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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 

Flexible Method for Corrective Actions Ranking in the Field of 
Protection Against Explosion 

Serge Forestier 
Swissi Process Safety GmbH, Mattenstrasse 24, CH-4002 Basel 
serge.forestier@tuev-sued.ch 

In the European Union, assessing the hazard of the explosion in a plant of a dust or gas atmosphere is 
mandatory for its manager (European directive 1999/92/EC). This assessment relies on three different steps:  
- the identification of the position of explosive areas and their frequency (appear during normal process, 
appear rarely during normal process, do not appear during normal process, do not appear at all) based on the 
standards IEC 60079-10-1 for gas atmospheres and IEC 60079-10-2 for dust atmospheres  
- the identification and the assessment of the frequency occurrence of ignition sources based on the standard 
EN 1127-1 
- the assessment of the plausible consequences of an explosion based on the standard ISO 14121-1.  
When the assessment highlights that the hazard of explosion is too high, some corrective measures must be 
implemented to decrease this hazard to a reasonably value. It is common that for a large plant, several 
dozens of actions need to be implemented. 
To the authors’ knowledge, there is a lack of method in the literature to help HSE engineers to rank the actions 
to be taken. What should be corrected first? A very rare deviation that could severely injure or even kill an 
operator or a less dangerous but more frequent one? 
This paper proposes a method derived from the determination of a SIL level (standard IEC 61511-3). A similar 
decision tree is build which is based on the consequences of the explosion defined in ISO 14121-1. It takes 
into account the probability of attendance of an operator in the hazardous area and the frequency of 
occurrence of an ignition source and of an explosive atmosphere. 
This method gives an index for each couple of [consequence of an explosion/ frequency of occurrence of an 
explosion]. It thus permits to compare each situation and correct the one with the highest index first.  
This method is very flexible and can be adapted to every situation. It allows emphasizing one or two of the 
used parameters according the safety policy of the firm who uses it. It is thus possible to justify to the 
authorities the choice of the prioritized actions. This method will be illustrated with two case studies.  

1. Introduction 

The protection against an explosion is a hot topic since decades with still improving results. Tools were 
developed to accurately define the position of a flammable atmosphere and to remove the possible ignition 
sources (R. L Rogers, Broeckmann, & Maddison, n.d.; Tixier, Dusserre, Salvi, & Gaston, 2002). The European 
directive 1999/92/EC (European parliament, 1999) so called ATEX 137 requires an explosion protection 
document for each plant handling flammable substances. Every equipment must be considered and 
depending on the frequencies of a flammable atmosphere and of an ignition source, it is determined whether 
or not corrective actions must be implemented (part 2) without taking into account the possible effects of an 
explosion on the operator. It means that an explosion taking place in a place exempt from people will be 
considered as dangerous as one taking place when an operator himself ignites it. Even though the 
consequences of the two explosions differ, a standard ATEX assessment considers the two incidents with the 
same criticality. In order to improve that point, some countries such as Germany started to integrate parts of 
classic risk analysis (FMEA and risk matrix method) but out of the scope of the designed classes defined 
during an ATEX assessment (part 3).  

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1648066

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Forestier S., Dien J., Suter G., 2016, Flexible method for corrective actions ranking in the field of protection against 
explosion, Chemical Engineering Transactions, 48, 391-396  DOI:10.3303/CET1648066  

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This paper presents a method (part 4) derived from the Safety Integrated Level determination method (IEC, 
2003) in order to refine the criticality of an explosion. It permits:  
1. to accurately assess the criticality of an explosion thanks to the assessment of the consequences of the 
explosion, the frequency of attendance of the operator in the dangerous area, the possibility for the operator to 
avoid an explosion and the frequency of occurrence of a hazardous situation based on ATEX assessment 
criteria 
2. to rank the situations and clearly and easily define what are the most critical situations.  

2. ATEX risk assessment 

Since 2003, the ATEX directive requires that an explosion protection document needs to be prepared in any 
plant where a flammable atmosphere could appear using an ATEX risk assessment. An ATEX risk 
assessment is a four steps process:  
1. Identify where a flammable atmosphere could occur and estimates its frequency of occurrence,  
2. Estimate the frequency of occurrence of 19 different ignition sources for each identified flammable 
atmosphere 
3. Define if each configuration (flammable atmosphere – ignition source) represents a hazard 
4. Propose different corrective measures to sustain a sufficient level of safety. 
  
The frequency of occurrence of a flammable atmosphere can be defined knowing the duration of the process 
during a year (Table 1). 

Table 1: Ex-zoning (IEC, 2008; IEC, 2015) 

Ex-zone Duration of occurrence of a flammable atmosphere  Signification 
Zone 0 More than 1000 h/year Flammable atmosphere made of gas 
Zone 1 More than 10 h/year and less than 1000 h/year Flammable atmosphere made of gas 
Zone 2 More than 1 h/year and less than 10 h/year Flammable atmosphere made of gas 
Zone 20 More than 1000 h/year Flammable atmosphere made of dust 
Zone 21 More than 10 h/year and less than 1000 h/year Flammable atmosphere made of dust 
Zone 22 More than 1 h/year and less than 10 h/year Flammable atmosphere made of dust 
No zone Less than 1h/year No flammable areas 
 
The relevant ignition sources are defined in the EN 1127-1 standard (CEN, 2011). Their frequency of 
occurrence depends on the different equipments and must be assessed case by case.  
 

 

Figure 1: Hazard matrix, the configuration in the grey area must be improved. 

 

… is not expected to be present
in quantities such as to require
special precautions for the
construction, installation and use
of equipment

is not likely to occur in normal
operation but, if it does occur, will
persist for a short period only

… is likely to occur in normal
operation occasionally

… is present continuously, or for
long periods or frequently.

Zone HZ 2 / 22 1 / 21 0 / 20 

A… happens
frequently under
normal conditions 

 

B… happens during
rare deviations 

C… happens during
very rare deviations 

D… can be ruled
out or is not an
effective ignition
source 

A flammable atmosphere… 

Th
e 

ig
ni

tio
n 

so
ur

ce
...

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Each couple “Flammable atmosphere – Ignition source” is placed in a 4 x 4 matrix (figure 1). If the studied 
configuration lies in the upper part of the matrix (grey area), the configuration is too hazardous and the 
frequency of occurrence of either the flammable area or the ignition source must be lowered. 
This method does not provide any ranking. An ungrounded twenty litres drum will be considered as dangerous 
as a reactor containing flammable vapours where a flammable powder is manually introduced. This point must 
be improved in order to increase the efficiency of the plant management. 

3. Overview of the existing methods 

Several European countries have enforced additional rules, especially in Germany. Overviews of three 
different countries are given below. 

3.1 Swiss method 
The Swiss authorities follow the European standards. No additional method is emphasised and the criticality of 
an explosion on an operator does not influence the importance of a configuration. 

3.2 French method 
The French authorities follow the European standards but sometimes require a deeper study taking into 
account the effects of an explosion on an operator. In that case there is a lack of methods. The only scale in 
terms of injuries or death of people is used for the assessment of the consequences of an accident outside the 
plant (Ministre de l’écologie et du développement durable, 2005) but cannot be used as it is for the 
assessment of an explosion on site since the overall method aims quantitatively to estimate the frequency of 
occurrence of an accident. Since the frequency of an explosion depends on both of the frequencies of 
flammable atmosphere and ignition sources, the usage of the previous matrix is thus difficult since a third 
parameter must be added.  

3.3 German method 
Some German associations like the Association of German Engineers (VDI) propose in different German 
standards and recommendations (e.g. VDI, 2013a) the use of either a risk matrix method or an FMEA risk 
analysis. These two methods differ from an ATEX risk assessment in the sense that the probability of an 
explosion needs to be assessed.  
FMEA and risk matrix method are semi-quantitative methods. An FMEA assessment is based on frequencies 
of occurrence of an event and the distinction between normal operation, frequent fault or infrequent fault as 
described in EN 1127-1 (CEN, 2011) disappears. Two other parameters, the detectability (the index ranges 
from 1 to 10) and the severity (the index ranges from 1 (harmless incident) to 10 (loss of life or irreparable 
damage to health)) are taken into account. The product of the 3 indexes gives an estimation of the hazard 
level. The frequency of attendance of an operator is not taken into account. This method permits to rank the 
situations one to another. The German guidelines recommend to install some constructive measures to 
protect the operators from an explosion if the product of the three index is higher than 150.  
The risk matrix method differs from the FMEA method in the sense that the probability of an explosion 
depends on the zone defined and on the occurrence of the ignition source. In that sense, this method really 
corresponds to the ATEX policy. The severity presents the same boundaries as the FMEA method. It is thus 
not possible to take into account the probability of attendance of an operator in the vicinity of the explosion. 
The absence of index does not allow a clear ranking between the different actions to be taken. 

4. Proposed method 

An ATEX assessment aims at protecting the operators from the effects of an explosion. Obviously, an 
explosion must be avoided as far as possible but the different presented methods can perhaps be improved 
by putting together the two main assets of the FMEA and risk matrix methods:  

- easy ranking of the hazardous configurations 
- matching of the method with the ATEX definition of frequency of occurrence of an ignition 

This goal can be achieved by adapting the SIL determination method.  

4.1 SIL determination method 
The IEC 61511-3 (IEC, 2003) proposes a method of determination of the required SIL level based on a risk 
graph and on the following parameters:  

- Consequences on the operator of the explosion (C parameter) from an harmless accident (C1) to the 
death of an operator) 

- Exposure time parameter (F parameter), often or not 
- Probability of avoiding the hazardous event (P parameter), yes or no 
- Frequency of occurrence of the hazardous event (W parameter) from rare (W1) to often (W3)  

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The approach can be summarized in the following tree (Figure 2):  
 

 

Figure 2: Decision tree for SIL level determination. 

Depending on the chosen values for each parameter, the user easily defines the required SIL level for the 
configuration that he studies. The number of possible options decreases with the consequences on the 
operator since the protection of an operator must less rely on human factors as the hazard increases. When 
the C3 (severe injuries) and C4 (death of an operator) cases are considered, the highest possible value 
should be chosen for the missing parameters. On the other hand, when using the C1 parameter (harmless 
accident) F1 and P1 values can be used. This approach can be adapted for an ATEX assessment.  

4.2 Adaptation to an ATEX assessment 
Some bonds exist between SIL and ATEX assessments. The German VDI/VDE 2180 Part 6 (VDI, 2013b) 
proposes a method to define the proper SIL level of a protective equipment in order to decrease the defined 
Ex zone. On that basis, we propose a qualitative approach to rank the explosion hazard based on the same 
two parameters as a SIL assessment. The first parameter is focused on the operator (OI) and the second is 
focused on the possibility of an explosion (W). To do so, the sub parameters C, F, P and W are adjusted and 
weighted in order to set up the priorities or to cope with the safety policy of the plant where the ATEX 
assessment is carried out. Tables 2 to 4 propose values for the sub-parameters C, F and P. In these tables it 
is considered that and accident where an operator is slightly injured (C2 in table 2) is twice more severe than a 
harmless one (C1 in table 2) and that the frequency of presence of an operator (sub parameter F in table 3) is 
as important as the possibility to anticipate the explosion (sub parameter P in table 4). The parameter focused 
on the operator (OI) can be computed by multiplying the sub parameters C, F and P. 

Table 2: Allocation for risk scores for consequences (C sub-parameter) 

Parameter C Significance Index value 
C1 No personal injuries 1 
C2 Slight injuries 2 
C3 Severe injuries 4 
C4 Death of one operator 16 

Table 3: Allocation for risk scores for exposure time parameter (F sub-parameter) 

Parameter F Significance Index value 
F1 The operator is not usually in the vicinity of the equipment 1 
F2 The operator stays near the equipment or is the cause of the explosion 2 

Table 4: Allocation for risk scores for the possibility of detection (P sub-parameter) 

Parameter P Significance Index value 
P1 The operator can detect the malfunction (noise, odour, …)  1 
P2 The operator cannot detect the malfunction leading to the accident 2 
 
The parameter W is modified in order to take into account all the possible combinations of Ex - zones and 
ignition sources. This parameter can be expressed as a function of the classes of frequency of occurrence of a 

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flammable atmosphere (from zone 2 or 22 to zone 0 or 20) and of an ignition source (from occurs during very 
rare malfunction to occurs under normal conditions). If both of these criteria are considered of the same 
importance, six different classes appear and the explosion parameter ranges from 1 to 9 (Figure 3). This 
number would be different if one parameter is considered as more important than the other 
 

 

Figure 3: Definition of the W sub parameter. 

With this method, all the information related to the ignition sources and the Ex zoning is preserved. The final 
criticality index is expressed as: 

100
)(max ,

×
×

×
=

jiji

ji
ij

WOI

WOI
IC  (1) 

 A new criticality matrix can be built (figure 4) where an explosion index is defined for each case. 

 

Figure 4: Criticality matrix. 

5. Case studies 

This method will be applied to rank two classic examples in the chemical industry: an explosion due to the 
unloading of a bag from a centrifuge and an explosion of a mixer due to an electrostatic discharge.  

5.1 Extraction of a bag from a centrifuge 
An operator is involved to empty a centrifuge. The product inside is an electrical resistive paste whose solvent 
concentration is higher than 0.5%. A zone 1/22 is defined 1 meter around the centrifuge. Due to a deviation in 
the filling procedure, the amount of powder is lower than usual, the process generated more electrical charges 
than usual and the paste is still charged with static electricity when the operator unload the centrifuge. A brush 
discharge occurs between the bag and the centrifuge and the cloud of solvent ignites. The operator is slightly 
injured but manages to stop the fire.  
Using a standard risk assessment (figure 1), some corrective measures should be carried out (zone 1 / ignition 
source occurs under normal conditions). Using the proposed method, the following indexes are defined: the 
operator is slightly injured, a C2 value is defined. The hazard of ignition is only present while the operator 

   Ex - Zone 

F
re

qu
en

cy
 o

f o
cc

ur
en

ce
 o

f a
n 

ig
ni

tio
n 

so
ur

ce
 

  Zone 0 - 20 Zone 1 - 21 Zone 2 -22 

 Index 3 2 1 

Under normal 
conditions 3 9 6 3 

Under 
predictable 
malfunction 

2 6 4 2 

Under rare 
malfunction 1 3 2 1 

 

9 6 4 3 2 1
C1 1

P1 2

P2 4

P1 4

P2 8

F1 8

F2 16

C4 64 100.00 66.67 44.44 33.33 22.22 11.11

1.39

25.00 16.67 11.11 8.33 5.56 2.78

C3
12.50 8.33 5.56 4.17 2.78

0.69

12.50 8.33 5.56 4.17 2.78 1.39

F2
6.25 4.17 2.78 2.08 1.39

0.35

4.17 2.78 2.08 1.39 0.69
C2

F1
2.08 1.39 1.04 0.693.13

6.25

O
I Zone index

1.04 0.69 0.52 0.35 0.171.56

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works, a F2 factor is defined. The operator is not aware that the product still contain electric charges, a P2 
factor is defined. Using the coefficients in the tables 2 to 4 and in the figure 3, the Operator Index is worth 8. 
The area around the centrifuge during its emptying is a zone 1 and a brush discharge does not usually appear 
under normal conditions. The W parameter is set at 4. The criticality index of this accident is 5.56 

Table 5: Summary of the chosen values and Criticality Index 

C F P OI W CI 
C2 F2 P2 8 2 5.56 

5.2 Explosion of a mixer 
An operator notices that the manhole of a mixer is opened while working. An ignition occurs when he 
approaches the lid. He is severely burned at his back.  
Using a standard risk assessment (figure 1), this situation would also need improvements (zone 2 around the 
manhole and ignition source occurring under normal operation). Using the proposed method, a C3 and a F1 
coefficients are defined since the operator is severely injured and that he just walks near the equipment when 
the explosion occurs. Since he is severely burned, a P2 factor is considered. Besides, the W parameter is set 
at 3. The criticality index of this accident is also 4.17. 

Table 5: Summary of the chosen values and Criticality Index 

C F P OI W CI 
C3 F1 P2 8 3 4.17 

5.3 Summary 
These examples present two situations that need corrective actions according to the standard procedure of an 
ATEX assessment. Thanks to this new method, it is now possible to define that the first situation should be 
solved first. It is shown that with the describe method a ranking of actions can be provided. 

6. Conclusion and outlooks 

This paper presents a qualitative method aiming to improve an ATEX assessment. This method is based on 
the SIL determination procedure and uses the same basis: a parameter focused on the operator and another 
one focused on the possibility of an explosion. A criticality index is defined for each considered situation 
depending on the value of each parameter and permits to rank them one another. The expression of the 
different parameters can be adjusted according the safety policy of the firm and can lead to different ranking 
for the same scenarios. This method a real improvement towards an FMEA and a risk matrix method in an 
ATEX assessment since the accurate frequency of the ignition source does not need to be assessed as it is 
for an FMEA while ranking between the different situations clearly appears unlike a risk matrix method 
analysis.  

References 

Chapter 2 CEN, 2011, Explosive atmospheres - Explosion prevention and protection - Part 1 
European parliament, 1999, Directive 1999/92/EC of the European parliament and of the council of 16 

December 1999 on minimum requirements for improving the safety and health protection of workers 
potentially at risk from explosive atmospheres  

IEC, 2008, Explosive atmospheres - Part 10-1: Classification of areas - Explosive gas atmospheres 
IEC, 2015, Explosive atmospheres - Part 10-2: Classification of areas - Explosive dust atmospheres 
IEC, 2003, Functional safety – Safety instrumented systems for the process industry sector – Part 3: Guidance 

for the determination of the required safety integrity levels 
ISO 14212-1, 2007, Safety of machinery – Risk assessment – Part 1 : Principles 
Ministre de l’écologie et du développement durable, 2005, Arrêté du 29/09/05 relatif à l'évaluation et à la prise en 

compte de la probabilité d'occurrence, de la cinétique, de l'intensité des effets et de la gravité des conséquences 
des accidents potentiels dans les études de dangers des installations classées soumises à autorisation 

Rogers, R. L., Broeckmann, B., & Maddison, N. (n.d.). A RISK ASSESSMENT STANDARD FOR 
EQUIPMENT FOR USE IN POTENTIALLY EXPLOSIVE ATMOSPHERES: THE RASE PROJECT. 
Symposium Series, 147. 

Tixier, J., Dusserre, G., Salvi, O., & Gaston, D. (2002). Review of 62 risk analysis methodologies of industrial 
plants. Journal of Loss Prevention in the Process Industries, 15(4), 291–304. 

VDI, 2013a, Dust fires and dust explosions – Part 7.1 
VDI, 2013b, Safeguarding of industrial process plants by means of process control engineering (PCE) – Part 6 

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