Evaluating the Environmental Impacts of Pavement
Maintenance Strategies Based on Life Cycle Assessment
P Wu
1
, S M Paik
1
, Q Li
2
and X Wang
1
1
Corresponding Author, The Australasian Joint Research Centre for Building
Information Modelling, Curtin University, Kent Street, Bentley, WA6102, Australia
2
Main Roads Western Australia, Don Aitken Centre, Waterloo Cres, East Perth, WA
6004, Australia
Corresponding author and e-mail: Peng.wu@curtin.edu.au
Abstract. The concept of sustainable development calls for a change of the way about how
projects should be appropriate managed. Generally speaking, maintenance management, as an
integral part of the whole life cycle asset management, are well developed based on cost
effectiveness and performance improvement. Due to the rising recognition of environ mental
and social concerns, there is a need to include sustainability into the maintenance
manage ment of road projects. This paper will innovatively evaluate the environmental impact
of road pavement maintenance strategies in Australia through life cycle assessment. Eight
pavement maintenance strategies, from asphalt replacement to slurry seal, are investigate d.
The results show that 2.15 to 9.92 kg CO
2
e/m
2
can be generated by maintenance strategies at
the project level. Maintenance stage has relatively low impact on carbon emissions when
compared to the construction stage. However, at the network level, the annual monetary value
of the carbon emissions from maintenance strategies is estimated to be A$3.27 million, which
is significant when compared to the maintenance budget. The results offer useful insights for
road authorities to report their performance on sustainability and make relevant maintenance
decisions.
1. Introduction
Global climate change has been recognized one of the biggest threats to human development. In
order to address the challenge, environmental consideration, especially greenhouse gas emissions,
should be integrated into the decision making process of business, individuals and policy makers [1].
Many major initiatives have been developed in the building industry to address the concerns of
global climate change, e.g. the green building initiatives [2] and the carbon labelling schemes for
construction materials [3].
Road maintenance is a very large sector in Australia. The maintenance expenditure on all roads in
Australia in 2013 was A$7.8 billion [4]. The expenditure on road maintenance is expected to increase
[4]. However, the expenditure is not adequate to meet the needs of road maintenance, because
maintenance and rehabilitation activities can be very resource-intensive [4]. It is forecasted that with
the annual reduction of 15% of maintenance funds, a shortfall of A$17 billion can be expected for
road maintenance in Australia between 2010 and 2014 [4]. As such, how to effectively conduct
38
Wu, P., Paik, S., Li, Q. and Wang, X.
Evaluating the Environmental Impacts of Pavement Maintenance Strategies Based on Life Cycle Assessment.
In Proceedings of the International Workshop on Materials, Chemistry and Engineering (IWMCE 2018), pages 38-45
ISBN: 978-989-758-346-9
Copyright © 2018 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
maintenance, such as selecting maintenance strategies and allocating maintenance funds, is
imperative for Australian road authorities.
Road maintenance has been a well-studied research area, especially in using deterioration
modelling techniques to predict the pavement performance [5]. Traditional maintenance management
decisions are based on the deterioration models, as well as the life cycle cost of various maintenance
strategies. For example, four major maintenance strategies, including rehabilitation, overlay,
Microsurfacing and slurry seal are investigated in [5]. A network-level budget allocation program
was also developed to optimize two indicators, including pavement performance improvement and
budget utilization [6]. It should be noted that as sustainability becomes a rising concern, it is
important to understand other aspects of road maintenance, such as the environmental impact of road
maintenance activities and effectively integrate these aspects into the maintenance management
framework.
It is widely acknowledged that maintenance activities should be conducted before road assets
deteriorate to achieve long-term performance. Many studies have therefore been conducted on
evaluating the deterioration of road pavement. Generally, the deterioration models have been well
developed. For example, Markov model has been widely used for deterioration forecasting and
performance under the curve can be used as an indicator of the improvement potential of pavement
strategies [7].
Over the past few years, a few other important indicators to evaluate the effectiveness of
maintenance strategies have also been developed. The environmental impacts of various maintenance
activities can be quite different because the inputs of these activities, such as resources and the use of
equipment, vary significantly. Life cycle assessment, which is a method to evaluate the
environmental outputs of products or processes based on the inputs, can be adopted [8]. A few
commonly adopted system boundaries, i.e. the life cycle stages that are included in the assessment,
are cradle-to-grave, cradle-to-gate and gate-to-gate. Cradle-to-grave refers to the full life cycle stages,
starting from raw materials extraction to final disposal. Cradle-to-gate refers to the life cycle stages,
starting from raw materials extraction to the point when the product leaves the production factory. In
addition, gate-to-gate refers to the life cycle stages within an organization, such as manufacturing
company or supplier. The assessment procedure has four stages, including scope definition, life cycle
inventory analysis to list all inputs (i.e. resources) and outputs (i.e. environmental impacts), impact
assessment to convert inputs to outputs, and interpretation [9].
Eight pavement maintenance strategies are investigated in this paper, including:
ASDG - Dense graded asphalt overlay/replacement. This strategy is related to the use of
asphalt replacement. The activities include asphalt mixing, paving and compacting. The
equipment used in this strategy include asphalt mixing plant, asphalt paver and asphalt
compactor. The depth of the asphalt replacement in this strategy is 30mm.
ASIM Intersection mix asphalt overlay/replacement. Similar with ASDG, this strategy
is related to the use of asphalt replacement and the depth of the replacement is 40mm.
ASOG Open graded asphalt replacement. Similar with ASDG, this strategy is related to
the use of asphalt replacement and the depth of the replacement is 30mm.
ASRS Structural asphalt work. A full depth asphalt (150mm) will be replaced every 50
years and 5% of road placed will need patching and repair every 50 years.
GrOL Granular overlay. This strategy refers to granular overlay with spray and seal.
RipSeal RipSeal includes a 150mm cement stabilization, 50mm gravel placement and a
seal of 10mm.
Slurry Slurry/micro surfacing. This strategy is cold mix surface treatment, including a
3-20mm layer of in-situ mixture of aggregate, bitumen, adhesion agents, water and
cement.
Evaluating the Environmental Impacts of Pavement Maintenance Strategies Based on Life Cycle Assessment
39
CS Surface dressing. This strategy refers to simple repair or patching by spraying
bitumen on a road surface followed by the spreading of a layer or layers of aggregates.
This paper therefore aims to: 1) investigate the environmental impact, in terms of carbon
emissions value, of maintenance activities adopted in Australia; and 2) integrate the environmental
impact of maintenance activities into the decision making process, such as selecting opt imal
maintenance activities.
2. Research method
The life cycle assessment approach is adopted to evaluate the environmental impacts of the eight
maintenance strategies. The system boundary of the assessment is shown in Figure 1.
Figure 1. The system boundary of the life cycle assessment study.
As can be seen from Figure 1, this study includes the extraction of raw materials and on-site
maintenance activities, but excludes the transportation of raw materials from manufacturing plants to
sites, as well as end-of-life treatments. The analysis of the transportation stage requires an estimation
of the average transportation distance, on which future studies can help improve the estimation
accuracy. The end-of-life treatments involve many uncertainties related to the treatment strategies.
These two stages are therefore excluded from this study.
In addition, the functional unit of this study is one square meter of pavement. The Greenhouse
Gas Assessment Workbook for Road Projects [10] and the World Bank’s study on greenhouse gas
emissions mitigation [11] are referred to as the main sources for emission factors. The general
equation to estimate the carbon emissions is:
C = EF x Q
Where: C refers to the amount of carbon emissions; EF refers to the emission factors of various
sources, such as material usage and equipment usage; and Q refers to the quantity of the usage.
2.1. Emission factors
Four commonly adopted construction materials in these maintenance treatment strategies are asphalt,
crushed aggregate, gravel and cement. The emission factors of the four types of materials are based
on [10] and listed in Table 1.
IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering
40
Table 1. The emission factors of construction materials required in road maintenance.
Materials
Boundary
Unit
Emission factors
Bitumen
Mine to end-of-production
t CO
2
-e/t
0.630
Crushed aggregate
Mine to end-of-production
t CO
2
-e/t
0.005
Gravel (sand)
Mine to end-of-production
t CO
2
-e/t
0.003
Cement
Mine to end-of-production
t CO
2
-e/t
0.820
In addition, the emission factors of equipment usage in maintenance activities are calculated,
following the recommended factors in [10], [11] and [12]. The emission factors are listed in Table 2.
Table 2. The emission factors of equipment usage in road maintenance.
Materials
Technical specifications
Emission factors or fuel
consumption
References
ASDG
Asphalt replacement (30mm)
6.313 L/ m
3
[11]
ASIM
Asphalt replacement (40mm)
6.313 L/ m
3
[11]
ASOG
Asphalt replacement (30mm)
6.313 L/ m
3
[11]
ASRS
Full depth asphalt replacement
4.3 x 10-4 KL/ m
2
(Diesel)
[10]
GrOL
Granular + spray and seal
0.19 L/ m
3
[11]
RipSeal
150mm cement stabilization, 50mm
gravel + 10mm seal
0.31 L/ m
3
[11]
Slurry
30mm layer of in-site mixture
2.87kg CO
2
-e/ m
2
[12]
CS
Spraying bitumen followed by a layer
of aggregates
1.00kg CO
2
-e/ m
2
[12]
3. Results
Based on the information provided Main Roads Western Australia, there are 5,007 road sections
which have gone through maintenance in 2016. Table 3 presents the treatment areas and number of
road sections under each treatment strategy. As can be seen from Table 3, the most commonly
adopted treatment strategy is surface dressing with 2,980 road sections. Other commonly used
strategies include dense graded asphalt overlay/replacement (ASDG) with 1,077 road sections,
ripseal with 261 road sections and intersection mix asphalt overlay/replacement (ASIM) with 254
road sections. Table 4 shows the material consumption rate and cost of the eight maintenance
strategies.
Table 3. Background information of the 5,007 road sections under maintenance.
Treatment areas (m
2
)
No. of road sections
120-107,008
1077
78-38,717
254
198-98,719
136
82-14,672
42
84-88,386
169
108-160,066
261
270-160,621
88
22-284,520
2980
Evaluating the Environmental Impacts of Pavement Maintenance Strategies Based on Life Cycle Assessment
41
Table 4. The unit cost and material consumption of maintenance strategies.
Treatment
types
Bitumen
(L)
Crushed
aggregate (m
3
)
Gravel
(m
3
)
Cement
(kg)
Unit cost
(A$/m
2
)
ASDG
3.6
0.03
0
0
52.07
ASIM
4.8
0.04
0
0
60.00
ASOG
3.6
0.03
0
0
48.00
ASRS
12
0.1
0
0
138.00
GrOL
1.8
0.0014
0
0
70.00
RipSeal
1.92
0.02
0
0.064
47.00
Slurry
1.8
0.0014
0.05
4.95
12.00
CS
1.8
0.0014
0.15
4.95
5.99
Based on the emission factors presented in Table 1 and Table 2, the carbon emission values of one
functional unit (i.e. one square meter of pavement treatment) under the eight treatment strategies are
presented in Table 5. As can be seen from Table 5, the carbon emissions value of different treatment
strategies vary significantly. Full asphalt replacement (ASRS) has the highest value of carbon
emissions (9.92 kg CO
2
e/ m
2
) due to its high amount of material usage, contributing to 87.5% of the
overall carbon emissions generated. On the other hand, other pavement maintenance strategies, such
as surface dressing and ASDG, have relatively low carbon emissions value, due to the low amount of
material usage. The contribution of material usage to the overall carbon emission values varies from
34.2% (for slurry seal) to 99.3% (GrOL).
Table 5. Emissions of different pavement treatment strategies.
Treatment
types
Emissions
from
extraction
(kg
CO
2
e/m
2
)
Equipment
usage
(l/m3)
Emissions
from
equipment
(kg
CO
2
e/m
2
))
Total
emissions
(kg
CO
2
e/m
2
)
Environmental
cost (A$/m
2
)
Percentage
(%)
ASDG
2.60
6.313
0.55
3.15
0.08
0.16
ASIM
3.47
6.313
0.73
4.20
0.11
0.18
ASOG
2.60
6.313
0.55
3.15
0.08
0.17
ASRS
8.68
Not needed
1.24
9.92
0.26
0.19
GrOL
6.22
0.190
0.08
6.30
0.16
0.23
RipSeal
5.55
0.310
0.04
5.59
0.14
0.31
Slurry
1.49
Not needed
2.87
4.36
0.11
0.94
CS
1.15
Not needed
1.00
2.15
0.06
0.93
4. Discussions
Global climate change has been recognized as an emerging issue that should be integrated in decision
making [13]. The issue has already re-shaped the decision making process of many areas. For
example, sustainability has been integrated into the decision making system of selecting structural
materials [14], including concrete [15] and precast components [16]. As road agencies are now under
increasing pressure to report their performance against environmental sustainability criteria, it is
important that the environmental emissions of road maintenance activities are accurately and
transparently reported [17].
The results of the study indicate that different maintenance strategies have different carbon
emission values when being implemented. The results are useful when making relevant maintenance
management decisions, especially when considering the impact of potential carbon tax [3]. In 2011,
IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering
42
the Australian government introduced the carbon tax as an effective measure to achieve the emission
reduction target. Although the carbon tax was abolished in 2014, it provides a useful indicator of the
monetary value of carbon emissions in Australia. A carbon tax of A$23 per tonne of carbon dioxide
was charged by the Australian Government. An inflation of 2% is assumed to calculate the carbon
tax at the time of this study. Based on the carbon tax of A$23 and an inflation of 2%, the carbon tax
of Australia in 2017 is calculated to be A$25.90.
The monetary values of emissions from maintenance strategies are shown in Table 5. As can be
seen in Table 5, the monetary value of carbon emissions of maintenance strategies are relatively low
when compared with the unit cost of the maintenance treatment. The average percentage values vary
from 0.16% to 1%. It appears that the environmental cost of the maintenance stage is relatively low
when compared to the construction stage. A hybrid input-output analysis was conducted to
investigate the energy consumption of road construction [18]. The results show that the embodied
energy of concrete road construction is 27.2GJ/m. Based on the emission factors provided by IPCC
[19], the estimated carbon emissions from the construction stage of road projects is 251.9 kg CO
2
/m
2
(assuming that the average treatment width is 8m, based on the 5,007 road sections in this study).
5. Conclusions
This study uses the process life cycle approach to investigate the carbon emissions of eight
maintenance strategies in Australia. The results indicate that the carbon emission values from
maintenance are relatively low when compared to the construction stage. Road maintenance can lead
to emissions from 2.15 to 9.92 kg CO
2
e/m
2
, which is around 1% of the emissions from construction.
As such, it can be usefully concluded that for a single and non-repeating road maintenance project,
maintenance strategies have relatively low impact on the carbon emission values of the project at a
specific time. However, it should be noted that the life cycle performance of maintenance strategies
should be investigated as the strategy can happen multiple times in the road project’s life cycle. In
addition, the carbon emission values at the network level is not an insignificant number to be
overlooked. For the 5,002 road sections, the annual emission value is 126,295 tonne CO
2
e, which is
equivalent to A$3.27 million. As sustainability has been an emerging issue for all industries,
including the building industry [19, 20, 21] and the infrastructure and urban planning [22, 23], it is
extremely important that the environmental impact is included in the decision making process.
It should, however, be noted that the emission values calculated in this study are based on a single
and non-repeating cycle. In real life cases, a life cycle consideration of maintenance strategies should
be conducted. In addition, this study does not evaluate the strategies that can be used to mitigate
carbon emissions. Useful methods, such as the lean philosophy [24] and carbon labelled materials [17,
25] can be tested and evaluated.
Acknowledgement
This research was funded by the Australian Research Council Discovery Early Career Researcher
Award (Project No. DE170101502) by the Australian Government.
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