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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 54, 2016 

A publication of 

 
The Italian Association 

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

Guest Editors: Selena Sironi, Laura Capelli 
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-45-7; ISSN 2283-9216 

Enhancing VDI3940 Grid Method via In-Field Olfactometry to 
Obtain Complete Odour Impact Assessment 

Ardevan Bakhtari*, Sidarta Medina 
Scentroid – A division of IDES Canada Inc., Markham Canada 
bakhtari.a@idescanada.com 

This study describes an enhanced method for the measurements of odour impact as per VDI3940 (VDI, 
2006), part 1. The methodology incorporates the use of the SM100i in-field olfactometer within the panel of 
assessors to determine the odour concentration in the assessed site. The results from this enhanced method 
will allow not only to understand the total odour load determined as per VDI3940 (VDI, 2006), but will also 
allow us to determine the odour concentration in terms of Odour Units obtained through a reliable in-field 
olfactometry protocol.  

1. Introduction 

Odors have been subject of regulation in diverse countries including Canada. Nowadays, odor specialists are 
studying a variety of factors to determine the impact of odours. These factors are commonly known by the 
FIDOL acronym (Naddeo, 2013): 

• Frequency 
• Intensity 
• Duration 
• Offensiveness 
• Location 

The most common approach used for assessing ambient odour concentrations is source sampling with 
dispersion modelling analysis (Bokowa, 2012). Another approach for assessing the odour impact is conducting 
field inspections by recording some of the FIDOL factors (DEFRA, 2010). In the European Union a common 
approach for assessing odours in the field is described German Guideline VDI 3940 (VDI, 2006), parts 1 and 
2. The proposed VDI 3940 (VDI, 2006),  part 1 enhanced method considers the collection of odour samples 
using a grid to determine the total odour load and the odour concentration in terms of OUE/M

3. The inclusion of 
field olfactometers lay on the limitation of the laboratory based instruments to quantify odour concentrations 
below laboratory detection level (estimated between 20 OUE/m

3 to 50 OUE/m
3) (Gostelow et al, 2003).  

2. Study General Principles 

This study was developed for the Environmental Protection Department of a refinery. The refinery had been 
receiving a large number of complaints due the proximity to urban developments. Plant’s location and Grid 
nodes (sampling points) are showed in Figure 1 

3. Assessor Selection 

For this study, the panel members were selected in accordance to section 3.3 of the VDI 3940 part 1 guide 
and according the methodology described in the EN 13725:2003 (CEN, 2003) Standard.   

4. Instruments Used 

The instruments used for field assessments according the VDI 3940 part 1, were: Digital chronometer, GPS 
device, and field sheets. To assess field odour concentrations at grid points, SM100i portable olfactometers 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1654048

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Bakhtari A., Medina S., 2016, Enhancing vdi3940 grid method via in-field olfactometry to obtain complete odour 
impact assessment, Chemical Engineering Transactions, 54, 283-288  DOI: 10.3303/CET1654048 

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were used by 2 panel members. The instrument was set up to conduct Yes/No tests according the 
EN13725:2003 (CEN, 2003). Weather data was gathered using a portable Davis Vintage Pro Plus 
meteorological station.  

 

Figure 1 Refinery location and grid points 

5. Data collection 

An initial protocol was carried out inside the plant to identify potential odorous sources and to establish the 
baseline for this study. An initial survey was carried out to identify and determine the odour characteristic 
using Curren’s odour wheel (Figure 2). The most representative odour characteristics were: Chemical 
(Gasoline/ Oil), Sulphur (Rotten Egg, Natural Gas), Burnt (Exhaust, Burnt Rubber).  

 

Figure 2 Refinery odour wheel (Curren 2012) 

6. Measurement principles 

To assess odours from each assessing point, a team of 1 administrator and 3 assessors was created. The 
assessor (A) was responsible to carry out the measurements according the section 4.1 of the VDI3940 part1. 
The two assessors (B) used the SM100i portable olfactometer to evaluate odour concentration. The assessors 
were in parallel and close to the assessor (A). The assessors (B), analyzed the ambient air in 5 duplicated 

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events within a period of ten minutes. The portable olfactometers were preset in auto mode (Figure 3), to say, 
the equipment produces automatically dilution ratios until the odour is detected by the assessor. During the 
assessment, the equipment presents blanks randomly. This presentation method is known as Yes/No and is 
described in the EN13725:2003 (CEN, 2003) standard. 

 

Figure 3 SM100i yes/no method user interface 

7. Protocol for data collection  

The assessments were carried out according (Figure 4) per grid node:  

Method 1 2 3 4 5 
VDI3940 Part 1 
Assessor A (time) 

                              
SM100i  
Assessor b (Concentration) 

                              
SM100i  
Assessor b (Concentration) 

                              
 6 7 8 9 10 

VDI3940 Part 1 
Assessor A (time) 

                              
SM100i  
Assessor b (Concentration) 

                              
SM100i  
Assessor b (Concentration) 

                              

Figure 4 Data collection schedule per grid node. 

From figure 4 Blue squares represents the evaluation of ambient air every 10 seconds that was carried out by 
the assessor (A) and according the methodology of the VDI3940 (VDI, 2006), part 1. Red squares represent 
the assessments carried out by the assessors (B) to verify the odour concentration using the portable 
olfactometer.  
For time data collection in the assessment points the assessors followed the criteria determined by the VDI 
3940 (VDI, 2006),  part 1. A total of 14 assessors were evaluated and used for this study. For odour 
concentration evaluations the administrator and the assessors (B) followed this protocol.  

Previous to data collection 
• Administrator activities 
• Prepared the forms to collect the data in the field that were used by the assessors (A) 
• Verified correct operation of the weather station wireless console, verifying the hour, battery state, 

and the correct reception of the data transmitted form the weather station.  
• Verified the power state of the tablet and the SM100i servo controller.  
• Verified the state and the pressure of the SM100i making sure the pressure in the gauge showed 

80psi as per the operating manual.  
• Verified that the cylinders were filled completely to reach the required duration.  
• Reviewed that the SCBA tanks were filled in the case that a recharge was necessary in the field.  

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During the data collection 
The assessor (B) initiates the procedure turning ON the servo controller and testing the SM100i face masks 
and verify proper sealing. This operation was performed before the assessor reached the assessing point to 
avoid exposure to predominant odours and to prevent sensitivity loses before the test started. The assessor 
initiates the SM100i application on the tablet once he/she reaches the assessing point, the application was 
configured with the sample presentation time of 10 seconds. The assessor starts the test indicating if he/she 
perceived the odour to record their response in the tablet, the assessor continues until the application 
recognizes 2 positive responses to thereafter calculate the odour concentration in OU. 

8. Results and discussions 

The odour impact study was performed in 29 nodes, which were used to create 17 assessment squares 
according figure 1. A total of 52 in field inspections were carried out per grid square for a period of 6 months, 
therefore a 3120 measurements using the VDI3940 (VDI, 2006),  part 1 methodology and a total 520 odour 
concentration readings  per assessed square were performed.  

Odour impact characteristic 
To calculate the exposition percentage time for each assessing point equation (1) was used.  	 100		(1) 
Where:  

Pod = percentage odour time at a measurement point 

L+ = number of positive responses per measurement cycle and measurement point. 

R = number of odour samples. 

The time percentage evaluation results obtained (13 per node) in which the refinery odour characteristic were 
present in more than 10% of the time are showed in Figure 5.  

 

Figure 5 Percentage odour time per node and grid squares. 

Once all the positive measurements were obtained as percentage time in which the odour was present in the 
assessed point (Pod), the odour impact characteristic was calculated. To calculate the odour impact 
characteristic per assessment square, it was considered the number of hours that each assessed square was 

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evaluated divided by the total number of samples that were taken, this was to obtain the odour impact 
characteristic as the relative frequency of odour hours. The results are shown in the image that follows.  

 

Figure 6 Odour impact characteristic per node and grid squares. 

Odour Concentration calculation 
The results for odour concentration were calculated automatically in OU/M3 by the SM100i application. Each 
node (measurement point) a total of 13 measurement cycles were performed (10 Min/ each). All cycles are 
compounded by 10 odour concentration evaluations expressed in OU/m3 obtained from the 2 assessors (B). A 
total of 130 measurements were carried out per square node, totalizing 520 evaluations per grid square.  

 
Figure 7 Ambient odour concentration per node and grid squares. 

9. Conclusions 

FIDOL factors are used typically for odour impact assessment. The main objective of this study was to 
propose an enhanced method to the VDI3940 for a more comprehensive impact assessment. VDI 3940 
guideline does not consider the measurement of odour concentration within the assessed area, therefore the 
utilization of the field olfactometer was a significant contribution for odour impact assessment.  

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From the results of this study, it can be concluded that according to the numbers shown in Figure 5, grid 
squares numbers 8, 9, 10, and 11 were the most impacted with the presence of characteristic odors related to 
refinery operations. In the aforementioned grid squares, is observed a significant presence of odors of up to 
64% of the time (Figure 6), which might be supposed as a potential problem due to the presence of odors. 
Among the odour characteristic of the refining of crude oil, the most common was the smell of burning from 
incinerators (2 units), chimneys (2 units) and one high burner corresponding to the Sulphur recovery plant. 
The analysis of odor concentration was a valuable contribution to observe certain phenomena related to 
irregular emissions. Effects of gas flaring impacted significantly the node F2, which reached 30 OU/m3. It is 
important to notice that within the measurement cycle for node F2, levels of 240 OU / m3 were encountered, 
and as a consequence this levels affected the average obtained for that node. For the nodes in the square 
grids numbers 14, 15, 16, and 17, high odour concentrations were detected. These concentrations appeared 
intermittently but they did not exceeded the percentage of odour time Pod in more than 10%, and therefore 
they were not considered as positive measures for the annual impact characteristic. Within the square grids 
14, 15, 16, and 17, concentrations ranging from 21, 22, 28, and 26 odor units were encountered, respectively. 
From the above we conclude that even though the square grids number 9, 10 and 11 showed the high 
percentages of odour impact (high frequency of appearance), the average concentration was between 10-12 
OU /m3. On the other hand, squares 14, 15, 16 and 17 presented the highest odour concentration.  

References 

Bokowa, A, 2012. Ambient Odour Assessment Similarities and Differences between Different Techniques. 
Chemical Engineering Translations, 30, 313-318 

CEN, 2003. EN13725: Air quality- determination of odour concentration by dynamic Olfactometry. Brussels: 
CEN (Committee for European Normalization).  

Curren, J., 2012. Characterization of Odor Nuisance. Los Angeles, California: University of California.  
DEFRA, D. 2010. Sniff Tests / Field Assessments by EHPs. In Odour Guidance for Local Authorities (pp. 38-

39). London: Department for Environment, Food and Rural Affairs.  
Gostelow, P., Longhurst, P., & Parsons, S., 2003. Sampling for the measurement of odours. Scientific and 

Technical Report No.17. London, Uk: IWA Publishing  
Naddeo, V., Belgiorno, V., Zarra, T., 2013. Odour impact assessment handbook. John Wiley & Sons, LTD.  
 VDI (Verein Deutscher Ingenieure). (2006). Measurement of odour impact by field inspection. VDI 3940 Part 

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