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This paper outlines an experiment to investigate the response to solar irradiation of square slabs of asphalt concrete
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1
Laboratory Investigation into the
Collection Efficiency of Various Pipe
Materials and Depths in Solar Asphalt
Collectors
Lecturer: Dr Michael McLoughlin
Students: Luke Molloy
Jason Corbett
Frank Kenna
Module: Highway Design
1 Abstract
This paper outlines an experiment to investigate the response to solar irradiation
of square slabs of asphalt concrete. The energy source was provided for by
halogen bulbs to simulate solar irradiation in the laboratory. The effects of the
light energy on the asphalt slabs was monitored by the insertion of 8mm copper
tubing and 16mm plastic tubing at 3 different depths from the surface within the
asphalt layer in which water was circulated at a constant rate of 1.5 l/min. The
thermal energy transmitted to the slabs was collected by the circulating water.
The temperature differential was monitored by placing thermocouples on the
inlet and outlet locations. Thermocouples were also inserted into the asphalt
slab at 20mm incremental depths from, and including, the surface to monitor the
response of the asphalt to the energy source and the circulating water. The
results show that the asphalt pavement can be cooled down by the solar
collector and thus reducing the heat island effect. This was most prominent in
the 8mm copper pipe at a depth of 20mm from the surface, which also showed
an energy absorption rate of 537W/m2 while being exposed to approximately
900W/m2 of light energy.
Bachelor of Engineering
(Honours)
Civil Engineering
2
2 Introduction
Physical issues associated with asphalt pavements subjected to solar radiation,
which can result in high surface temperatures, include structural damage due to
hardening as a result of thermal cycles and the environmental phenomena
known as the heat island effect (Bobes-Jesus et al. 2013). Rapid changes in
temperature induce thermal stresses within the pavement causing changes to
the visco-elastic properties and gradual deterioration of the pavement (Merbouh
2012) while it has been well documented that overheating asphalt bitumen can
lead to oxidation and stiffening (Dessouky et al. 2011). The rate of oxidation is
dependent on temperature, thickness of the bitumen layer and time of exposure.
The results of oxidation produce more complex molecules in the bitumen which
make the pavement harder and less flexible and are the main cause of ageing
(Read et al. 2003).
Asphalt solar collectors (ASC) were firstly developed for an under-road heating
system, to prevent pavement icing and to melt snow on bridge surfaces in Japan.
The first system of automatic collection and storage of energy and its use to melt
snow, called the Gaia System, is currently still in service (Shaopeng et al. 2011).
There are many benefits from taking advantage of this energy source which has
the potential to be in abundance especially in urban areas where parking lots and
pavements are a considerable percentage of total urban area. Nicolas and
Eleftherios (2010) have, in a Swedish context and climate conditions,
investigated the application of an ASC for heat capture and a ground source heat
pump with borehole storage. The intention is to use that heat for domestic hot
water and heating demands in Fågelsten, a newly planned residential building
area. The performance is being compared to the common use case of district
heating and standard ground source heat pump systems in Sweden.
Sustainable energy sources can be exploited from the installation of ASC as in
2006 when the Highways Agency in UK had commissioned a scoping study for the
Transport Research Laboratory (TRL) to explore available methods and assess the
possibility that renewable energy generation could be exploited within the
3
highway network. The findings of this study resulted in trials on an access road
near Toddington UK, where the use of an inter-seasonal heat transfer system
incorporating ASC and shallow insulated heat stores in the ground were
conducted. Two solar heat collecting arrays each 5m by 30m installed at a depth
of 120mm were used to collect the heat and the identical arrays, but at a depth
of 875mm, were used for the heat store. The results of this experiment showed
that 6.5MWh of heat energy were exchanged from the ASC to the ground
storage array during the good summer of 2006. This translates to approximately
43kWh/m2. Air temperatures peaked at 34oC and temperatures of 50oC and 38oC
were recorded at the road surface and in the underground storage array
respectively (TRL 2007). This type of experiment includes environmental factors
such as variations in sunlight intensity over time and ambient air temperatures
which are affected by wind direction and velocity. It has also been argued by
Gao et al. (2010) that the average heat collecting capacity computed was
approximately 150 to 250 W/m2 in the sunny days where the selective test time
was from 9:30 AM to 4:30 PM in August 2008, in Changchun in the northeast of
China.
Laboratory experiments will not provide as accurate results if environmental
conditions are not replicated. Laboratory investigations can be carried out to
investigate the thermal response of asphalt pavements to solar radiation.
Shaopeng et al. (2011) used 20mm diameter copper piping in 300mm square
asphalt slabs at a depth of 75mm from the surface where a laboratory irritation
simulation test was performed to heat up the asphalt slabs. The effects of flow
rate, time of start of collection and the initial temperature distribution of the
slabs on the process of heat collection were all factors in the solar collector’s
performance. The results show that the asphalt pavement can be cooled down
by the solar collector and thus is good for reducing the effect of heat-island in a
city, but the temperature gradients between the slabs’ surface and the pipe were
noticeable.
There are many factors influencing the effectiveness of thermal transfer from
slab to pipe and in turn to the circulating fluid within the pipe network. Test
4
results obtained by Mallick et al. (2008) from small-scale samples showed that
the use of aggregates with high conductivity can improve the efficiency of heat
capture and using quartzite as an aggregate significantly increases heat capacity.
Adding filler material to the asphalt mix in order to improve the efficiency of the
collector has proved effective and is a key issues relating to performance
optimisation (Wu et al. 2009).
Pipe spacing and fluid flow rates also affect the solar collection efficiency.
Shaopeng et al. (2011) show that circulating water temperature in the pipe
network varies as a function of the applied flow rate, while there proved to be
only minimal variation in surface temperatures (1.87oC), the maximum extracted
heat energy increases as flow rate increases with a maximum value of 400W/m2
being extracted in that system.
The increase of flow rate results in increased fluid velocity and thus improves the
heat transfer coefficient of fluid in the pipes (Shaopeng et al. 2011).
Furthermore, the pipe configuration, especially the effective total length in a
certain area is also important for the amount of heat that can be extracted which
is determined by pipe configuration in the slab (Wu et al. 2009).
The process of optimising the effectiveness of solar collection may lead to
secondary effects such as pavement durability. It is found that locating the heat
exchanger tubes at shallow depths can extract more energy but results in higher
stresses in the asphalt, and thus reduced durability of the pavement (Bijsterveld
et al. 2001). Asphalt pavement durability is considerably increased with the
addition of reinforcement in the pavement layer. Reinforcement refers to the
ability of an interlayer to better distribute the applied load over a larger area and
to compensate for the lack of tensile strength within structural materials. Elseifi
and Al-Qadi (2005) showed that placing steel reinforcement at the bottom of the
hot mix asphalt layers, the range of improvement for the pavement structure
was between 15 and 257% in the transverse direction, and between 12 and 261%
in the longitudinal direction compared to the pavement without any
reinforcement.
5
The purpose of this research is to investigate the performance of two different
types of materials to be used for the pipes. The first pipe is high-density
polyethylene (HDPE), which has a diameter of 16mm and a thermal conductivity
of 0.45W/m.K. The second pipe is copper with a diameter of 8mm and a thermal
conductivity of 401W/m.K. The performance of each pipe will be compared in
terms of extracted heat energy as was carried out by Shaopeng et al. (2011). The
pipes will be placed at three different depths and the performance of each pipe
at the various depths will be investigated in terms of their ability to transfer the
heat from the asphalt to the fluid flowing through the pipes.
The use of steel reinforcing mesh could also provide a means of conducting heat
from areas surrounding the collector pipes in the asphalt layers, provided there
is contact between the reinforcing mesh and the pipes themselves. To
investigate this possibility, steel mesh will be placed into two of the test samples
and the results obtained will be compared with each other and with the samples
without the mesh.
3 Experimental
3.1 Test configuration
The experimental asphalt solar collection systems (ASC) were constructed with
imbedded tubing arranged in a serpentine configuration within 0.5 x 0.5 x 0.11m
asphalt slabs as can be seen in Figure 1, Figure 2 and Figure 5. Two types of
imbedded tubing were incorporated in the experimental system, namely an 8mm
diameter copper tubing configuration at 58mm centres and a 16mm diameter
plastic tubing configuration at 175mm centres. Three depths within the asphalt
slabs were selected for the placement of the tubing configurations at 20, 40 and
60mm below the slab surface, with two ASCs incorporating zinc coated mild steel
mesh sheets. The asphalt slab mix consisted of 200pen bitumen; 6mm singled
sized limestone aggregate and 6mm limestone dust aggregate with an average
density of the asphalt slab being 2692kg/m3. The main test apparatus
incorporated the ASC, inflow manifold with flow meters, an acquisition unit
6
connected to thermocouples and 400W tungsten lamp rig. Water is fed to the
system from the mains supply, whereby the flow rate to the ASC was controlled
by flow meters on the inflow manifold with the water being discharged directly
from the system instead of recirculation.
Figure 1- ASC with plastic embedded pipes
Figure 2 – ASC with copper embedded tubing
Figure 3 – Manifold and pipe connections
Figure 4 – ASC being operated with halogen light rig in place
7
Figure 5 – ASC layout
3.2 Test method
The solar collector surface was subjected to radiation heat from a rig of halogen
lamps, as seen in Figure 4, in an arrangement similar to Wu et al. (2009) which
was first proposed by Mrawira and Luca (2006) and gives an approximate
exposure of 900W/m2, determined by the relative positioning of the lamps. The
total test period for each ASC continued for 4 hours and comprised of 3 phases, a
1 hour phase with the slabs exposed to the radiated heat source without water
flow, a 2 hour phase with radiated heat and a constant water flow rate of 1.5 l/s
and finally a 1 hour phase with the flow rate maintained without the presence of
the radiated heat source. Temperature readings were taken at three minute
intervals by thermocouples at the outlet and inlet of the ASC and at 20mm
increments from the surface of the asphalt at a location adjacent the imbedded
tubing of the systems.
8
4 Results and discussion
4.1 Temperature profile
Figure 6 shows the temperature differential at different depths within the
asphalt for the various depths of the 16mm diameter plastic pipe.
Figure 6 – Temperature distribution at 180 min
The tests were performed in a laboratory environment where the effects of wind
velocity and heat transfer downward were not considered variables. Ambient air
temperature was recorded at a constant 20oC. The pipe placed at 20mm below
the surface showed the lowest surface reading as expected peaking at a
temperature of approximately 51oC, in comparison to the pipe at its lowest
position of 60mm depth from the surface in which the surface temperature
peaked at 550C. The flow rate was maintained at a steady 1.5l/min throughout
the duration of the test.
The rate of decent in temperature from the surface to the respective pipe
locations can be seen from the graph. This rate is reduced in the locations below
each pipe giving the indication that less heat energy is passing the pipe than is
0
20
40
60
80
100
120
30 35 40 45 50 55 60
The
rmo
cou
ple
De
pth
(m
m)
Temp OC
Temperature distribution
60mm cover with mesh
60mm cover witout mesh
40mm cover without mesh
20mm cover without mesh
16 mm Diameter Plastic Pipe
9
being absorbed by the pipe in each case, thus being absorbed by the flowing
water in the pipe.
The plastic 16mm diameter pipe at a depth of 20mm proved to be the most
effective location for the test conditions for the reduction in asphalt temperature
at the surface of the slab. The pipe placed at 40mm did reduce the core
temperature of the asphalt at that location however the overall energy gain was
not produced as can be seen in Table 3.
Figure 7 shows the temperature differential at different depths within the
asphalt for the various depths of the 8mm diameter copper pipe.
Figure 7 – Temperature distribution at 180 min for ASC with embedded copper pipes
The test was carried out under the same conditions as the plastic piping.
Significant variations were found especially in the 20mm depth. The maximum
temperature recorded was 36oC on the surface at the 20mm depth after 180
minutes of irradiation. Both 60mm depth pipes showed similar surface
temperatures of just over 50oC. The available energy absorbed into the slab was
0
20
40
60
80
100
120
10 20 30 40 50 60
The
rmo
cou
ple
De
pth
(m
m)
Temp oC
Temperature distribution
60mm cover with mesh
60mm cover without mesh
40mm cover without mesh
20mm cover without mesh
8 mm Copper Pipe
10
most efficiently captivated by the copper piping in general, with the 20mm pipe
depth being the most efficient as outlined in Table 2.
4.2 Energy transfer efficiency
The temperature difference between the incoming and outgoing water, ΔT, is a
key element when establishing the efficiency of the system for extracting heat
energy. The temperature difference between inlet and outlet from the heat
carrier directly reflects the absorbing heat ability (Gao et al. 2010), while
Shaopeng et al. (2011) stated that ΔT acts as an indicator of the efficiency of the
system for extracting heat energy from pavements.
To investigate the effectiveness of the asphalt solar system as an energy
collector, the change in temperature between the inlet and outlet for each
sample was used. An average value of ΔT was calculated by taking the ΔT values
for each sample box between the times of 72 and 180 minutes of irradiation.
These times were chosen because a steady state temperature was observed in
between these times at depths equal to the location of the pipes for each test
sample as observed in Figure 8 and Figure 9.
11
Figure 8 – Steady state water temperature (copper pipe)
Figure 9 – Steady state water temperature (plastic pipe)
0
5
10
15
20
25
30
35
40
0 50 100 150 200 250 300
Tem
pe
ratu
re a
t d
ep
th o
f p
ipe
(D
egr
ee
s C
elc
ius)
Time (Minutes)
Location of Steady State Temperature for Copper Pipes
Copper with mesh at 60mm depth
Copper at 60mm depth
Copper at 20mm depth
Copper at 40mm depth
72 180
0
10
20
30
40
50
60
0 50 100 150 200 250 300
Tem
pe
ratu
re a
t d
ep
th o
f p
ipe
(d
egr
ee
s C
elc
ius)
Time (Minutes)
Location of Steady State Temperature for Plastic Pipes
Plastic at 40mm depth
Plastic at 20mm depth
Plastic with mesh at 60mm depth
Plastic at 60mm depth
72 180
12
This method of observing the steady state temperature differential between the
inlet water temperature and the outlet water temperature is used, as an average
maximum achievable temperature differential (Shaopeng et al. 2011).
The ΔT varies for each of the samples tested which was expected as the depths
of the embedded pipes varied as did the material of the pipe itself. The results of
the ΔT are outlined in Table 1. The average ΔT for the various depths was greater
in the samples that used the copper pipes compared to the plastic pipes by
approximately 50%. For each material the ΔT was greatest where the pipe was
embedded at 20mm from the top surface of the slab, with ΔT for the copper
being 1.28 oC and 0.87oC for the plastic. The addition of the mesh in the slab with
copper had an insignificant effect on the ΔT but when used with the plastic pipe
it had a significant effect, in this case the addition to the mesh resulted in a
reduction of 57% of the ΔT.
Figure 10 – Temperature variations at 60mm depths over the 4 hour test period
The temperature variation profile at the 60mm depth, which includes the steel
mesh, increase and dissipate at approximately the same rate for both the copper
and plastic tubing configurations when compared to the depths without mesh.
However, the temperature is as much as 4oC lower between equivalent systems.
This would suggest that the mesh is inhibiting the potential ∆T of the ASC at this
0
10
20
30
40
50
0 30 60 90 120 150 180 210 240
Tem
pe
rtu
re (
0C
)
Time (mins)
Temperature variations at 60mm depth
Plastic tubing 60mm cover with steel mesh Plastic tubing 60mm cover Copper tubing 60mm cover with steel mesh Copper tubing 60mm cover
13
depth by conducting heat away from the imbedded tubing. This is also reflected
by the maximum ∆T being recorded in the systems without mesh at this depth.
It can be seen from Table 1 that the close configuration spacing of the copper
system, coupled with the materials higher conductivity returns the temperature
profile to a steady state much more efficiently than the plastic system.
Table 1- Temperature Differential
Temperature Differential between Inlet and Outlet During Steady State Temperature
Plastic Copper
Pipe 60mm 60mm Mesh
40mm 20mm 60mm 60m Mesh
40mm 20mm
Δt (Max)
oC 0.68 0.29 0.34 0.87 1.01 1.02 0.94 1.28
The quantity of heat energy which can be extracted by the circulating water was
found using the following expression by Shaopeng et al. (2011) as:
qout = Cp x V x ΔT/Aslab (1)
Where:
qout = Heat energy absorbed, W/m2
Cp = Specific heat capacity of the water, kJ/kg.K
V = Flow rate, l/s
ΔT = Maximum change in temperature, oC or Kelvin
Aslab = Experimental slab area, m2
The following data was used for the energy value calculation:
Cp, specific heat capacity of water = 4.2 kJ/kg.K
V, water low rate, 25 l/second
A, area of surface = 0.25 m2
qin, irradiation rate = 900 W/m2
14
The maximum value of energy extraction of 536.9 W/m2 is representative of
idealised laboratory conditions of the copper pipe at 20mm depth from the
irradiated surface exposed to 900 W/m2. This is higher than the average heat
collecting capacity of between 150 and 250 W/m2 outlined by Shaopeng et al.
(2011).
The above energy calculations were based on the solar collectors reaching a
steady state condition which were experienced between 72 and 180 minutes of
irradiation.
Using Equation 1 the following maximum energy extraction was obtained:
Table 2 – Energy values from copper pipe
Copper Pipe cover qout (W/m2) Efficiency (%)
60mm 423.0 47.0
60mm with Mesh 428.3 47.6
40mm 394.5 43.8
20mm 536.9 59.7
Table 3 – Energy values from plastic pipe
Plastic pipe cover qout (W/m2) Efficiency (%)
60mm 284.7 31.6
60mm with Mesh 120.6 13.4
40mm 141.6 15.7
20mm 364.2 40.5
The efficiency is calculated based on:
[qout/qin]*100 (2)
The efficiency reported here is based on a laboratory condition of irradiation at a
constant value approximating 900W/m2 which is relative to typical summer day
15
in Ireland (MetÉireann 2013). Laboratory conditions do incorporate other typical
climatic conditions such as wind direction, speed and ambient temperature.
The results indicate that the copper pipes perform better in terms of heat energy
collection efficiency than the plastic pipes. As can be seen in Table 2 and Table 3
the maximum percentage energy efficiency achieved from the ASC with the
copper pipes reached 59.7% while the corresponding value in the ASC with the
plastic pipes reached only 40.5%. This suggests that the copper pipes give 150%
of the energy efficiency of the plastic pipes. Given the thermal properties of the
two materials this result is expected. For both materials, the energy efficiency
was greatest for the pipes at 20mm depth. This suggests that the pipes of either
material will potentially be more efficient if utilised in a system when they are
close to the surface of the pavement but placing pipes close to the surface may
have negative impacts such as loss of strength of the pavement and problems
associated with the physical embedding of the pipes in the pavement without
causing damage to the structure of the pipe itself.
With both the plastic and copper pipe the efficiency at a depth of 60mm was
greater than at a depth of 40mm. These results were unexpected, considering
that the pipes at 60mm were further away from the surface and therefore
further away from the heat source. These results may be explained by the fact
that 50mm of insulation was place at the bottom of the boxes. As the heat
reached the bottom of the box it may have been deflected upwards and this may
have led to an increased temperature at the lower depth. Another explanation is
the larger volume of material above the pipe at a depth of 60 mm could have
had more potential heat energy stored above it due to the larger mass of
material under which it was embedded, which resulted in a more efficient
transfer of heat through the system.
The results from Table 2 indicate that the addition of the mesh in the ASC that
use the copper pipes has little effect on the energy efficiency of the system.
Without the addition of the mesh, at a depth of 60mm, an efficiency of 47.0%
was achieved in the ASC. When this value is compared to 47.6% which was
achieved for the ASC with the mesh at the same depth the difference between
16
both values is relatively insignificant although a slightly better performance was
achieved as a result of adding the mesh. The effect of the adding the mesh was
far greater in the ASC that used plastic pipes. The results from Table 2 show that
the use of the mesh reduced the energy efficiency of the ASC from 31.6% to
13.4%. These results represent a disadvantage associated with the addition of
mesh as the omission of the mesh has resulted in the ASC without the mesh
having an efficiency of 235% of the ASC with the mesh. As can been seen in
Figure 8, Figure 9 and Figure 10 no apparent advantage can be observed by the
addition of the mesh after the heat source is removed. Initially it was considered
that the addition of the mesh would lead to the ASC to retain the heat energy in
the system for longer but no significant results were achieved which suggest that
this is the case.
5 Conclusion
Asphalt solar collection systems were prepared and tested using two different
pipe materials at various depths, with two having zinc coated, mild steel mesh
placed under the pipes. Each collection system was exposed to 900W/m2 of heat
energy from a rig of halogen lamps and the difference between the incoming and
outgoing temperature of the water along with the temperature at various depths
throughout the asphalt slab was recorded. The results show that the closer to
the surface the pipes are embedded in the asphalt slab, the greater the
reduction in the surface temperature of the slab. A surface temperature
difference of 4oC was recorded between the asphalt slab with the plastic pipes
embedded at 20mm and the asphalt slab with the pipes embedded at 60mm.
The results of the ASC with the copper pipes show that the temperature
difference between at the surface of the slab is 16oC cooler when the pipe is
20mm from surface as opposed to 60mm from the surface.
The results indicate that embedding pipes that are part of an ASC system can be
effective in reducing the surface temperature of the asphalt. The results also
indicate that copper pipes will perform better at reducing the surface
17
temperature of the asphalt than plastic pipes and the closer to the surface that
the pipes are embedded, the greater the reduction of temperature of the surface
of the asphalt.
The results indicate that the copper pipes are more effectual in terms of energy
efficiency than the plastic pipes. The energy achieved from the from each asphalt
slabs which had the copper pipes embedded in them performed significantly
higher than those with the plastic pipes with a maximum energy collection
efficiency of 59.7% and 40.5% being achieved respectively. The least efficient
results for both the copper and plastic pipes were achieved at a depth of 40mm,
however, the use of insulation under the asphalt slab may have given erroneous
results of the pipes at a depth of 60mm. The inclusion of the zinc coated, mild
steel mesh has resulted in no significant increase in the energy collection
efficiency of the asphalt solar collection systems containing the copper pipes, but
in fact has resulted in a decrease of 18.5% in the system containing plastic pipes.
The method of extracting heat energy from asphalt slabs prepared in the lab has
been investigated in this present work. The results suggest the most efficient
configuration for such system involves the integration of copper pipes close to
the surface of the asphalt. The addition of the zinc coated, mild steel mesh may
not increase the efficiency of system in terms of heat energy collection but its
inclusion may have benefits in terms of the structural integrity of the asphalt.
18
6 References used
Bijsterveld, W.T.V., Houben, L.J.M., Scarpas, A. & Molenaar, A.A.A. (2001) Using Pavement as Solar Collector: Effect on Pvement Temperature and Structural Response. Journal of the Transportation Research Board, 1778 pp. 140-148.
Bobes-Jesus, V., Pascual-Muñoz, P., Castro-Fresno, D. & Rodriguez-Hernandez, J. (2013) Asphalt solar collectors: A literature review. Applied Energy, 102 (0) pp. 962-970.
Dessouky, S., Reyes, C., Ilias, M., Contreras, D. & Papagiannakis, A.T. (2011) Effect of pre-heating duration and temperature conditioning on the rheological properties of bitumen. Construction and Building Materials, 25 (6) pp. 2785-2792.
Elseifi, M.A. & Al-Qadi, I.L. (2005) Effectiveness of Steel Reinforcing Nettings in Combating Fatigue Cracking in New Flexible Pavement Systems. Journal of Transportation Engineering, 131 (1) pp. 37-45.
Gao, Q., Huang, Y., Li, M., Liu, Y. & Yan, Y.Y. (2010) Experimental study of slab solar collection on the hydronic system of road. Solar Energy, 84 (12) pp. 2096-2102.
Mallick, R.B., Chen, B.L., Bhowmick, S. & Hulen, M.S. (2008) Capturing Solar Energy from Asphalt Pavements. International Symposium on Asphalt Pavements, pp. 161-172.
Metéireann (2013, 2013-3-10) Met Éireann - The Irish Weather Service. [Online]. Available at: http://www.met.ie/climate-ireland/sunshine.asp [Accessed: 10/03/2013].
Merbouh, M.H. (2012) Effect of Thermal Cycling on the Creep-Recovery Behaviour of Road Bitumen. Energy Procedia, 18 (0) pp. 1106-1114.
Mrawira, D.M. & Luca, J. (2006) Effect of aggregate type, gradation, and compaction level on thermal properties of hot-mix asphalts. Canadian Journal of Civil Engineering, 33 (11) pp. 1410-1417.
Nicolas, S. & Eleftherios, Z. (2010) Asphalt Solar Collector and Borehole Storage. Thesis (Masters). CHALMERS UNIVERSITY OF TECHNOLOGY, Sweeden.
Read, J., Whiteoak, D. & Shell, B. (2003) The Shell Bitumen Handbook. Thomas Telford
Shaopeng, W., Mingyu, C. & Jizhe, Z. (2011) Laboratory investigation into thermal response of asphalt pavements as solar collector by application of small-scale slabs. Applied Thermal Engineering, 31 (10) pp. 1582-1587.
TRL (2007) Performance of an Interseasonal Heat Transfer Facility for Collection, Storage and Re-use of Solar Heat from the Road Surface. (PPR 3023/302_81): Transprt Research Laboratory.
Wu, S.P., Chen, M.Y., Wang, H. & Zhang, Y. (2009) Laboratory Study on Solar Collector of Thermal Conductive Asphalt Concrete. International Journal of Pavement Research and Technology, 2 (4) pp. 130-136.