u ¼VVVsolid ð47Þx ¼VGVsolid total ¼

u ¼
VV
Vsolid ð47Þ
x ¼
VG
Vsolid total ¼
VG
VG þ VE þ VC ¼
VG
VG þ VP ð48Þ
From Eq. (44), it can be written as:
Di þ 2ei
Di ¼
1 þ Qx
1 þ Q1=3
ð49Þ
k ¼
1 þ Qx
1 þ Q1=3
ð50Þ
The value k varies among authors. According to [13–16], the coefficient
‘‘k’’ varies from 1.064 to 1.233. See for example in Table 2.
The determination of k plays an important role on the amount
of cement in concrete while the cement is the most expensive
concrete constituent. In addition, the pervious concrete is often
used for low-load applications which do not need much resistance.
So it is better to reduce as much as possible the amount of cement
in the mix. Also, from the optimization study of the mix of pervious
concrete achieved in the laboratory, it is noticed that a low value of
k near to 1.116 still carries a good pervious concrete. This value
simile to the value founded by Deo and Neithalath [16]. Thus, a
preliminary study is recommended for k = 1.116.
and the ratio
ei
Di ¼ 0:058 ð51Þ
2.3. Aggregate and cementitious paste amount correction
In the calculation above, the void volume VV is equal to the volume
of empty space among the aggregates. Therefore, the porosity
of the cement paste is not included in the calculation of void
volume.
For the total porosity accessible to water assessed by
hydrostatic weighing (according to the AFPC-AFREM procedure
[17]), this total porosity, denoted as Pt, is the inter-granular
porosity + porosity of aggregate + porosity of the cement
paste + porosity of the transition zone. To simplify the calculation,
it can be assumed that the total porosity accessible to water is the sum
of the inter-granular porosity and the porosity of the cement paste.
For one cement paste, depending on the w/c ratio, the porosity
of cement paste can be calculated according to some following
equations [18]:
Total porosity of the cement paste:
Pp ¼ Po  0:53  a  ð1  PoÞ ð52Þ
Initial porosity of the cement paste Po:
Po ¼
Vw
Vw þ Vc ¼
w=qw
w=qw þ c=qc ¼
w=c
w=c þ 0:32 ð53Þ
Degree of hydration of cement a:
According to Powers and Brownyard [18], the theoretical
predictable hydration is determined on data of the consumption
of water in the hydration reactions:
If w=c < 0:42 : að1Þ ¼
w=c
0:42 ð54Þ
If w=c > 0:42 : að1Þ ¼ 1 ð55Þ
According to Mills [19], the degree of hydration can be
calculated from a phenomenological model also based on the w/c
ratio:
að1Þ ¼
1:031  w=c
0:194 þ w=c ð56Þ
According to Waller, one phenomenological model based on
experimental results and a compilation of measurements found
in the literature has been developed [20]:
að1Þ ¼ 1  exp 3:4
w
 c ð57Þ
The void volume of the concrete according to the total porosity
of the cement paste:
VV ¼ Pt  Vp  Pp ð58Þ
With Eqs. (43) and (58), the void volume can be written as
follow:
VV ¼ Pt  Vp  Pp ¼ Pt  ð1  VVÞ  b  Pp ð59Þ
Then, the void volume can be deduced as:
VV ¼
b  Pp  Pt
b  Pp  1 ð60Þ
and the total porosity is calculated as:
Pt ¼ b  Pp  ð1  VVÞ þ VV ð61Þ
2.4. Determination of w/c ratio by using the binder drainage test
The correct amount of water will maximize the strength without
compromising the permeability characteristics of the pervious
concrete. Generally a w/c ratio ranging from 0.27 to 0.40 is used for
pervious concrete mix design [2,3]. The relation between strength
and w/c ratio is not clear for pervious concrete, because unlike conventional
concrete, the total paste content is less than the voids
content between the aggregates. Therefore, making the paste
stronger may not always lead to increased overall strength. Water
content should be tightly controlled. The correct water content has
been described as giving the mixture a sheen, without being so
soupy that it flows off the aggregate. From this concept, the binder
drainage test is proposed to determine an appropriate w/c ratio
that will yield a high permeability of pervious concrete,
maintaining a good gravel coating to ensure mechanical strength.
To determine the state of drainage of the cement paste with w/c,
the ratio between the aggregate volume and the cement paste
volume (VG/VP) is kept constant. For this, it is important to choose
initially mG/C and w/c in order to have sufficient volume of the
cement paste to coat the grains aggregate. Generally, the pervious
concrete has mG/CP4, therefore, the ratio mG/C = 4 is taken. Initially,
the ratio w/c = 0.32 is chosen. This is a typical value of w/c
ratio of pervious concrete. Indeed, the choice of w/c initial is just
to calculate the ratio VG/VP and keep it constant with another w/c
ratio.
Starting from the choice w/c = 0.32 and mG/C = 4, it can be
deduced VG/VP = 2.29 by subtracting the absolute density of cement
and aggregate. Table 3 shows the amounts of different materials
for different w/c ratio for the binder drainage test. The mass of
aggregate in saturated surface dry state for the test is 2500 g.
Protocol of binder drainage test:
Test protocol binder drainage is performed according the
following steps, in case w/c = 0.36 (written in bold) from Table 3
for example (Figs. 7 and 8):