Power (Eq. (54)) seems inappropria

Power (Eq. (54)) seems inappropriate because it often gives a
higher degree of hydration compared to the two remaining equations
(Eqs. (56) and (57)) (Fig. 10). By cons, in literature the formula
of Waller (Eq. (57)) is often used to estimate the degree of hydration.
This is why this equation is used to calculate the degree of
hydration of cement. With the w/c = 0.37, the degree of hydration
a = 0.71.
From the values of w/c and the degree of hydration obtained,
the porosity of the cement paste Pp is calculated according to
Eqs. (52) and (53), Pp = 0.36.
In addition, by the binder drainage test, the amount of cement
paste that coats the grains of coarse aggregate and does not flow
under the effect of vibration is shown in Fig. 11 as a function of
w/c ratio. It is noticed that this amount varies linearly with the
w/c ratio. A high regression determination coefficient shows a good
correlation between the cement paste amount and the w/c ratio.
Although the volume of cement paste obtained in Fig. 11 is quite
low compared to the value recommended which range from 15%
to 25% [2,3], it also gives us an idea of the difference in the amount
of paste by changing the w/c ratio. The detailed composition of the
mixes of the pervious concrete is summarized in Table 6. The theoretical
designed unit weight of pervious concrete composed is
2080 kg m3.
4.2. Preparation of sample and testing methods
The compaction method for manufacturing pervious concrete is
one of the most influential factors in the sample preparation. The
time necessary to mix pervious concrete is 7 min to get a homogeneous
mixture. The cubic samples 15  15  15 cm were pressed
under a pressure of 7.5 kPa. The workability of mixture was measured
with the concrete slump test.
Immediately after casting, all mixtures were kept in their molds
during the first 24 h in a chamber at 20 ± 2 C and 95% relative
humidity. After demolding specimens were moist-cured in a water
tank at a constant temperature of 20 C for 28 days before mechanical,
physical and hydraulic test.
– Compressive test: the compressive strength is measured on cubic
15  15  15 cm specimens in accordance with the European
Standard EN 12390 [26]. These tests were performed using a
constant rate loading of 0.06 MP s1.
– Splitting test: The tensile strength is deducted after the splitting
test on cubic specimens 15  15  15 cm according to NF EN
1338 [27].
– Porosity and density: the total porosity and the dry bulk density
of the concrete are determined by the method of hydrostatic
weighing. The measurements are performed according to the
recommendations of the AFGC [17]. The porosity is also determined
by an image processing according to the protocol defined
by Sebaibi et al. [28]. The continuous porosity and the unit
weight in air are performed according to the procedure of Mata
[29].
– Water permeability test: the water permeability of a material is
defined as its ability to pass through the water under the effect
of a pressure gradient. It is expressed by Darcy’s relationship is
valid in laminar flow regime [30]. This test determines the permeability
coefficient as a constant load and variable load. The
constant head permeability is measured with levels of
255 mm and the falling head permeability is evaluated with
an initial water level h1 = 255 mm and final height
h2 = 75 mm. The device for measuring permeability of pervious
concrete is shown in Fig. 12.
– Freeze–thaw resistance: profile cycle freeze/thaw to determine
the sustainability freeze/thaw is defined in standard NF EN
1338 [27]. However, a sample of pervious concrete is considered
at the off state due to freeze/thaw when the mass loss is
about 15% [11].
– Abrasion and skip strength: the abrasion and skip strength
(Pendulum skip Resistance Tester) are performed according to
standard NF EN 1338 [27]. The abrasion resistance is measured
by the wearing machine and the resistance to skip was
performed using the pendulum friction.
More details of these experimental tests can be found in [4,31].
4.3. Test results and discussions
4.3.1. Fresh concrete properties
Fresh pervious concrete is characterized by having a very low
slump, even zero slumps (Fig. 13). Fresh concretes are very stiff
since they contain less water and cement paste. This characteristic
conforms to common experience with this type of concrete.
0.25 0.30 0.35 0.40 0.45 0.50 0.55 0.60
0.5
0.6
0.7
0.8
0.9
1.0
Degree of hydration of cement
w/c ratio
Power [18]
Mills [19]
Waller [20]
Fig. 10. Theoretical calculation of the degree of hydration of cement.
0,28 0,30 0,32 0,34 0,36 0,38 0,40 0,42
0
5
10
15
20
25
w/c ratio
Paste content, percent by volume (%)
0,10
0,12
0,14
0,16
0,18
0,20
0,22
Thickness of excess paste (mm)
Fig. 11. Variation of paste content (black line) and thickness of excess paste (red
line) in function of w/c. (For interpretation of the references to color in this figure
legend, the reader is referred to the web version of this article.)
Table 6
Mix of pervious concrete obtained.
Vv Cement (kg m3) Water (kg m3) Gravel (kg m3) Sand (kg m3) W/C G/C S/G VP
0.17 335 124 1515 106 0.37 4.52 0.07 0.231