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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 

 
Experimental Evaluation of LPG Release and Dispersion  

in the Enclosed Car Parks 
 

Dorota Brzezinska, Adam S. Markowski 
 
Lodz University of Technology, Faculty of Process and Environmental Engineering,  
Stefana Zeromskiego 116, 90-924 Lodz, Poland;  
dorota.brzezinska@p.lodz.pl  
 
Despite the fact that LPG is used in a  large number of cars, tests have not yet been carried out on whether 
parked cars in enclosed garages are a greater threat than petrol cars. The problem of LPG-powered vehicles 
in enclosed car parks applies to both public and industrial areas. 
This paper describes real scale tests, which demonstrate conditions that can occur in a garage in the event of 
LPG release from a car installation. The validation of FDS code (NIST) for using in the case of modelling LPG 
release and dispersion in different situations is also described. Over the course of the tests, a series of six real 
scale LPG spillage experiments were performed to study emission time and cloud formation according to the 
leak size in the car installation. As a tested scenario, the release of 0.17 L of LPG in liquid phase, from the 
pipe connecting the tank and the engine, was used. On the basis of these measurements results, the 
distribution of LPG in the garage was obtained. The test results were used to create the optimal CFD model of 
LPG outflow and validation of FDS code against simulations of LPG gas release and dispersion.  

1. Introduction 

LPG (liquefied petroleum gas) is a mixture of hydrocarbon gases, mostly consisting of propane (C3H8) and 
butane (C4H10).  In winter, LPG contains more propane, while in summer, it contains more butane, but its 
average composition is about 35 % of propane and 65 % of butane. LPG exists as a gas at normal 
atmospheric pressure and temperature, but for minimalizing its volume, it is liquefied by the application of high 
pressure. Vapours of LPF gas can travel considerable distances from the source of release  to a source of 
ignition, where they can ignite, flash back, or explode. This can create vapour/air explosion hazards in 
confined spaces. In addition, car tanks may rupture if subjected to high temperatures. 
There are some publications on the technical problems with LPG powered vehicles, for example, methods for 
the determination of the required safety control levels for this process (Akyuz,  Celikb, 2015), hazards analysis 
in the LPG refuelling stations (Rajakarunakaran et al., 2015), or huge tankers (Kumar, 2013), but there are no 
publications about the problem with relatively small LPG tanks and installations, which exist in cars, which are  
very often situated in relatively small enclosures, like enclosed (very often underground) car parks. 
A study in Canada have shown that human error was the major cause of accidents involving LPG vehicles. 
The information on 80 accidents was gathered by Transport Canada’s Investigation Office and the Ontario 
Ministry of Consumer and Commercial Relations from August 1981 to May 1986. Among them, 47 cases were 
caused by human error, which accounts for 58 % of accidents (Liu et al., 1997). Further current statistics are 
unavailable.  
It is well known, that probability of LPG release from car installation always exists, and this fact promotes the 
necessity of equipping underground car parks with LPG detection systems along with automatically activated 
ventilation. In a situation where there is no ventilation, LPG vapour being heavier than air, would settle down 
at car park’s ground level, in low lying places, and would accumulate in any pockets or water outflows. 
Jet fans are often applied to support ventilation process in car parks (Viegas, 2010). The jet fans are mounted 
under the ceiling of the enclosure to generate momentum. This causes induction of air and promotes mixing 
and transport of the polluted air. The Jet fan system is a stream ventilation system, ductless, based on 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1648043

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Brzezińska D., Markowski A., 2016, Experimental evaluation of lpg release and dispersion  in the enclosed car parks, 
Chemical Engineering Transactions, 48, 253-258  DOI:10.3303/CET1648043  

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simultaneous action of a group of fans to transport the air from supply point(s) to exhaust point(s). Working in 
first gear, fans ventilate the enclosure in the quantities necessary to discharge pollutants from exhaust gases 
of cars circulating in the garage (daily ventilation). Second gear is used for smoke exhaust during a fire, and 
often in the case of LPG detection. Jet fans are often used in situations where large amounts of air need to be 
transported with a relative high velocity (Betta et al., 2010). However jet fan systems were previously used 
only for tunnels, and premature use in garages, prior to thorough testing and adaptation to the new destination 
of car parks. The design of this type of ventilation is based mostly on the CFD simulations, because it is the 
best tool for showing the conditions which may occur in a garage or tunnel in the case of fire or pollutant 
propagation (Loomans et al., 2009).  
Compared with traditional (duct) ventilation systems, CFD modelling of jet fans is much more difficult. This is 
due to the high dynamics of air flow in the vicinity of the jet fan outlet stream (Brzezinska, 2013). In addition, 
their outlets are usually equipped with guide vanes, giving the opportunity to shape the direction of the air 
stream. In result, CFD modelling of jet fan systems requires the use of special turbulent coefficients for 
resolving the Navier - Stokes equations. Because of the large gas flow rates in the case of unsealing the 
installation CFD, modelling of this phenomenon it is also very difficult and requires the execution of many tests 
in order to obtain satisfactory results, as shown in the following article. 
Fire Dynamics Simulator (FDS)  is a computational fluid dynamics (CFD) model originally created for fire-
driven fluid flow. The software solves numerically a large eddy simulation form of the Navier–Stokes equations 
appropriate for the thermally-driven flows, with an emphasis on smoke and heat transport from fires, but it is 
also used for mechanical ventilation systems analyses, sprinklers, nozzles flows etc. FDS is developed by 
the National Institute of Standards and Technology (NIST) of the United States Department of Commerce. 
Smokeview is the companion visualization program that can be used to display the output of FDS. Throughout 
its development, FDS has been aimed at solving practical fire problems in fire protection engineering, while at 
the same time providing a tool to study fundamental fire dynamics and combustion and fire protection systems 
like sprinklers, smoke detection or smoke ventilation efficacy. It was also tested as a tool for gas dispersion 
modelling. 
The problem of LPG-powered vehicles in the enclosed car parks applies to both public and industrial areas 
and there are no specific tools to analyze the emergency situations of gas release from the car installation in 
any enclosures. Because of this, real scale tests of fluid phase LPG release from the car installation were 
conducted and described in this article. On the basis of these measurement results, the distribution of LPG in 
the garage was obtained. The test results were used for creation the optimal CFD model of LPG outflow and 
for validation of FDS code against simulations of LPG gas emission and dispersion.  

2. LPG release time and dispersion measurements 

After loss of containment from the tank or other part of LPG car installation gas immediately releases and 
disperses in the atmosphere. During this process it cools, drops down and evaporates. 
LPG at atmospheric pressure and temperature is present as a gas which varies between 1.5 to 2.0 times 
heavier than air. LPG has an explosive range of 2 % to 10 % volume of gas in air. This gives an indication of 
hazard of LPG vapour accumulated in underground car parks in the eventuality of a leakage or spillage from a 
car installation. The auto-ignition temperature of LPG is around 410 °C to 580 °C and hence it will not ignite on 
its own at normal temperature, however, it is possible to ignite the cloud of gas phase LPG, through contact of 
hot car elements, which can reach even 1,000 °C. LPG gas is not poisonous in vapour phase, but can cause 
suffocation when found in large concentrations, due to the fact that it displaces oxygen. In addition to  this, the 
vapour possess mild anaesthetic properties.             

2.1 LPG car installation and the worst case scenario of gas spillage 
An LPG car installation consists of two main parts. The first  is the installation of fluid phase LPG, the second 
consists of gas vapour. In the fluid phase part, there is the tank and the pipe connecting it with the vaporizer. 
In the vaporizer, LPG is decompressed to gas and goes to the engine.  
Depending on the size of the vehicle, gas tanks can be sized from 35 L to 70 L. According to Polish 
regulations, LPG tanks with their multi-valves need to have legislative approval through an mandatory annual 
test.  As stated by the author, fatigue failure of the tank wall, caused by corrosion, is a negligible hazard. 
The tank is connecting with other parts of installation with the pipe placed under the car. Standard pipes are 
most often of 6 mm diameter and up to 6 m long. Its volume is about 0.17 L (Figure 1).  

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Figure 1. The scheme of the tested LPG installation. 

There are no statistics on the failure of LPG automotive systems. Based on surveys carried out in the vehicle 
control stations it was found that unsealed tanks are practically unheard of and, if a gas leak occurs, it occurs 
due to a leak from the installation, especially at the connecting points of its parts. This means that, if the flow 
of the whole tank is excluded, the worst case scenario, is the discharge of the gas from the rest of installation. 
This scenario was examined in the tests. In this case the full volume of fluid phase LPG which could be 
released is equal to volume of the described above pipe and equals 0.17 L. Taking into account that 1 L of 
liquid LPG creates  250 L of gas phase LPG, from 0.17 L liquid LPG we have 42.5 L of pure gas. This dilutes 
in air to 425 L of 10 % gas (Upper Explosion Limit)  and later into 2,125 L of 2 % gas (Lower Explosion Limit).  

2.2 Measurement layout  
Measurements have been carried out in an enclosure of plan dimensions  23.7 m x 4.2 m and height of 6 m 
(Figure 2). The LPG installation was mounted in the passenger car body. 

 

Figure 2. Scheme of the measurement layout for the LPG dispersion.  

 
The LPG installation was consist with a standard LPG tank with multivalve and pipe of liquid phase LPG, 
mounted under the car body. In the pipe three solenoid valves were mounted, controlled from a control panel. 
Each solenoid valve was equipped with an orifice of a diameter of 1 mm, 3 mm and 6 mm respectively, 
imitating various sizes of holes in the pipe. The layout of the installation is shown in Figure1. 
The stream ventilation system was provided in the enclosure by the jet fan with a diameter of 315 mm. This 
type of fan is most commonly used in garages. During the tests with working of ventilation, the ventilator 

Symbols: Double LPG measurement poins -height 10 cm and 30 cm
Single LPG measurement poins -  height 10 cm 
Air velocity measurement point- height 5 cm, 30 cm, 150cm 

Jetfan

Air flow

A A

7 6 5 4 3 2

1R

1L Car with LPG installation 
- LPG emision source

3L 2L4L5L6L

3R 2R4R5R6R

1

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worked in the first gear and had a flow rate of 0.61 m3/s. The jet fan’s guide vanes were sloped towards the 
floor, at an angle of 30° in relation to the longitudinal axis of the fan. LPG concentration was measured in the 
measurement points shown in the Figure 2. 

2.3 Measurement results 
To investigate the phenomenon of gas flow from the car installation and its dispersion in the garage six tests 
were conducted. The first 3 tests were without ventilation. For each leak size (1 mm, 3 mm, 6 mm) gas release 
time was estimated. Then all the tests were repeated with the jet fan switched on. The ventilation was 
switched on at the moment the detector placed at a distance of 9 m from the gas source found the LPG 
concentration at  the level of 10% of lower explosion limit. Maximum fan rotation was achieved 20 s after 
switching on the fan. The tests results are shown in the table 1.  

Table 1. Gas outflow time and rate and ventilation activation time during the tests. 

Test 
series 

Gas 
volume 

Diameter of 
the hole 

Gas outflow 
time 

Gas outflow 
rate 

Ventilation  
switch on time 

Ventilation  full 
efficiency   time 

1 0,17 l 1 mm 20,75 s 0,008 l/s Not active - 

2 0,17 l 3 mm 5,30 s 0,032 l/s Not active - 

3 0,17 l 6 mm 3,95 s 0,043 l/s Not active - 

4 0,17 l 1 mm 20,75 s 0,008 l/s 150 s 170 s 

5 0,17 l 3 mm 5,30 s 0,032 l/s 25 s 55 s 

6 0,17 l 6 mm 3,95 s 0,043 l/s 27 s 57 s 

 
The highest concentration of LPG was detected close to the source of release, during the test with the biggest 
hole diameter – 6 mm, and reached 350 % of the lower explosive limit, but this was a relatively short-lived 
phenomenon. The possibilities of explosion (concentration between lower explosion limit and upper explosion 
limit) were found for about 10 seconds and later the concentration of LPG decreased on its own. It was seen, 
that a ventilation system could be activated when the LPG concentration was already very low. 
At a greater distance from the LPG source, the concentration of gas reached much lower levels and huge 
differences of gas concentration between detectors localized at 10 cm and 30 were observed. At a distance of 
3 m from LPG outflow the concentration was still high at height of 10 cm (up to about 180 % of lower explosion 
limit), but at 30 cm it reached only 23 % of lower explosion limit (Figure 3). At a distance of 9 m from LPG 
outflow, the differences between concentrations at 10 cm and 30 cm were smaller and concentrations only 
reached  10-20% of lower explosion limit. 
 

 

Figure 3. LPG concentration 3 m from emission source with 6 mm gap (measurement point No. 3L). 

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3. CFD simulations 

On the basis on the measurements prescribed above, CFD simulations with the FDS 6 code were prepared. 
Their goal was to check, if there is possible to use FDS code for risk assessment of explosion of LPG in the 
car parks, and for the evaluation of detection and ventilation systems. All simulations were prepared in 3D 
model of the enclosure, with LPG emission source and jet fan localisation, which were identical as during the 
tests. All measurement points in the CFD model were in the same positions as during the tests.  
For grid sensitivity analysis three densities of meshes were used: 5 cm, 10 cm and 30 cm with 10 cm in the „z” 
direction. It was found that grid of 5 cm gives the best results and the LPG concentration received was very 
similar to the concentration reached in real scale tests. In the FDS simulation results, differences between 
LPG concentration at 10 cm and 30 cm, observed earlier during the tests, were mapped very well. It is shown 
in Table 2, where the concentration of LPG (represented by propane) at a height of 30 cm is presented 
graphically as being several times lower than at the level of 10 cm. 

Table 2. CFD results - LPG concentration at the height of 10 cm and 30 cm respectively (4*10-3 kg/m3 at the 
scale equals 10 %  of lower explosion limit). 

LPG concentration at the height of 10 cm LPG concentration at the height of 30 cm Scale 

 

 
Simulations results confirmed also that the jet fan ventilation has a major impact on the reduction of LPG 
concentration (Table 3). “Time” column in Table 3 means the “Time from the beginning of LPG emission”, 
which was used in the simulations. 

Table 3. CFD results - LPG concentration in two cases: with ventilation active and with ventilation not active 
(4*10-3 kg/m3 at the scale equals 10 % lower explosion limit). 

Time  Ventilation active Ventilation not active Scale 

20s 

 

50s 

 

70s 

 

110s 

 

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4. Conclusions 

The paper describes real scale tests and concentration measurements of the LPG release from the typical car 
installation. The data received from tests was used for CFD simulations in FDS 6 code and gave successful 
validation results. FDS 6 code was also used for the LPG dispersion analyses, especially for evaluating the 
ventilation systems influence on LPG dispersion in air.  
On the basis the tests and simulations it was found that: 
1. in conditions of poor ventilation released LPG accumulates on the floor of the enclosure; 
2. the LPG detectors must be located as close as possible to the floor; 
3. good ventilation (especially jet fan systems) can remove released LPG very quickly; 
4. FDS 6 code is a good CFD tool for simulation of LPG release and dispersion, and it can be used for 
analysis of: 

- the LPG explosion hazards (evaluated on the base of predicted gas concentrations),  
- the effectiveness of the ventilation systems for the LPG discharge, 
- the effectiveness of LPG detection systems. 

For further studies in this field, it is planned to make the tests and simulations of other dangerous gases 
release from different internal industrial installations. 

Acknowledgements 

The 4th State Firefighting and Rescue Unit in Lodz is kindly acknowledged for providing a garage in which the 
measurements were done, Fläkt Woods Sp z o.o. (Warsaw, Poland) - for providing a the jet fan, and Hekato  
Sp z o.o. providing a the  LPG detectors that were applied in the experiments. 

Reference 

Akyuz E.  Celikb M., March 2015, Application of CREAM human reliability model to cargo loading process of 
LPG tankers Journal of Loss Prevention in the Process Industries, Volume 34, Pages 39–48. 

Betta V., Cascetta F., Musto M., Rotondo G. , 2010, Fluid dynamic performances of traditional and alternative 
jet fans in tunnel longitudinal ventilation systems, Tunnelling and Underground Space Technology 25, 
415–422. 

Brzezinska D., 24-26th June 2013, Fds Jet Fan Stream Modelling –Comparison With Experimental Data, 13th 
International Fire Science & Engineering Conference INTERFLAM 2013, Royal Holloway College 
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Kumar P. Fire disaster following LPG tanker explosion at Chala in Kannur (Kerala, India): August 27, 2012, 
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Liu  E.,  Yue S.Y., Lee J., 1997, A Study on LPG as a Fuel for Vehicles, Research and Library Services 
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Loomans M., Lemaire A.D., Plas M. v.d., 2009, Results from a CFD reference study into the modelling of heat 
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expert elicitation for evaluation of risks in LPG refuelling station Journal of Loss Prevention in the Process 
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Underground Space Technology 25, 42–53. 

 
 
 

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