Landfill Gas Monitoring Network
Development of Wireless Sensor Network Platforms
Fiachra Collins, Dylan Orpen, Eoghan McNamara, Cormac Fay and Dermot Diamond
CLARITY Centre for Sensor Web Technologies, National Centre for Sensor Research, Dublin City University,
Glasnevin, Dublin 9, Ireland
Keywords: Environmental Monitoring, Gas Sensing, Landfill Gas.
Abstract: A wireless sensor network has been developed for the application of landfill gas monitoring, specifically
sensing methane, carbon dioxide and extraction pressure. This collaborative work with the Irish
Environmental Protection Agency has been motivated by the need to reduce greenhouse gas emissions as
well as aiming to improve landfill gas management and utilisation. This paper describes the preliminary
findings of an ongoing trial deployment of multiple sensing platforms on an active landfill facility; data has
been acquired for nine months to date. The platforms have operated successfully despite adverse on-site
conditions, with validity demonstrated by reasonably strong correlation with independent on-site
measurements. The increased temporal and spatial resolution provided by distributed sensor platforms is
discussed with regard to improving landfill gas management practice.
1 INTRODUCTION
Wireless sensor networks are gaining increasing
attention with regard to environmental monitoring;
the extended temporal and spatial resolution
provided by distributed sensing nodes enable a
wealth of environmental parameters to be measured.
The need for such environmental monitoring is
driven by international legislation targeting a
reduction in greenhouse gas emissions and
improving air quality (EU, 2008). Traditionally,
such parameters have been measured using fixed
single-point sampling equipment. For example, the
Irish Environmental Protection Agency (EPA)
operates 29 fixed stations around Ireland for the
purposes of monitoring ambient air quality (EPA,
2012). The emergence of medium and large scale
sensor networks has been evident in recent years; the
first urban network for monitoring carbon dioxide
was announced in Oakland, USA (Cohen et al.,
2012), while air quality sensor networks have been
deployed in urban centres in the UK (Envirowatch,
2012). However, while WSNs are moving to the
foreground of attention with respect to
environmental monitoring, they have yet to
proliferate to their full potential. The principle
obstacles to this proliferation are price-point and
technology dependability. The extrapolation of
current sensor and platform technology costs for
scaled-up deployments is, for the most part, not
economically viable. Furthermore, the deployment
of a distributed network of sensors presents a
challenge in terms of configuration, maintenance
and multiplication of technical issues.
The environmental monitoring discussed in this
paper is specifically with regard to landfill waste
facilities. Landfill gas is primarily composed of
carbon dioxide (CO
2
) and methane (CH
4
) generated
from the anaerobic decomposition of biodegradable
waste. Modern landfill facilities contain a network
of pipes connecting perforated wells sunk into the
waste body, where an applied negative pressure
extracts the gases from the waste cells. Landfill gas
poses significant environmental hazards, both in
terms of greenhouse gas contribution and local
hazards such as asphyxiation and combustion. This
was dramatically demonstrated in Ireland in early
2011 where a subterranean fire on a closed landfill
site incurred local controversy and costly
extinguishing and remediation measures.
It can be seen therefore that substantial attention
is required to effectively manage landfill gas and
indeed utilise it for electricity generation where
methane concentrations are sufficiently high. From
the viewpoint of landfill facility operators, there are
two aspects of monitoring landfill gas: firstly at
222
Collins F., Orpen D., McNamara E., Fay C. and Diamond D..
Landfill Gas Monitoring Network - Development of Wireless Sensor Network Platforms.
DOI: 10.5220/0004314502220228
In Proceedings of the 2nd International Conference on Sensor Networks (SENSORNETS-2013), pages 222-228
ISBN: 978-989-8565-45-7
Copyright
c
2013 SCITEPRESS (Science and Technology Publications, Lda.)
Figure 1: (i) Exploded view of platform (a) microcontroller (MSP430), (b) sensors, (c) IP68 casing, (d) battery, (e) GSM
module, (f) extraction pump. (ii) Configuration of wireless sensor network deployed on landfill site.
perimeter wells to ensure against gas migration
through the waste body into the surrounding soil
beyond the confines of the site; secondly in-line with
the extraction network to maintain an appropriate
gas composition for optimum engine/flare operation.
The former aspect of perimeter landfill gas
monitoring is what initially motivated this work,
resulting in autonomous monitoring platforms being
developed and validated (Beirne et al., 2010; Fay et
al., 2011; Collins et al., 2012). The latter aspect of
in-line monitoring has been the focus of more recent
efforts and is the subject of this present paper. Gas
management via the site’s extraction pipe network is
one of the crucial aspects of landfill operation in
order to comply with environmental legislation.
Given their hazardous nature, all landfill gases must
be thermally oxidised (i.e. burned) to mitigate
against greenhouse gas emissions and local
pollution. For methane concentrations in excess of
50% v/v, the gas can be used as fuel for a CHP
(combined heat and power) engine, presenting a
financial advantage in recuperating costs by
generating electricity and selling it to the national
grid; otherwise the gas must be burned in a flare.
The composition of the gas must be precisely
controlled for effective combustion, requiring the
adjustment of flow from different waste cells within
the landfill site - this operation is called ‘field
balancing’.
The development of wireless sensor networks is
ideally suited to the landfill application, where a
typical extraction system covers an expansive area
of ground. Moreover, this terrain by nature is
difficult to traverse, implying that remote sensors
deployed in-situ represent an advantage over the
current infrequent manual sampling routines. Gas
composition monitoring would indicate the gas
generation potential of different waste cells as well
as identifying fugitive gas emissions. Measurement
of the extraction pressure can be used as a diagnostic
tool to identify loss in flow due to blockages or
leakages. The distribution of autonomous sensing
platforms in a networked configuration would
enable more informed and precise field balancing
and gas management which, in turn, represents cost
savings by promoting electricity generation and
avoiding engine/flare downtime.
The paper addresses the research challenge of
attaining reliable and accurate sensor performance
without incurring prohibitive expense. Typically,
cost and performance are inherently linked – cheaper
components fail to deliver adequate resolution,
accuracy or in-calibration duration. Traditionally,
long-term reliability is achievable only at a
substantial cost. However, the price of electronics
and sensors is continuously reducing, driven by the
ever-growing market of consumer technologies and
optimised manufacturing techniques. The integration
of such technology into deployable platforms with
WSN capabilities can fulfil the demand in industry
for low-cost long-term sensing. However, market
acceptance is only achievable if the sensing
performance is validated and proven to work. This is
the motivation behind the platform technology
described in this paper, which represents a
progression of work on developing autonomous gas
monitoring platforms with web-based accessibility
in collaboration with the Irish EPA.
The rugged construction of these autonomous
platforms, as shown in Figure 1(i), enables long-
term in-situ monitoring of transient gas events. The
system is deployable with GSM communications
enabling transmission to a remote base-station,
which parses the data onto a database and uploads it
onto an online portal. The performance of these
platforms has been validated by deployment
LandfillGasMonitoringNetwork-DevelopmentofWirelessSensorNetworkPlatforms
223
durations of up to 13 months (Collins et al., 2011).
In addition to the autonomous monitoring operation,
analysis of the data provides a value-added service
by investigating the factors affecting landfill gas
activity, evaluating the contributions of extraction
flow-rate and local weather conditions (barometric
pressure and rainfall). This paper presents the
initialisation of a deployment of multiple sensor
platforms on one site, the first of its type on an Irish
landfill site.
2 PLATFORM DEPLOYMENT
2.1 Deployment Configuration
A wireless sensor network in the form of five
autonomous platforms has been deployed on a single
active landfill site in Ireland. To minimise any
debugging issues and allow for flexibility in locating
the systems, each of the five systems has been
equipped with independent GSM modems for
wireless communications. While this may not satisfy
the classical definition of a wireless sensor network
comprising of a central gateway platform with
peripheral node platforms, the five systems
nevertheless represents the increased spatial
distribution achieved by a sensor network.
There were two configurations of platform
deployed on this site: three units were fitted with
CH
4
and CO
2
infrared gas sensors (Premier Series,
Dynament, UK) for gas concentration monitoring,
two units were fitted with pressure sensors (40PC,
Honeywell, UK) for monitoring extraction pressure.
The two configurations of platforms employed
slightly different data acquisition strategies. The gas
platforms ran a sampling routine every 6 hours, with
data from that sampling routine being transmitted
immediately afterwards. The sample routine
consisted of a two-minute sampling period, where
the sensors took a reading every three seconds as the
pump drew the gas from the landfill’s extraction
network, resulting in 40 readings each for CO
2
and
CH
4
. The two-minute routine enabled a reasonable
volume (~0.6 litres) of gas to be sampled, thus
avoiding any outliers caused by pockets of
concentrated gas. The full dataset of 80 readings was
encoded to fit within the 160 character SMS limit,
whereupon it was transmitted as a text message to
the remote base-station. As the pressure was by
nature more variable, readings were acquired every
30 minutes, stored on flash memory and transmitted
by SMS every 24 hours. Upon reception in the base-
station (based in the lab in DCU), a java program
decoded the text message, parsed the data to a
database via MySQL and uploaded averaged data to
an online portal which could be accessed from a web
browser.
The configuration of the deployment is shown in
Figure 1(ii). The deployment began in December
2011, with two pairs of gas/pressure platforms
deployed in-line with the extraction pipes leading to
each of the two flares on site (locations #1 and #2 in
Figure 1(ii)). The reasoning behind these locations
was that the readings could be validated against the
flares’ SCADA monitoring systems. A third gas
monitoring system was deployed in a newly capped
cell (location #3 in Figure 1(ii)) to monitor the gas
activity as the waste body matured.
2.2 On-site Issue Resolution
As can be expected for outdoor environmental
deployments, there were a number of issues to be
surmounted including power requirements, wireless
communications and sensor readings validity.
Furthermore, there were site-specific issues inherent
to conditions on the landfill site.
A concern with all remote devices is power
provision. For these monitoring platforms, low
power ‘sleep’ algorithms programmed into the
microcontroller circuitry enabled a 10-week
deployment duration using the 12V 5Ah lead-acid
battery. To avoid system downtime, photovoltaic
panels (BP SX-5M) with charge controllers (Solar
Technology STS01208) were fitted to the three gas
monitoring systems. As seen in Figure 2, solar
charging was found to acceptably sustain the battery
level of the system indicating an indefinite
deployment period in terms of power requirements.
Note the 13.5V upper limit in Figure 2 is not
representative of the actual battery voltage but
instead is the maxed-out voltage potential across the
solar panel during daylight hours. A truer reading of
the battery level is the night-time values - the
minima in Figure 2 (ii). Solar charging was not
necessary for the pressure monitoring systems which
had an estimated battery life of 12 months due to the
lack of the pump and power hungry IR sensors.
Figure 2: Power levels during operation (i) battery
depletion rate, (ii) battery solar recharging.
(i)
(ii)
SENSORNETS2013-2ndInternationalConferenceonSensorNetworks
224
Setting up communications was straight-forward
with acceptable GSM coverage found for the
deployment locations on-site. Intra-network
communication protocols (RF, etc) were not
implemented at this stage due to issues with line-of-
sight and the need to simplify the initial network
operation. This will be the subject of future
development when the scale of the deployments
increases. Communications was the principal
contributor to the running costs of the platforms;
monthly text message costs of €6.30 and €2.70 are
associated with each gas and pressure system,
respectively.
The validity of the sensor readings was
confirmed by occasional spot checks using the
industry standard equipment (GA2000, Geotech
Instruments, UK). Moreover, the gas monitoring
platforms were retrieved to the laboratory to test
their calibration settings after eight months
deployed. As seen in Figure 3, the CO
2
sensor was
found to have a sensitivity drift of 1.2% and zero
drift of 6.38%; the CH
4
sensor had a sensitivity drift
of 0.6% and zero drift of 8.8%. This was considered
to be an acceptably small drift considering continual
exposure to high gas levels as well as the presence
of other noxious and corrosive gases such as
hydrogen sulphide (H
2
S).
Figure 3: Comparison of sensors’ calibration data before
and after 8 months deployed (i) CO
2
, (ii) CH
4
.
A number of issues specific to this site were
encountered and rectified in the early months of the
deployment. Firstly, a high moisture content in the
landfill’s extraction pipes led to condensate forming
in the monitoring systems’ connection tubing, hence
inhibiting the sampling of gas, see Figure 4(i). This
was rectified in two ways: the monitoring systems
were elevated on their mountings such that any
condensate would flow back down into the landfill
pipes and the tubing was insulated by neoprene
sleeves to reduce the differential temperature
between the tubing and the landfill pipes, thus
lessening the extent of condensation. The second
issue related to the tubing, where an abrupt increase
in ambient temperature in April 2012 led to
shrinkage of the tubes until disconnection occurred,
see Figure 4(ii). The length of the tubing was
extended to compensate for this. The third issue
concerned the landfill pipe at location #3; given that
this was a newly capped cell, remedial construction
works were ongoing to stabilise the pipe which was
collapsing from its support ridge due to the weight
of excessive water in the pipe, resulting in the
breakage of connections on numerous occasions, see
Figure 4(iii). These issues were identified from
observing the online data, enabling the monitoring
operation to be resumed quickly.
Figure 4: Site-specific issue rectification (i) Water-
blockage, (ii) Tube shrinkage, (iii) Connection breakage
due to pipe collapse.
(i)
(ii)
(iii)
LandfillGasMonitoringNetwork-DevelopmentofWirelessSensorNetworkPlatforms
225
3 RESULTS & DISCUSSION
To date, the platforms have operated for up to 9
months, with valid readings totalling over 3,000 and
25,000 for gas concentration and pressure,
respectively. Subsets of the data from the sensors in
Locations #1 and #2 are shown in Figure 5 (some
gaps in the data were due to the aforementioned
issues described in Section 2). Distinct ‘events’ are
clearly seen in the data, coinciding in both the gas
concentration and pressure values. Such evidence of
the dynamics of landfill gas concentration has not
been available previously; now, for the first time, the
cause and effect relationship of landfill gas
behaviour can be investigated. Interpretation of this
gas field behaviour would be conducive to more
informed decisions about the impact of field-
balancing.
Figure 5: Subset of monitored data, where ‘events’ are
evident in both gas and pressure readings.
The variations in the constituent gas levels
tended to be correlated, i.e. CO
2
and CH
4
tend to rise
and fall at the same time. This indicated that the gas
activity was predominantly controlled by a singular
factor affecting the entire volume of the gas, most
likely the extraction rate towards the flare. However,
it can be seen that CH
4
at times experienced a
greater differential change possibly due to other
factors, such as varying methanogenic activity of the
waste body associated with the different stages of
waste decomposition and increased moisture content
after rainfall. Clearly, the availability of near real-
time methane concentration variation across the site
can assist in field-balancing to attain the optimum
gas composition for combustion in the flare.
Pressure readings also tended to align with gas
activity. This was an interesting finding: given their
substantially lower cost, greater proportion of
pressure sensors could be deployed for the same
investment. A relationship established between
pressure and gas would enable pressure sensors to be
deployed as low-cost indicative monitors, signalling
a possible change in gas concentration levels which
could then be verified by a smaller number of gas-
specific sensors. Judging from Figure 5, the
correlation between gas and pressure appeared
stronger for location #1 compared to Location #2;
the investigation of the relationship between gas and
pressure is subject to further careful consideration.
Figure 6: Subset of data indicating correlation between
location #1 deployed platforms and SCADA (a) gas
comparison (b) pressure/flow comparison.
Table 1: Correlation analysis of deployed systems and
SCADA measurements (values approaching ±1.0 indicate
stronger correlation).
Deployed
platforms
SCADA
CH
4
CO
2
Pressure Flow
#1
CH
4
0.72 - -0.024 -0.005
CO
2
- 0.736 0.059 0.107
Pressure - - 0.065 0.218
#2
CH
4
0.649 - 0.195 0.358
CO
2
- 0.592 0.337 0.505
Pressure - - 0.376 0.307
SENSORNETS2013-2ndInternationalConferenceonSensorNetworks
226
Correlation analysis was conducted between the
platforms’ data and the flares’ SCADA data. The
correlation for two months (64 data points) is
demonstrated in Figure 6 with correlation
coefficients presented in Table 1. Reasonably strong
correlations for gas concentrations were found for
both locations and their respective SCADA
measurements. This serves to validate the gas data
collected by the deployed platforms. Interestingly,
this correlation is not consistently positive, e.g.
negative correlations in gas levels on 2/3/12 and in
pressure on 27/3/12 as seen in Figure 6. Gas activity
measured locally at a specific point in the gas field
does not necessarily manifest at the flare. This
underscores the incapability of the flare’s SCADA
measurements to fully describe behaviour in gas
activity further along the extraction system – a task
that could be accomplished by distributed sensor
network.
The correlations in gas concentration levels were
slightly higher for location #1 compared to location
#2 (0.73 vs. 0.62 averaged); as this difference is
slight, no major conclusions are being drawn though
this is subject to further investigation. Conversely,
correlations for pressure/flow were substantially
stronger for location #2 (>0.3 vs. <0.2); the
interrelationship was less evident for location #1
possibly due to other gas inlets to that particular
flare.
A lesser correlation is seen between the CH
4
values and SCADA flowrate compared to that of
CO
2
(0 vs. 0.1 for location #1; 0.35 vs. 0.5 for
location #2). It is difficult to ascribe variations in a
system as complex as a landfill gas field to a specific
source; one possibility is differing levels of
methanogenic activity in the waste body according
to varying conditions of waste decomposition.
Figure 7: Methane readings from locations #2 and #3.
The simultaneous measurement of gas levels at
different points in the landfill extraction system is
another advantage provided by distributed sensor
platforms. Location #3 was situated on an extraction
line leading to the flare via location #2, see Figure
1(ii). A subset of the CH
4
data from both locations is
displayed in Figure 7. CH
4
generation in location #3
is seen to be less than that in Location #2 – this is to
be expected for a new-capped waste cell where
waste decomposition is not at a sufficiently
advanced stage. The elevated CH
4
levels in location
#2 indicate that the field is balanced from other cells
to provide the appropriate composition for the flare.
Interestingly, CH
4
levels in location #3 matches
those in location #2 on a few occasions; the authors
estimate that the extraction rate from location #3
was increased, hence reducing the CH
4
concentration by allowing less time for the gas to
accumulate. This finding illustrates the benefit of
immediate feedback following field-balancing,
allowing for more precise and effective gas
management.
4 CONCLUSIONS
Autonomous monitoring platforms have been
developed for the application of monitoring gas on
landfill sites. This paper describes the deployment of
a wireless sensor network on an active landfill site,
the first of its type in Ireland. The near real-time
access to gas concentration and pressure data via an
online portal enabled the landfill operators and EPA
to characterise, for the first time, the dynamics of
landfill gas activity. The authors aim to continue
working closely with landfill operators,
demonstrating that the integration of data arising
from distributed sensor networks into landfill
operational practice would assist in field-balancing
and gas management. Furthermore, the cost-benefit
of this service will be promoted where the operation
of the engine/flare can be more effectively managed.
At this approximately half-way point in the
deployment duration, the preliminary analysis
presented in this paper illustrates the valuable insight
provided by knowledge of trends in landfill gas
activity; more comprehensive analysis is ongoing
with the deployment projected to continue until
March 2013.
Further development of the platforms will
involve implementing different communications
protocols and reducing platform costs. The current
use of GSM modules for all platforms is not
financially viable when considering the extrapolated
running costs associated with a greater magnitude of
deployed systems. Reducing costs to a viable price-
point is an integral part of the commercialisation
process of this technology; in a sector that is
LandfillGasMonitoringNetwork-DevelopmentofWirelessSensorNetworkPlatforms
227
becoming increasingly financially restricted, the
ideal scenario of installing a sufficient number of
platforms to fully encapsulate the gas field activity is
currently too cost-prohibitive. Despite this, the
authors believe that a viable commercial prospect
exists with the increased temporal and spatial
resolution provided by distributed monitoring
platforms complemented with value-added analysis
and interpretation of landfill gas data.
ACKNOWLEDGEMENTS
The authors wish to acknowledge funding from the
EPA under the STRIVE programme (grant no. 2010-
ET-MS-10), and to thank the EPA and the landfill
facility management for their co-operation.
REFERENCES
European Parliament and Council of the EU, 2008.
Directive 2008/50/EC on ambient air quality and
cleaner air for Europe.
EPA, 2012. Ireland's Environment - An Assessment.
Environmental Protection Agency, Ireland.
Cohen, R., Teige, V., Weichsel, K., 2012. The Berkeley
Atmospheric CO
2
Observation Network. URL:
http://beacon.berkeley.edu/
Envirowatch, 2012. URL: http://www.envirowatch.ltd.uk
Beirne, S., Kiernan, B., Fay, C., Foley, C., Corcoran, B.,
Smeaton, A. F., Diamond, D., 2010. Autonomous
greenhouse gas measurement system for analysis of
gas migration on landfill sites. In: SAS 2010 - IEEE
Sensors Applications Symposium, Limerick, Ireland.
Fay, C., Doherty, A., Beirne, S., Collins, F., Foley, C.,
Healy, J., Kiernan, B., Lee, H., Maher, D., Orpen, D.,
Phelan, T., Qiu, Z., Zhang, K., Gurrin, C., Corcoran,
B., O’Connor, N., Smeaton, A.F., Diamond, D., 2011.
Remote real-time monitoring of subsurface landfill gas
migration, Sensors, vol. 11, pp. 6603-6628.
Collins, F., Orpen, D., Fay, C., Diamond, D., 2012.
Analysis of landfill gas migration by use of
autonomous gas monitoring platforms. Proceedings of
The 27
th
International Conference on Solid Waste
Technology and Management, Philadelphia, USA.
Collins, F., Orpen, D., Fay, C., Foley, C., Smeaton, A.F.,
Diamond, D., 2011 Web-based monitoring of year-
length deployments of autonomous gas sensing
platforms on landfill sites. Proceedings of IEEE
SENSORS 2011, Limerick, Ireland.
SENSORNETS2013-2ndInternationalConferenceonSensorNetworks
228
