CET-vol95


 
 
 
 
 
 
 
 
 
 
                                                                                                                                                                 DOI: 10.3303/CET2295024 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Paper Received: 3 April 2022; Revised: 11 June 2022; Accepted: 28 May 2022 
Please cite this article as: Panzitta A., Bax C., Lotesoriere B.J., Ratti C., Capelli L., 2022, Realisation of a Multi-sensor System for Real-time 
Monitoring of Odour Emissions at a Waste Treatment Plant, Chemical Engineering Transactions, 95, 139-144  DOI:10.3303/CET2295024 
  

 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 95, 2022 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.cetjournal.it 

Guest Editors: Selena Sironi, Laura Capelli 

Copyright © 2022, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-94-5; ISSN 2283-9216 

Realisation of a Multi-Sensor System for Real-Time 

Monitoring of Odour Emissions at a Waste Treatment Plant 

Alessandra Panzitta, Carmen Bax*, Beatrice J. Lotesoriere, Christian Ratti, Laura 

Capelli 

Politecnico di Milano, Department of Chemistry, Materials and Chemical engineering “Giulio Natta”, piazza Leonardo da 

Vinci 32, Milan 20133, Italy; 

carmen.bax@polimi.it 

Currently, there is a growing interest in the development of Instrumental Odour Monitoring Systems (IOMS) for 

the real-time monitoring of odour emissions. They can be used at sensitive receptors for assessing the odour 

impact of the plant, or at plant fenceline or emission sources for process control purposes. The present work 

describes a research project, currently ongoing, concerning the realisation of an innovative IOMS network for 

the real-time measurement of odour concentration at the fenceline of a plant for the treatment of organic waste. 

More in detail, the IOMS, after a specific training phase, provides an output correlated to the odour concentration 

measured by dynamic olfactometry. As final goal, this project aims to define specific thresholds for the odour 

concentration at the plant fenceline, capable to effectively provide information about the probability of 

occurrence of odour episodes at sensitive receptors located in the surroundings of the plant. The research has 

been structured in five phases: 1) Parametric modelling study, aimed at correlating the odour concentration at 

the plant fenceline and the potential impact on the nearest sensitive receptors. 2) IOMS training for the specific 

application 3) IOMS performance verification in the field 4) Real-time monitoring of ambient air at the fenceline. 

5) Definition of variable “alarm” thresholds for the odour concentration on the basis of meteorological data. 

Results achieved until now concerning the performance verification of the instrument in the field proved, with an 

accuracy of 82% (CI95% 68-94), the capability of the IOMS to detect and recognize odours from the plant. The 

preliminary evaluation of the quantification performance highlighted that the IOMS can provide an estimation of 

the odour concentration within the confidence interval by dynamic olfactometry. 

1. Introduction 

In recent years, there has been a rising interest in applying electronic noses (e-noses), or more generically 

Instrumental Odour Monitoring Systems (IOMS), for monitoring odour emissions (Capelli et al., 2014; Deshmukh 

et al., 2015; Laor et al., 2014). Indeed, e-noses are being developed for the estimation of plant odour impact at 

sensitive receptors, or for continuous monitoring of plant operation at its fenceline (Cangialosi et al., 2018) or at 

the emission source. Currently, in Italy, the prescription within environmental permits of the permanent 

installation of IOMS at the plant fenceline for the real-time monitoring of the odour emissions is becoming more 

and more frequent (Cangialosi et al., 2018). This application is extremely relevant because the continuous 

analysis of odours close to the emissions allows the real-time identification of anomalous events, offering useful 

indications for the management of the plant and the minimization of odour impact on the receptors (Bax et al., 

2021b). In this context, this paper describes a research project concerning the development of an innovative 

IOMS network for real-time monitoring of odour concentration at the fenceline of a waste treatment plant (WTP) 

producing biomethane and quality compost.  

The overall project is structured in five phases: 1) Preliminary activities concerned the identification of the optimal 

installation points for the two instruments at the plant fenceline, through a parametric modelling study, aimed at 

correlating the odour concentration at the plant fenceline and the potential impact on the nearest sensitive 

receptors; 2) The IOMS were subjected to a training phase, involving the analysis of odour samples 

representative of the WTP odour sources and the implementation of specific quantification and classification 

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models to be further used for the real-time analysis of the ambient air; 3) The reliability of the implemented 

model was assessed by testing in the field; 4) The IOMS have been installed at the plant fenceline for the 

continuous assessment of the odour concentration; 5) IOMS outputs relevant to the monitoring phase are 

evaluated in combination with meteorological conditions and odour observations made by human “sentinels” 

occurring during the monitoring phase, with the purpose of defining suitable alarm thresholds for the real-time 

detection of odorous conditions potentially responsible for odour events in the vicinity of the plant. 

This paper, after a brief description of the plant under investigation, describes the first phases of the project (1-

3), focusing on the experimental protocol involved for defining suitable monitoring sites at the plant fenceline, 

training the IOMS and verifying their performance by means of specific field performance tests.  

2. The waste treatment plant 

The WTP under investigation converts the organic fraction of municipal wastes (OFMSW) into biomethane and 

high-quality compost. More in detail, after the separation of plastics and the de-blasting treatment, the OFMSW 

is mixed with water and undergoes anaerobic digestion. The gaseous product of the digestion is subsequently 

refined to biomethane in an upgrading section, while the solid phase of digestate is transferred to an aerobic 

composting section to produce high-quality compost. Odour emissions from the plant can be generated from 

the biofilter unit treating exhausted air extracted from the buildings storing compost and organic waste and 

biogas leaks from bio-pulpers and digester. 

3. Materials and methods 

3.1 Phase 1: Parametric dispersion model 

The first phase of the work focused on the selection of the monitoring sites of the IOMS on the basis of the 

results of a parametric dispersion modelling study of the odorous emissions from the plant. The parametric 

modelling aimed at correlating the odour concentration at the plant fenceline with the potential odour impact on 

the nearest sensitive receptors. The first step for the implementation of the model consisted in the identification 

of the main odour sources of the plant, i.e. the bio-pulpers, digesters, biofilter and the building dedicated to the 

de-sandblasting. The simulation is performed on a whole year with a spatial domain of 2000 m x 2000 m. Six 

sensitive receptors, represented by neighbourhoods located in the proximity of the plant, were included in the 

simulation. As a first result, the most impacted sensitive receptors were identified. Secondly, the hourly maps 

resulting from the simulation (i.e., the dispersion plume) were analysed by considering different meteorological 

conditions in terms of wind direction and stability classes. The points at which IOMS should be placed for the 

monitoring phase were selected as the ones included in the emissive plumes reaching most frequently the 

receptors of interest. Indeed, the detection of high odour concentrations levels at such points could most likely 

result in odour events at the sensitive receptors. 

3.2 Phase 2: E-nose training 

IOMS involved in the study 

For this study, we used two WT1 outdoor electronic noses commercialized by Ellona. For the specific 

application, the WT1 sensor arrays are equipped with 4 MOS sensors characterized by a high sensitivity to 

volatile compounds, 2 electrochemical sensors sensible to hydrogen sulphide (H2S) and ammonia (NH3), and a 

photoionization detector (PID) calibrated in isobutylene for detection of volatile organic compound (VOC).  

With the purpose of combining IOMS outputs with meteorological conditions, a weather station (Vantage Pro 2), 

marketed by Davis Instruments, has been also installed at the plant. The station provides real-time information 

about wind speed, wind direction, solar radiation, temperature, humidity, pressure and precipitation, which can 

be viewed and download via Ellona’s web interface for further processing. 

 

Data acquisition  

The training consists in the creation of a reference dataset (i.e., the Training Set – TS), including the 

characteristic “patterns” of the odours that the instrument will be exposed to during the monitoring phase, which 

the IOMS will refer for the characterization of the ambient air at the plant fenceline (Bax et al., 2020a). 

Representative samples were collected from the main odour sources of the plant according to rules of 

olfactometric sampling: the storage building of the OFMSW (Figure 1a) and the one of plastics separated from 

the organic waste, the de-sandblasting section, the biofilter (Figure 1b) and the biogas produced from anaerobic 

digestion (Figure 1c).  

 

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a)  b)  c)  

Figure 1: Olfactometric sampling of the plant main odour sources: a) OFMSW, b) biofilter, c) biogas. 

Before presenting the samples to the IOMS for the construction of the Training Set (TS), these were 

characterized by dynamic olfactometry according to EN 13725:2022. The olfactometry allowed assessing their 

odour concentration and evaluating the dilution factors to be applied to samples in order to prepare odour 

samples representative of odour events potentially occurring during the monitoring phase, whose concentrations 

are obviously lower than the ones at emission sources due to atmospheric dilution (Li Voti et al., 2018). The 

olfactometry campaigns were carried out on different days, with the purpose of including in the TS the intrinsic 

variability of the plant odour sources. During the training, also non-odorous ambient air samples were collected 

at the monitoring site, when no odour could be perceivable by operators, and were analysed to represent the 

condition of odour absence. Thus, the TS consists of six classes: “Air”, “Biogas”, “Biofilter”, “Organic waste”, 

“Plastic and Compost” and “De-sandblasting”.  

 

Data processing 

The data acquired by the instruments were processed aiming to implement first a classification model and 

subsequently a quantification model. The scheme of the data processing of this study is depicted in Figure 2 

and consists of 5 steps: data pre-treatment, feature extraction, feature selection, implementation of classification 

model using Support Vector Machine (SVM) radial algorithm and quantification model using Partial Least Square 

(PLS) algorithm.  

  

Figure 2: Work flow of data processing procedure developed within this study. 

3.3 Phase 3: Monitoring evaluation and alarm thresholds definition 

The last step of the work, which is still on-going, concerns the analysis of monitoring data about the quality and 

the odour concentration of the ambient air provided by the IOMS aimed at defining variable “alarm” thresholds 

on the basis of meteorological conditions. Indeed, as reported by Bax et al. 2021, the same odour concentrations 

at the plant fenceline could result in very different odour conditions at the receptors depending on wind speed, 

wind direction and atmospheric dispersion capability.  

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To do this, monitoring data acquired by the instruments are combined with the meteorological conditions 

measured by the weather station and with odour observations made by human “sentinels”. 

4. Results 

4.1 Phase 1: Installation site selection 

The installation points selected on the basis of the modelling results are located respectively at the western 

corner of the plant (i.e., F1) and at the eastern one (i.e., F17). Indeed, these points are those mainly downwind 

the plant and are located along the line of the prevailing wind direction, intended as the direction toward which 

the wind predominantly blows. The Figure 3 compares two hourly maps of the emissive plume associated to 

plant odour emissions related to stable and unstable meteorological conditions. The results of this first part of 

the study highlight how the impact on sensitive receptors is strictly related to atmospheric stability.  

 

a)  b)  

Figure 3: Hourly maps of the emissive plume related to stable (a) and unstable (b) atmospheric conditions. 

4.2 Phase 2: Electronic nose training 

Olfactometric results 

Table 1 summarizes the details of the odour samples used to train the IOMS. It reports the number of samples 

collected at each emission source, the measured odour concentrations and the odour concentration range of 

the diluted samples prepared and analysed for the IOMS training.  

Table 1: Details of training samples. 

 
N° Samples 

collected 

Odour concentration measured by dynamic 

olfactometry [ouE/m3] 

Odour concentration range of 

diluted samples [ouE/m3] 

Biogas 8 
390’000 - 740’000 - 810’000 - 860’000 - 

880’000 - 1’600’000 - 2’100’000 - 2’200’000 
22 - 860 

Biofilter 9 
290 - 410 - 460 - 610 - 680 - 1’000 - 1’600 - 

2’000 - 2’400 
18 - 590 

Organic waste 6 1’400 - 1’700 - 2’900 - 4’600 - 15’000 - 26’000 27 - 560 

De-sandblasting 4 910 - 2’700 - 2’900 - 12’000 18 - 270 

Plastic and 

Compost 
5 810 - 1’600 - 1’800 - 2’200 - 2’400 22 - 610 

 

Preliminary consideration 

First, PCA was applied to the TS to explore the structure of the data and obtain preliminary information about 

the IOMS discrimination capability between the different classes. Outliers were identified and removed from the 

TS. As shown in Figure 4, the PCA score plot highlights similar odour fingerprints for the classes ‘Plastic and 

Compost’, ‘De-sandblasting’ and ‘Organic waste’ samples. Thus, such samples were considered as a single 

odour class called ‘Sheds’ for tuning the pattern recognition model. This similarity is justified by the fact that the 

storage building for the organic waste fraction is contiguous with that for plastics and compost, and the de-

sandblasting department receives organic waste after initial pre-treatment and addition of water. 

 

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Figure 4: Principal Component Analysis (PCA) score plot relevant to the Training Set. 

Classification model 

PCA scores were used as input parameters for a classification model based on the SVM radial algorithm. 10-

Fold CV was used to optimize the pattern recognition model and define its tuning parameters. An accuracy close 

to 95% was achieved on 10-fold cross validation. Then, the trained IOMS were subjected to specific field tests, 

involving the analysis of 37 independent samples, to validate their classification capability. Accuracies and 

recalls relevant to the classification performance are summarized in Table 2. 

Because of maintenance activities on the biofilter, samples representative of this odour class could not be 

included in this first session of field testing. Therefore, the IOMS capability of recognizing such odour fingerprints 

will be tested in the next future.  

Table 2: Confusion Matrix for the evaluation of the e-nose capability odour classification. 

  
PREDICTION 

CLASSIFICATION 

PERFORMANCE 

  
Air Biogas Sheds AI 82% (CI95% 68-94) 

REFERENCE 

Air 13 0 0 Rair 100% 

Biogas 0 9 4 RBiogas 82% 

Sheds 0 2 9 RSheds 69% 

 

Quantification model 

A PLS regression model for each of the main odour sources of the plant (i.e., “Biogas”, “Biofilter” and “Organic 

waste”) was developed to estimate the odour concentration at the fenceline. The odour concentration of the 

training set each odour class ranges from 42 to 560 ouE/m3. The PLS models were validated by cross validation 

testing. The number of PLS components minimizing the root mean square error (RMSEP) was selected as 

optimal for tuning the PLS models (Mevik et al., 2007). Figure 5 shows the comparison between the odour 

concentrations predicted by the PLS models versus the concentration measured by dynamic olfactometry 

respectively for “Sheds”, “Biogas” and “Biofilter” samples. Plots in Figure 5 points out a very good predictive 

capability for “Sheds” and “Biogas” odour classes (i.e., a RMSEP in line with olfactometry confidence interval 

was recorded). A higher dispersion was obtained for “Biofilter” samples, most probably associated to the 

malfunctioning of the abatement system, causing an alteration of the samples composition. Specific tests for 

assessing the quantification capability by Bland-Altman approach is currently ongoing.  

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Figure 5: Predicted VS measured odour concentration for classes “Sheds”, “Biogas” and “Biofilter” 

5. Conclusions 

This paper presents the preliminary results achieved within a research project, currently ongoing, aimed at the 

realisation of an IOMS network for real-time monitoring of the odour concentration at the fenceline of a WTP 

plant. Preliminary results achieved prove the capability of the IOMS trained for the specific application of 

detecting, classifying and accurately quantifying odour events at the plant fenceline. Future developments of 

the project concern the definition of “alarm” thresholds for the odour concentration at the plant fenceline capable 

to effectively provide information about the occurrence of odour events at sensitive receptors located in the 

surrounding of the plant. Such thresholds will be implemented by combing IOMS predictions with meteorological 

data and observations of human ‘sentinels’, aiming at making the IOMS an effective monitoring tool for the 

management of the plant. 

References 

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Performance Verification in the Field. Chemical Engineering Transactions, v. 85, p. 19-24, 2021b. 

Bax, C.; Sironi, S.; Capelli, L. Definition and Application of a Protocol for Electronic Nose Field Performance 

Testing: Example of Odor Monitoring from a Tire Storage Area. Atmosphere, v. 11, n. 4, p. 426, 2020a. 

Bax, C; Lotesoriere, B. J.; Capelli, L. Implementation of a “smart” multi-sensor system with variable thresholds 

for the continuous monitoring of odour emissions from a landfill. Sardinia Symposium 2021. 

Cangialosi, F.; Intini, G.; Colucci, D. On line monitoring of odour nuisance at a sanitary landfill for non-hazardous 

waste. Chemical Engineering Transactions, v. 68, p. 127-132, 2018. 

Capelli, L.; Sironi, S.; Del Rosso, R. Electronic Noses for Environmental Monitoring Applications. Sensors, v.14, 

n. 11, p. 19979-20007, 2014. 

Deshmukh, S.; Bandyopadhyay, R.; Bhattacharyya, N.; Pandey, R.A.; Jana, A. Application of electronic nose 

for industrial odors and gaseous emissions measurement and monitoring – An overview. Talanta, v. 144, p. 

329-340, 2015. 

Laor, Y.; Parker, D.; Page, T. Measurement, prediction, and monitoring of odors in the environment: A critical 

review. Reviews in Chemical Engineering, v. 30, p. 139-166, 2014. 

Li Voti, M.; Bax, C.; Marzocchi, M.; Sironi, S.; Capelli, L. Testing procedure for performance evaluation of 

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