids and have values of 0.019 and 0.059 respectively. It has been assumed that diesel and gasoline have the same yields.
2.2.3. Adiabatic Temperatures
The adiabatic surface temperature developed by Wickström et Al. [11] has been used to transfer the information obtained by the fire model to the thermal model. This adiabatic surface temperature is a fictitious temperature obtained by FDS assuming that the structural element is a perfect insulator and is commonly used for calculating both convective and radiative heat transfer. The use in this paper of adiabatic temperatures is justified because it is a value that does not depend on the material of the bridge and can be used as an input in the thermo-mechanical models.
Adiabatic temperatures are measured in FDS by sensors. Sensors have been placed in cross sections along the bridge spaced 20 cm with three sensors each located in: bottom flange (sensor 0), the south face (sensor 1), and the north face (sensor 2). The total number of sensor varies according to the span length. Only the temperatures of the most heated girder are analyzed here.
2.3. Design of Experiments
A combination of all six parameters with two levels each would have required 64 simulations. Running so many simulations was undesirable due to the high computational cost. A Taguchi's method [10] has been carried out to reduce the simulations to 32, where fire scenarios are modeled to extract the maximum information and to know which interactions are important. The resulting scenarios that had to be run are shown in table 2.
| Nº Case | Clearance | Substructure | Span | HRR | Position | Width |
|---|---|---|---|---|---|---|
| (m) | (m) | (kW/m2) | (m) | |||
| 1 | 9 | Piers | 24 | 2400 | Abutment | 23.4 |
| 2 | 6 | Piers | 24 | 2400 | Abutment | 13 |
| 3 | 9 | Abutments | 24 | 2400 | Abutment | 13 |
| 4 | 6 | Abutments | 24 | 2400 | Abutment | 23.4 |
| 5 | 9 | Piers | 16 | 2400 | Abutment | 13 |
| 6 | 6 | Piers | 16 | 2400 | Abutment | 23.4 |
| 7 | 9 | Abutments | 16 | 2400 | Abutment | 23.4 |
| 8 | 6 | Abutments | 16 | 2400 | Abutment | 13 |
| 9 | 9 | Piers | 24 | 1600 | Abutment | 13 |
| 10 | 6 | Piers | 24 | 1600 | Abutment | 23.4 |
| 11 | 9 | Abutments | 24 | 1600 | Abutment | 23.4 |
| 12 | 6 | Abutments | 24 | 1600 | Abutment | 13 |
| 13 | 9 | Piers | 16 | 1600 | Abutment | 23.4 |
| 14 | 6 | Piers | 16 | 1600 | Abutment | 13 |
| 15 | 9 | Abutments | 16 | 1600 | Abutment | 13 |
| 16 | 6 | Abutments | 16 | 1600 | Abutment | 23.4 |
| 17 | 9 | Piers | 24 | 2400 | Center | 13 |
| 18 | 6 | Piers | 24 | 2400 | Center | 23.4 |
| 19 | 9 | Abutments | 24 | 2400 | Center | 23.4 |
| 20 | 6 | Abutments | 24 | 2400 | Center | 13 |
| 21 | 9 | Piers | 16 | 2400 | Center | 23.4 |
| 22 | 6 | Piers | 16 | 2400 | Center | 13 |
| 23 | 9 | Abutments | 16 | 2400 | Center | 13 |
| 24 | 6 | Abutments | 16 | 2400 | Center | 23.4 |
| 25 | 9 | Piers | 24 | 1600 | Center | 23.4 |
| 26 | 6 | Piers | 24 | 1600 | Center | 13 |
| 27 | 9 | Abutments | 24 | 1600 | Center | 13 |
| 28 | 6 | Abutments | 24 | 1600 | Center | 23.4 |
| 29 | 9 | Piers | 16 | 1600 | Center | 13 |
| 30 | 6 | Piers | 16 | 1600 | Center | 23.4 |
| 31 | 9 | Abutments | 16 | 1600 | Center | 23.4 |
| 32 | 6 | Abutments | 16 | 1600 | Center | 13 |
2.4. Results and Discussion
Table 3 shows the maximum web and flange adiabatic temperatures reached on the structure. Web temperatures are the average of the temperatures in the two web faces.
| Maximum Temperatures | Maximum Temperatures | Maximum Temperatures | ||||||
|---|---|---|---|---|---|---|---|---|
| Case | Flange | Web | Case | Flange | Web | Case | Flange | Web |
| 1 | 1126 | 1014 | 12 | 1114 | 1160 | 23 | 909 | 886 |
| 2 | 1323 | 1294 | 13 | 990 | 820 | 24 | 1073 | 1166 |
| 3 | 1301 | 1340 | 14 | 1253 | 1157 | 25 | 694 | 629 |
| 4 | 1248 | 1312 | 15 | 1178 | 1215 | 26 | 1043 | 1038 |
| 5 | 1170 | 1064 | 16 | 1225 | 1290 | 27 | 711 | 650 |
| 6 | 1288 | 1278 | 17 | 905 | 877 | 28 | 1022 | 1028 |
| 7 | 1170 | 1226 | 18 | 1162 | 1208 | 29 | 702 | 646 |
| 8 | 1081 | 1133 | 19 | 902 | 871 | 30 | 1037 | 1044 |
| 9 | 990 | 821 | 20 | 1158 | 1208 | 31 | 696 | 641 |
| 10 | 1246 | 1173 | 21 | 704 | 646 | 32 | 973 | 1000 |
| 11 | 1188 | 1216 | 22 | 1157 | 1204 | |||
To assess the significance of the parameters on the maximum adiabatic temperatures reached over the structure, an analysis of variance (ANOVA) using the STATGRAPHICS software [9] was carried out. An ANOVA statistical test compares the means of three groups in response to one or several variables and is used to determine the impact of independent variables (e.g the parameters studied) on the dependent variables (temperatures reached by the structure) in a regression analysis. This impact is given by a coefficient known as the p-value. Low p-values indicate a significant influence (Values below of 0.05) Table 4 and 5 show the ANOVA results.
| Flange Temperatures | Sum of Squares | d.f. | Mean Square | F-ratio | p-value |
|---|---|---|---|---|---|
| Principal Effects | |||||
| A: Vertical Clearance | 294352 | 1 | 294352 | 107.8 | 0.000 |
| B:Bridge Substructure | 782 | 1 | 782 | 0.3 | 0.604 |
| C: Span Length | 8739 | 1 | 8739 | 3.2 | 0.104 |
| D: Heat Release Rate | 81467 | 1 | 81467 | 29.8 | 0.000 |
| E:Position of the Fire Load | 511435 | 1 | 511435 | 187.3 | 0.000 |
| F:Bridge Width | 1214 | 1 | 1214 | 0.4 | 0.520 |
| Interactions | |||||
| AB:Clearance-Bridge Sub. | 60498 | 1 | 60498 | 22.2 | 0.001 |
| AC: | 145 | 1 | 145 | 0.1 | 0.822 |
| AD: | 6628 | 1 | 6628 | 2.4 | 0.150 |
| AE:Clearance-Position | 93894 | 1 | 93894 | 34.4 | 0.000 |
| AF: | 11044 | 1 | 11044 | 4.0 | 0.072 |
| BC: | 724 | 1 | 724 | 0.3 | 0.618 |
| BD: | 655 | 1 | 655 | 0.2 | 0.635 |
| BE: | 194 | 1 | 194 | 0.1 | 0.795 |
| BF: | 4866 | 1 | 4866 | 1.8 | 0.212 |
| CD: | 11940 | 1 | 11940 | 4.4 | 0.063 |
| CE: | 857 | 1 | 857 | 0.3 | 0.588 |
| CF: | 2484 | 1 | 2484 | 0.9 | 0.363 |
| DE: | 10029 | 1 | 10029 | 3.7 | 0.084 |
| DF: | 6705 | 1 | 6705 | 2.5 | 0.148 |
| EF: | 3588 | 1 | 3588 | 1.3 | 0.278 |
| Residuals | 27313 | 10 | 2731 | ||
| Total | 1.14E+06 | 31 | |||
| Web Temperatures | Sum of Squares | d.f. | Mean Square | F-ratio | p-value |
|---|---|---|---|---|---|
| Principal Effects | |||||
| A: Vertical Clearance | 533413 | 1 | 533413 | 93.8 | 0.000 |
| B:Bridge Substructure | 63858 | 1 | 63858 | 11.2 | 0.007 |
| C: Span Length | 5517 | 1 | 5517 | 1.0 | 0.348 |
| D: Heat Release Rate | 151161 | 1 | 151161 | 26.6 | 0.000 |
| E:Position of the Fire Load | 444768 | 1 | 444768 | 78.2 | 0.000 |
| F:Bridge Width | 532 | 1 | 532 | 0.1 | 0.766 |
| Interactions | |||||
| AB:Clearance-Bridge Sub. | 83045 | 1 | 83045 | 14.6 | 0.003 |
| AC: | 510 | 1 | 510 | 0.1 | 0.771 |
| AD: | 4305 | 1 | 4305 | 0.8 | 0.404 |
| AE:Clearance-Position | 121255 | 1 | 121255 | 21.3 | 0.001 |
| AF: | 17145 | 1 | 17145 | 3.0 | 0.113 |
| BC: | 33 | 1 | 33 | 0.0 | 0.940 |
| BD: | 3086 | 1 | 3086 | 0.5 | 0.478 |
| BE:Bridge Sub.-Position | 38680 | 1 | 38680 | 6.8 | 0.026 |
| BF: | 6239 | 1 | 6239 | 1.1 | 0.320 |
| CD: | 12050 | 1 | 12050 | 2.1 | 0.176 |
| CE: | 523 | 1 | 523 | 0.1 | 0.768 |
| CF: | 2076 | 1 | 2076 | 0.4 | 0.559 |
| DE: | 10553 | 1 | 10553 | 1.9 | 0.203 |
| DF: | 6037 | 1 | 6037 | 1.1 | 0.327 |
| EF: | 5513 | 1 | 5513 | 1.0 | 0.348 |
| Residuals | 56867 | 10 | 5687 | ||
| Total | 1.57E+06 | 31 | |||
The main conclusions of this analysis are:
-
Bridge span and bridge width do not have a significant influence on the maximum adiabatic temperatures reached on the bridge (p-values of 0.10 and 0.52 for the bottom flange temperatures and 0.35 and 0.77 for web temperatures respectively), although they do have a significant influence on the distribution of temperatures along the longitudinal axis of the bridge.
-
The bottom flange adiabatic temperatures are influenced mainly by the vertical clearance, the fuel type and the position of the fire load (p-values below 0.05 and close to 0). Web temperatures are influenced by the parameters mentioned before, but also by the bridge substructure configuration (p-value of 0.0074) due to the effect that the presence/absence of abutments has on the accumulation of smoke between two consecutive girders.
-
A tanker fire with the tanker close to the abutments is the fire load position that provokes the maximum adiabatic temperatures (values between 1100 and 1300 °C). This is due to the Coandă effect that makes the fire flames adhere to the walls of the abutments. This effect can make the fire cause problems even in bridges with high vertical clearance.
-
The location of the maximum adiabatic temperatures depends on the bridge substructure configuration and the position of the fire. If the fire happens under an intermediate span, then the maximum temperatures are usually in the bottom flange, because there is less accumulation of smoke within the girders. If the fire is close to the abutments, then the smoke accumulates within the girders and the maximum temperatures are located in the web.
3. FEM ANALYSIS
In this section a FEM Analysis of a 21.34 m span and 5 m vertical clearance steel-girder bridge has been carried out. The bridge deck has five W36x300 hot rolled steel girders that support a reinforced concrete slab 0.2 meters deep not connected to the girders and, therefore, there is no composite action. The thermo-mechanical response of the bridge is obtained with the finite element software Abaqus. The Abaqus analysis consists of 2 steps. In the first step the thermal analysis is carried out by using the adiabatic surface temperature given in the previous analysis as input and the heat transfer method provides the transient nodal temperatures against time using the thermal properties of the material. In the second step (the structural analysis), the nodal temperatures are read from the thermal analysis and corresponding temperature-dependent material properties are used to find the equilibrium of the structure at each time step. More information about the model building can be found in [6, 7].
Two different fire scenarios with the tanker truck centered under the central girder of the bridge have been considered (See Fig. 2). The first scenario with the tanker located under the bridge mid-span (scenario “fire1”) and the second with the tanker close to the east abutment (scenario “fire2”).
The purpose of carrying out two different fire scenarios is to see if the bridge have different structural behaviour when the position of the fire changes, even if the maximum adiabatic temperatures reached over the structure are in the same range (1200°C - 1300°C) as it is shown in Fig. 3, where the adiabatic temperatures along the most exposed bridge girder (Girder 3) at the steady state of the fire event are shown. Web temperatures are always higher than bottom flange temperatures due to the accumulation of smoke in the space between girders. The existence of sudden temperature steps circa 150°C for fire1 and 80°C for fire2 are explained due to the existence of a confinement caused by the diaphragms.
Figure 4 compares yielding extension and deformed shapes for both fire scenarios at collapse time.
As it is shown above, the failure of the structure is different depending on the position of the fire. When the fire is located under the mid-span, the failure occurs after 12 minutes because a high web yielding appears at mid-span in the central girders. If the fire source is located close to the abutments the structural integrity of the bridge would be affected, collapsing around 4 minutes, 8 minutes earlier than the fire1 scenario. This is caused by a high web-yielding that appears on the contact with the abutment, creating high stresses into the girder in the area affected by the fire. This effect did not appear at fire1 scenario.
4. CONCLUSIONS
This paper studies the factors that influence the maximum temperatures of the gas surrounding I-girder bridges and also applies a methodology to obtain the structural response of a 21.34 meters span steel-girder bridge subjected to two different fire scenarios.
Results show that vertical clearance, type of fuel and position of the fire load are the most influential parameters for the flange temperatures. Web temperatures are also influenced by the bridge substructure configuration. This type of analysis is very relevant as it constitutes the basis for the development of parametric temperature curves specific for bridges.
Also, it has been shown that the position of the fire load has an influence on the type and time of failure even if the maximum adiabatic temperatures are on the same range. This conclusion should be taken into account when performing a conventional analysis of the structural behaviour of bridges against fire.