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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 48, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Eddy de Rademaeker, Peter Schmelzer
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-39-6; ISSN 2283-9216 

CFD Modelling of Blast Waves from BLEVEs 
Olav R. Hansen, Malte T. Kjellander*  
Lloyd’s Register Consulting – Energy, Fjøsangerveien 50B, 5059 Bergen, Norway  
Malte.Kjellander@lr.org 

Boiling Liquid Expanding Vapour Explosions (BLEVEs) are among the major hazard scenarios to be 
considered in siting studies as well as transportation safety assessments. The main hazards from BLEVEs 
consist of blast waves and projectiles, and radiation for flammable and toxicity for toxic substances. Well 
established relations exist to predict consequences for BLEVEs in the open. With increasing confinement, due 
to tanks being inside or surrounded by buildings, or tunnels for transport scenarios, the consequences from 
blast waves become more severe, while the empirical relations can no longer be used to predict the 
consequences. Blast waves from BLEVEs are partly caused by expansion of pressurized vapour head, partly 
by the rapid phase change of the boiling liquid, and further pressure waves may be generated by pressure 
oscillations and combustion. Which mechanism that will dominate the blast generation will depend on the 
vapour head volume and pressure and the degree of superheat of the liquid. FLACS, a computational fluid 
dynamics (CFD) model has been applied to model blast waves from BLEVEs. The modelling of the different 
contributions to blast waves has been validated against experiments. For accurate results, both directional 
effects due to shape of tank and the cooling during the rapid phase change must be included in the modelling. 
With the validated modeling approach the CFD model can be applied to predict partially confined BLEVE 
scenarios, including tunnel scenarios. We consider our modelling approach to be more accurate than similar 
work published in the past.  

1. Introduction 

BLEVEs might occur when vessels storing a liquid above its normal boiling point loose containment 
catastrophically. If the breach is not catastrophic, that is, if it is limited or slow, the result will be a flashing 
liquid or gaseous jet leak. For a BLEVE to occur it is necessary that the vessel ruptures entirely and 
instantaneously. The liquid will quickly be depressurized and suddenly be far above its boiling point, resulting 
in violent flashing. The appearing vapour will push away the surrounding air and if the process is fast enough, 
generate shock waves. If the gas is flammable it may ignite and cause further damage as large fireballs are 
formed, causing thermal radiation. Many common liquids are stored at such conditions, e.g. hydrocarbons, 
chlorine, carbon dioxide, ammonia and other refrigerants. Certain liquids with boiling points normally above 
ambient conditions may be heated and thereby reaching conditions where a BLEVE might occur, for example 
water in an overheated steam boiler.  
The consequences of a BLEVE are often severe and excluding escalation effects these can be divided in 
three sources: pressures waves, projectiles and – if the liquid is flammable – fireball radiation. Empirical 
methods exist to estimate the pressure and fireball effects in the open, and especially the radiation from the 
fireball have shown good agreement with experiment. The present study is concerned only with the pressure 
waves. The blast overpressure can be predicted with an analogue of the TNT-equivalence method, where the 
energy of the explosion is estimated from the available expansion energy in the vapour and/or liquid. Different 
authors suggest methods for estimating the energy to be used as input: usually assuming isentropic or 
irreversible expansion of the vapour and/or liquid to ambient conditions, and then selecting an empirically 
determined fraction of that energy. Some, if not all of these methods seem to over-predict the strength of the 
blast waves however, and they naturally may only be used in unrestricted geometries.  
There seem to be no complete consensus on the exact source of the blast overpressures. Reid (1976, 1979) 
stated that a BLEVE may only happen if the pressure and temperature is around or above the superheat limit 
temperature, so that spontaneous homogenous nucleation occurs. However, experiments have shown that 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1648034

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Hansen O., Kjellander M., 2016, Cfd modelling of blast waves from bleves, Chemical Engineering Transactions, 48, 
199-204  DOI:10.3303/CET1648034  

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strong pressure waves might be generated even though the temperature is well below this limit. Typically the 
vessel will not be completely filled with liquid: it also contains a vapour head. At tank rupture, this pressurized 
and overheated gas will cause a shock wave to form as it rapidly expands – Birk (2007) states that this vapour 
space is may be the main source of the blast wave and that the liquid evaporation may be too slow to 
contribute to far-field blasts – but might have significant effects in the near-field or propel projectiles consisting 
of pieces of the vessel. Birk also suggests there might be a scaling effect and that liquid flashing might 
produce shock waves in larger scale BLEVEs.   
Detailed CFD (computational fluid dynamics) simulations accounting for the multi-phase nature of the problem, 
including nucleation and evaporation of the subsequently expanding vapour have been carried out in 1D, but 
are currently not practical in a real three-dimensional setting. Van den Berg (2004, 2006) carried out single-
phase 2D CFD studies where the BLEVE was modelled as a pseudo-source through a boundary-condition 
where the evaporation-rate was driven by inertial forces. Simulating the flashing liquid is computationally 
expensive and currently not practical to use in industrial-scale risk analysis. The present study aims to create 
a source-model that can be used in three-dimensional simulations with readily available commercial 
softwares.  
The approach presented considers both the vapour and liquid sources of pressure waves. The vapour is 
modelled in a straightforward manner while a pseudo-source models the liquid. The liquid energy is 
represented by an overpressure region containing expansion energy equal to the energy available for flashing 
and expansion in the liquid space, with the flashed gas cooled to ambient boiling point of the liquid. The 
models are used in a regular Navier-Stokes solver. 

2. Experiments  

Our simulations are mainly based on the experiments conducted by British Gas (Johnson et al., 1991) and 
Birk et al. (2007). The British Gas experiments centered on a base case of a 5.7 m3 tank filled with 2 metric 
tonnes of butane. Blast overpressures, projectiles, fireball size and resulting radiation were measured and 
documented. A parametric study was made varying tank size, fuel mass, pressure and gas. The fuel was 
heated using electrical heaters inside the tanks until desired temperature and pressure. Shaped charges 
placed along the top of the tanks were used to initiate catastrophic failure. The method of heating and rupture 
produced repeatable results with the tanks failing in similar manner. The scale and repeatability makes the 
experiments suitable for the purpose of developing methods to predict the effects of the BLEVE and will serve 
as benchmark tests for the present study.  
Birk et al. presents a number of BLEVE experiments conducted over a decade. The tanks were heated until 
they ruptured: this is realistic but for our purposes the opening is less controlled and the repeatability is limited. 
They distinguished between what they designate one-step and two-step BLEVEs. The one-step process was 
described to be a single continuous opening of the tank that is too fast for the flashing of the liquid to do any 
work on the tank, and the vapour space is therefore partly depleted while doing work to rupture the tank. In the 
two-step BLEVE the opening temporarily stops or slows down as the pressure of the vapour space is 
depleted, and a second opening stage occurs when flashing from the liquid quickly replenishes the vapour 
space. When the tank eventually ruptures there is more energy available in the vapour, which causes stronger 
blast waves. It is likely that the opening is re-accelerated before the pressure reaches the pressure of the 
initial of rupture and a conservative choice of vapour pressure at the time of final and catastrophic failure is the 
pressure at the initial rupture. Although the model is benchmarked against the British gas experiments, a 
comparison with one of the worst cases from Birk’s experiments will also be offered as a realistic test of the 
method: case 01-2 which was described as a two-step process.  

3. Problem formulation 

At the time of rupture it is assumed that the tank is filled to some level of liquefied gas.  Above the liquid there 
is a gas head at the same pressure but possibly with another temperature. Assuming an ideal opening, i.e. 
one where the tank ruptures instantly and completely, a shock wave will be formed at the interface between 
atmosphere and vapour space. This is a 2- or 3D equivalence of a shock tube problem, which has a well-
known solution and most relevant CFD tools are validated for this problem. Simultaneously the liquid space is 
quickly depressurized. Suddenly having a temperature far above the saturation temperature, the liquid starts 
to boil violently. The processes involved are not nearly as well-known as with those in the vapour space, as 
described previously. The evaporation rate for this process is not known, and shock waves will only be formed 
if this rate is rapid enough.  Depending on the circumstances, the remaining liquid might burn in a pool fire or 
continue to evaporate. The released gas will disperse or, if the gas is flammable, it may ignite and result in a 

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fireball. Delayed ignition with flash fires or vapour cloud explosions is also possible. The change in pressure 
experienced by a point in the far field due to these events may be summarized as:  
1. An initial overpressure peak caused by the expansion of the vapour space and/or the flashing of the liquid 
2. A negative phase due to overexpansion 
3. A second pressure peak due to the reflection of the expansion wave, or oscillation of the expanded gas 

cloud. 
4. Overpressure generated by combustion if the gas is flammable and ignited 

In the British Gas experiments a second peak immediately after the first sometimes occurred, but the nature of 
this peak was not thoroughly explained. It was suggested that the overpressure pulse from the vapour 
expansion sometimes merges with pressure waves emanating from the flashing of the liquid and subsequent 
expansion, while sometimes they come separated. Assuming that this is correct we have used the following 
approach: 

I. Modelling only the vapour space neglecting flashing entirely. First investigate whether the 
overpressure from the vapour space can be adequately modeled. Compare with the experiments: if 
the assumption above is correct, in the cases where the liquid and vapour peaks are separated this 
should give good predictions.  

II. Vapour and liquid. Unfortunately no large-scale experiments with only liquid were available - instead, 
the vapour and liquid spaces are modeled simultaneously and comparisons made with experiments. 
The liquid space will be modeled by a pseudo-source as described below. 

The vapour space is straightforward to model. Assuming an ideal opening, which is a reasonable model for 
the British gas experiments where explosives were used to break the tank evenly and instantaneously, this 
can be modelled directly as a volume of high pressure gas. The liquid space on the other hand is modelled by 
a pseudo-source: a second high pressure volume, but the pressure and mass are determined so that the 
irreversible expansion energy of the pseudo-source corresponds to the energy calculated from the real liquid 
source. Different methods to estimate this energy were tested, the one selected for the calculations estimated 
the mass of flashed gas and added this as a high pressure volume next to the vapour space. The temperature 
of the liquid source is set to the boiling point of the liquid as it is assumed the gas cools as it flashes. Initial 
tests showed that immediate and complete flashing resulted in overestimation of pressure peaks of an order of 
magnitude. This is not surprising as it has previously been pointed out that the evaporation may not be fast 
enough to produce pressure waves coalescing into shock waves, and e.g. Genova (2008) suggests using only 
7% of the available thermal energy when applying energy-equivalent methods. The pressure was therefore 
reduced to an empirical fraction of 20% of the initial pressure. Descriptions of these processes may be found 
in e.g. Reid (1976) and Casal, J. et al. (2002). 

4. Simulations 

The numerical computations were performed with the commercial 3D RANS-solver FLACS. A square domain 
with grid size 0.1 m in the vicinity of the tank was used. The pressure was monitored at the same locations as 
in the experiments: however the slightly inclining ground in the experiments was replaced with a completely 
flat surface. The monitor points in the simulations were located at the same height above the ground as the 
real pressure sensors and not at the height relative to the tank. Table 1 shows an overview of the test cases, 
five from the British Gas tests and one from Birk (2007).  

Table 1:  Overview of the test cases 

Experiment  Mass 
(t) 

Pressure 
(barg) 

Gas Vessel size 
(m3) 

Liquid fill 
(-) 

Liquid temp 
(°C) 

Vapour temp 
(°C) 

British gas 
experiments:  

       

1R 2 15.1 Butane 5.7 77% 95 83 
2 2 15.2 Butane 5.7 39% 101 90 
3 1 7.7 Butane 5.7 68% 50 12 
4 2 15.1 Butane 10.8 40% 82 90 
5 2 15.2 Propane 5.7 80% 35 34 
        
Birk 02—1  18 Propane 1.9 51% 57 61 
 
Figure 1 shows the pressure histories for various distances from the tank. The typical appearance of the 
BLEVE pressure wave is well reproduced and the values are either reasonably accurate or conservative. Peak 

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values for all cases are tabulated in Table 2, for comparison with experiments. Figure 2 shows the pressure 
contours along the perpendicular axis and at a horizontal plane 1 m above the ground. The 3-dimensional 
effects as a result of the elongated tank shape are clearly seen, with shock waves being stronger in the 
perpendicular direction. Reflection against the ground shows a stronger wave close to the ground. 
For most cases the simulations considering only the vapour space give pressures as high as the experiments. 
Only in some cases the pressures were lower than the experimental. Especially BLEVE 1R with the smallest 
vapour head resulted in pressure 30-40% lower than the measured. This is likely a combination of a small 
vapour head and a large degree of superheat: BG BLEVEs 3-5 have relatively low temperatures compared to 
the superheat limit. The vapour head simulations are performed by direct simulation of the vapour head the 
results show that the overpressure generation might very well be mainly due to the vapour in the tank. 
However, when the tank is mostly filled with liquid or the degree of superheat is large, also the liquid flashing 
must be taken into consideration.   

  

Figure 1: Pressure histories from sensors 1 (25 m perpendicular to axis) and 2 (25 m along axis) from BLEVE 
1R, 4, 5 and Birk 02-1 (at 20m) are shown. The typical two-peak behaviour is clearly captured by the 
simulations. 

  

Figure 2: Pressure contours of BLEVE 1R at 20 ms (left) at 60 ms (right) after rupture. Upper pictures show a 
horizontal plane 2 m above the surface, while the lower show the perpendicular cross-section. 

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Table 2: Overview result. BG refers to the British Gas experiments. All values in mbarg. 
 
Case Mass (t) Simulations 

vapour only  
Simulations  
Vapour&liquid 
 

 Experiments 

BG 1R 25 m W 
50 m W 
25 m N 
50 m N 

45 
18 
15 
6 
 

76 
26 
35 
14 

 63 
39 
18 
10 

BG 2 25 m W 
50 m W 
25 m N 
50 m N 

89 
35 
40 
16 
 

96 
40 
45 
20 

 50 
28 
16 
11 

BG 3 25 m W 
50 m W 
25 m N 
50 m N 

30 
12 
10 
4 

76 
24 
37 
14 

 10 
5 
4.5 
- 
 

BG 4 25 m W 
50 m W 
25 m N 
50 m N 

110 
42 
30 
19 

138 
47 
68 
27 
 

 82 
34 
9 
8 

BG 5 25 m W 
50 m W 
25 m N 
50 m N 

35 
10 
12 
5 

40 
13 
26 
9 
 

 23 
12 
11 
6 

      
Birk 02-1 10 m  

20 m  
30 m 

155 
65 
36 

300 
95 
43 

 130 
90 
60 

 
5. Conclusions 
 
A new method for simulating the pressure effects from BLEVEs in 3D has been developed. Although the 
simulations were performed with the Navier-Stokes equations, they could be even faster using the Euler 
equations without much loss of accuracy. The method enables detailed studies of actual incidents or risk 
analysis with realistic geometries, such as tunnels and process or storage facilities. 
The shock caused by the vapour head is simulated by assuming a pressure jump with instantaneous opening. 
Comparison with experiments shows that in many cases it is entirely possible for the vapour head to cause the 
measured maximum pressures without direct contribution from the liquid flashing. The liquid would in this case 
contribute indirectly by creating boiling before and during the vessel failure to build up or replenish the 
pressure, as described by Birk.  
The liquid space was modelled using a pseudo-source with a high-pressure region contained expansion 
energy corresponding to that of the liquid space in the tank. Using the entire energy severely overestimates 
the resulting pressure waves and there is a need to determine the fraction of energy that contributes to blast 
waves. This is analogous to the energy-equivalent methods using an empirical fraction of the energy.  
Some simulations underestimated the pressure when only vapour was used, and since the vapour setup is 
idealized with a perfect opening, this indicates that liquid contribution should be considered. It is worth noticing 
that, consistent with the conclusion, this happened for the cases with the largest degree of superheat and 
largest amount of liquid fill. 
The pressure histories from experiments show a distinct pattern with two or more sharp peaks. The second 
pressure wave is clearly affected by the evaporation of the liquid even if the first peak would be mainly due to 
vapour. If only vapour is present, the second peak is due to the reflection of the expansion wave and is not 
nearly as distinct, and comes much closer behind the first. Evaporation would clearly interfere with this 
process and temperature drop causes a delay of the second peak compared to when only vapour head is 
simulated. It is expected that finite evaporation rates would affect this, but this is out of the scope of this study. 

203



 
The largest advantage of being able to use CFD is that 3D effects and complicated geometries ca be 
represented which enables realistic situations to be modelled. The effect of tank shape is also captured: the 
pressure is higher in the direction perpendicular to the tank axis. In all scenarios the pressure is either similar 
to the experiments or slightly conservative. 

References 

Birk A.M., Davison C., Cunningham M., 2007, Blast overpressures from medium scale BLEVE tests, Journal 
of Loss Prevention in the Process Industries 20, 194-206, doi:10.1016/j.jlp.2007.03.001  

Casal J., Arnaldos J., Montiel H., Planas-Cuchi E., lchez J. A. V., 2002, Modeling and understanding BLEVEs, 
chapter 22 The Handbook of Hazardous Materials Spills Technology, McGraw-Hill, New York, USA  

Genova B., Silvestrini M., Trujillo F.J.L., 2008, Evaluation of the blast-wave overpressure and fragments initial 
velocity for a BLEVE event via empirical correlations derived by a simplified model of released energy, 
Journal of Loss Prevention in the Process Industries 21(1), 110-117, DOI:10.1016/j.jlp.2007.11.004 

Hemmatian B., Planas-Cuchi E., Casal J., 2014, Analysis of methodologies and uncertainties in the prediction 
of BLEVE blast, Chemical Engineering Transactions, 36, 541-546, DOI: 10.3303/CET1436091 

Johnson D.M., Pritchard M.J., Wickens M.J., 1991, A large scale experimental study of BLEVEs, British Gas 
Report No I536, the United Kingdom 

Johnson D.M. & Pritchard M.J., 1991, Large scale experimental study of boiling liquid expanding vapour 
explosions  

    (BLEVEs),  Gastech 90: The 14th Int. LNG/LPG Conference And Exhibition, 1-30. 
Laboureur D., 2012, Experimental characterization and modelling of hazards: BLEVE and boilover, PhD 

Thesis from the von Karman Institute / Université Libre de Bruxelles, ISBN 978-2-87516-055-3 
Reid, R. C. 1976, Superheated Liquids, American Scientist 64, 146–156 
Reid, R. C. 1979, Possible Mechanism for Pressurized-Liquid Tank Explosions or BLEVEs, Science 203, 

1263–1265. 
van den Berg A.C., Van der Voort, M.M., Weerheijm, J., Versloot, N. H. A., 2004, Expansion-controlled 

evaporation—A safe approach to BLEVE blast, Journal of Loss Prevention in the Process Industries 17, 
397-405, Doi:10.1016/j.jlp.2004.07.002 

van den Berg A.C., Weerheijm, J., 2006, Blast phenomena in urban tunnel systems, Journal of Loss 
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