J. Build. Mater. Struct. (2021) 8: 128-138 Review Article  
DOI : 10.34118/jbms.v8i2.1080  

 

ISSN  2353-0057, EISSN : 2600-6936 

ANN modelling approach for predicting SCC properties - Research 
considering Algerian experience.  Part III. Effect of mineral admixtures 

Sahraoui M *, Bouziani T 

 
Structures Rehabilitation and Materials Laboratory (SREML), University Amar Telidji, Laghouat, Algeria. 
* Corresponding Author: med.sahraoui@lagh-univ.dz 

Received: 23-01-2021 
 

 Accepted: 02-11-2021 

Abstract. This paper addresses the effect of mineral admixtures on fresh and hardened 
properties of self compacting concrete (SCC). Artificial neural networks (ANN) and simplex 
lattice design approach was integrated to predict and evaluate the effect of limestone, marble 
powder, natural pozzolan and slag on rheological and mechanical properties of SCC 
evaluated by slump flow, L-Box, V-funnel, sieve segregation test and 28 days compressive 
strength. The modelling results show an acceptable prediction accuracy of SCC behaviour 
containing mineral admixtures as substitution of cement especially related to the flow time 
measured with the V-funnel test and mechanical compressive strength at 28 days. 
 

Key words: SCC, ANN, simplex lattice design, mineral admixtures, fresh and hardened properties. 

1. Introduction 

Self-compacting concrete (SCC) is an innovative material characterized by its ability to 

consolidate without the necessity of mechanical vibration. This advanced concrete should have a 

low yield stress and moderate viscosity in order to achieve self-compactness and provide high 

flowability without any segregation between coarse aggregate and mortar (Okamura and Ouchi, 

2003; Elemam et al., 2020). 

It is generally known that workability and segregation resistance can be achieved by reducing 

coarse aggregate content, minimizing water to binder ratio while increasing the superplasticizer 

concentration. Furthermore, the employment of mineral admixtures was considered as another 

key factors to offer a high paste volume, forming a lubricating layer and achieve more 

workability (Sahraoui and Bouziani, 2019; Abendeh and Baker, 2021). 

A number of studies have been performed to investigate the rheological and mechanical 

properties of SCC with different mineral admixtures. Daoud and Mahgoub (2020) show that 

limestone powder can be effectively used as partial replacement of cement to enhance the 

performance of SCC in fresh and hardened stages. Alyamac et al (2017) confirm the 

improvement of fresh properties of SCC with the addition of marble powder and after an 

optimum value of substitution, the compressive strength decreases. Ghafoori et al (2016) show 

an improvement in SCC fresh properties with incorporation of natural pozzolan while 

compressive strength is slightly decreased. Zhao et al (2015) reported that the use of slag as 

mineral admixture in the SCC had not obvious effect on flowability and stability, while a 

reduction in mechanical properties was observed. 

The multilayer perceptron is an artificial neural network technique which can be used to predict 

SCC properties on the basis of input data extracted from literature. This type of network showed 

an excellent capability to predict fresh and hardened properties of SCC with high accuracy(Özgür 

Deneme, 2020; Nguyen et al., 2020). 

mailto:med.sahraoui@lagh-univ.dz


 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138 129 

 

 

Based on Scheffe's simplex lattice design technique, many researches were carried out the 

development of mathematical models in order to predict and provide a better description in the 

field of concrete materials (Ubachukwu and Okafor, 2020; Okere and Sule, 2019; Arimanwa et 

al., 2019). This kind of space-filling design is a symmetrical arrangement of points within the 

experimental region in a suitable polynomial equation representing the response surface in 

triangular contour plot (Oba and Amadi, 2020). 

2. Methodology 

The objective of this part is to illustrate the effect of mineral admixtures (limestone, marble 

powder, pozzolan and slag) as substitution of cement. Based on the design of experiments 

technique, a simplex-lattice mixture design with three factors and five levels was used to 

evaluate the effect of the above selected mineral admixtures on fresh and hardened properties of 

SCC models developed in the Part I (Sahraoui and Bouziani, 2020). The simplex-lattice modelling 

approaches can describe the influence of mineral admixtures as well as all their possible 

combinations with cement in binary and ternary systems. The number of experiments is 

expressed by the flowing relation: 

 

  
        

        
 (1) 

Where, m and q are the number of levels and factors respectively. According the Equation (1), 

the number of combinations to be treated is 21 (with m=5 and q=3). As illustrated in Figure 1, A1 

and A2 present two out of four mineral admixtures (Lim, MP, Pz and Slag) selected in this 

modelling. While cement remains unchanged in all triangular grid. It should be noted that the 

developed model is appropriate to predict SCC properties with fixed proportions summarized in 

Table 1. 

The developed model concerning the effect of mineral admixtures is expressed by a second-

order polynomial as follows: 

 

                                                    

                                                 

                                                      

             

(2) 

Where Y is the output result of ANN-based model developed in the first part (Sahraoui and 

Bouziani, 2020). 

 



130 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138  

 

 

Table 1: Concrete mixture proportioning 

Sand 

(kg/m3) 

Gravel 3/8 

(kg/m3) 

Gravel 8/15 

(kg/m3) 

Cement 

(kg/m3) 

Lim - MP - Pz - Slag 

(kg/m3) 

W/b 

 

Sp (%) 

 

860 420 420 225-450 0-225 0.4 1 

 

 

Fig. 1. Illustration of the simplex-lattice design with three factors 

 

3. Results and discussion 

Mineral admixtures combinations and their output results of ANN models are given in Table 2 

and the estimated modelling parameters of all responses are summarized in Table 3. 

V-funnel derived models have the stronger R-square and the lower root mean square error 

(R2=0.99 and RMSE in the range of 0.2-0.25) which indicate the good prediction performance of 

V-funnel models in this ANN modelling compared to the other test results.  

L-box derived model developed with MP and Slag has the highest RMSE value compared to the 

other models which mean that L-box derived model has a low accuracy in predicting SCC passing 

ability in this case study. It is also noted that slump flow model developed with Lim and Slag 

exhibit a low R2 and high RMSE compared to that with MP and Pz.  

The p-value lower than 0.05 (p<0.0001) indicates that developed models are accurate and 

performed satisfactorily to predict SCC properties. It is worth bearing in mind that ternary 

graphs selected in this work are chosen according to high and low values of obtained models in 

order to better insights the effect of mineral admixtures. 



 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138 131 

 

 

Table 2: Mineral admixtures combinations and output results of ANN models 
M

ix
 N

° MA 
combinations 

Slump (cm) L-Box (%) V-Funnel (s) Pi (%) Rc28 (MPa) 

Cm A2 A3 
A2 : Lim A2 : MP A2 : Lim A2 : MP A2 : Pz A2 : Lim A2 : MP A2 : MP A2 : Lim A2 : Lim 
A3 : Slag A3 : Pz A3 : Pz A3 : Slag A3 : Slag A3 : MP A3 : Pz A3 : Lim A3 : MP A3 : Pz 

1 0 0 1 65,54 48,80 95,69 74,23 18,31 5,20 6,91 10,00 44,30 43,30 

2 0 0,2 0,8 62,61 51,46 96,53 45,66 17,91 4,28 7,77 11,17 45,93 35,16 

3 0 0,4 0,6 76,18 57,05 97,34 28,99 16,99 4,98 8,26 12,32 50,65 24,52 

4 0 0,6 0,4 76,31 63,93 85,01 25,10 15,61 7,58 4,77 12,76 50,62 22,55 

5 0 0,8 0,2 70,82 67,02 79,46 29,52 13,90 11,50 5,15 8,20 49,31 38,11 

6 0 1 0 65,72 64,88 66,87 52,52 12,06 16,02 8,24 8,24 53,41 53,41 

7 0,2 0 0,8 64,02 55,43 93,08 86,14 15,56 5,06 7,48 11,02 47,06 44,99 

8 0,2 0,2 0,6 68,98 62,42 94,81 58,14 14,79 4,66 8,52 12,25 51,13 40,82 

9 0,2 0,4 0,4 84,90 67,93 97,24 43,20 13,69 5,96 7,87 13,01 60,02 31,22 

10 0,2 0,6 0,2 81,88 69,85 82,58 45,63 12,37 9,01 5,47 10,08 57,12 34,49 

11 0,2 0,8 0 72,63 68,22 81,32 73,62 10,95 13,15 8,34 8,34 54,28 54,28 

12 0,4 0 0,6 64,51 66,90 88,94 94,08 12,69 5,12 8,26 12,12 51,67 46,21 

13 0,4 0,2 0,4 79,53 70,21 92,66 52,34 11,64 5,13 9,06 13,03 58,09 44,81 

14 0,4 0,4 0,2 88,49 71,21 96,85 49,55 10,53 6,86 7,77 13,02 68,63 44,25 

15 0,4 0,6 0 83,48 72,06 81,59 80,86 9,45 10,17 8,50 8,50 58,75 58,75 

16 0,6 0 0,4 68,16 71,30 83,60 80,59 9,95 5,35 8,99 12,98 56,29 49,50 

17 0,6 0,2 0,2 86,81 71,83 93,15 53,00 8,78 5,61 10,38 13,48 66,13 51,80 

18 0,6 0,4 0 87,08 75,71 85,58 83,57 7,82 7,59 9,61 9,61 73,38 73,38 

19 0,8 0 0,2 74,35 72,13 79,86 70,65 7,64 5,67 10,75 13,52 67,52 59,62 

20 0,8 0,2 0 86,46 78,21 94,80 84,33 6,52 6,04 12,94 12,94 79,98 79,98 

21 1 0 0 78,79 78,79 83,45 83,45 6,01 6,01 13,78 13,78 79,96 79,96 

 

Table 3: Model parameters estimates of modelling output results 

 

Slump (cm) L-box (%) V-funnel (s) Pi (%) Rc28 (MPa) 

A2 : 
Lim 

A2 : MP 
A2 : 
Lim 

A2 : MP A2 : Pz A2 : Lim A2 : MP A2 : MP 
A2 : 
Lim 

A2 : Lim 

A3 : 
Slag 

A3 : Pz A3 : Pz 
A3 : 
Slag 

A3 : 
Slag 

A3 : MP A3 : Pz 
A3 : 
Lim 

A3 :MP A3 : Pz 

R2 0.85 0.96 0.83 0.87 0.99 0.99 0.80 0.83 0.93 0.95 

RMSE 3.93 1.83 3.89 8.68 0.20 0.25 1.15 0.93 3.34 4.31 

Coeff P<0.0001 

b1 78,81 77,68 83,06 78,78 5,71 5,80 13,87 13,88 80,69 81,38 
b2 63,02 - 65,13 - - - - 7,09 48,81 51,23 
b3 - 65,59 - 58,12 - 16,82 6,85 9,58 43,27 - 
b4 60,07 - - 83,72 12,21 - - - - - 
b5 - 46,96 96,12 - 18,53 5,01 7,90 - - 48,20 
b6 68,57 - 60,41 - - - - -1,97 15,75 -7,05 
b7 - 9,73 - 33,70 - -9,88 -3,57 5,07 -27,71 - 
b8 -3,07 - - -10,79 -1,63 - - - - - 
b9 - 22,89 -9,12 - -3,53 -0,71 -8,12 - - -71,64 
b10 - - - - - - - 15,85 22,60 - 
b11 58,73 - - - - - - - - - 
b12 - - 48,86 - - - - - - -103,17 
b13 - - - -200,87 - - - - - - 
b14 - 20,03 - - - -19,03 -3,69 - - - 
b15 - - - - 3,75 - - - - - 

 



132 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138  

 

 

 

Fig. 2. Ternary plot of slump flow (cm) as function of 
Cm, Lim and Slag proportions. 

 

Fig. 3. Ternary plot of slump flow (cm) as function of 
Cm, MP and Pz proportions. 

Ternary contour plots presented in Figure 2 illustrate the effects of cement, limestone and slag 

proportions on predicting slump flow. From this figure, it can be seen that slump flow increased 

with the increase of limestone proportions (corresponding to the rate of 15 to 25% of Lim) and 

then decreased. This is due to the fact that limestone filler scattered between cement particles, 

the maximum packing density is achieved and hence larger amount of excess water for more 

lubrication (Kounakoff et al., 2017; Hanzic and Ho, 2017; Ren et al., 2020). Once the space 

between cement grains is filled, limestone filler began to occupy the place of cement particles 

which leads to an increase in specific surface area and hence more effective water for 

lubrication. Therefore, the mixture becomes sticky, denser and hence less self-comparable 

(Benabed et al., 2012; Daoud and Mahgoub, 2020). 

 Figure 2 indicates that the increase in slag results in a reduction of slump flow. Results in 

literature revealed that the addition of slag powder has reasonably enhanced the flowability 

(Pyo and Kim, 2017; Liu et al., 2018; Gopinathan and Anand, 2018). In this case study, the 

decrease in flowability may be attributed to the fact that the mixtures models were designed at 

fixed water and superplasticizer dosage. Slag has a reactive character and requires more water 

and superplasticizer than almost other inert additions such as limestone filler, moreover, some 

superplasticizer molecules can be absorbed to the surface of very fine particles slag and leads to 

a higher request to superplasticizer (Brahim, 2018; Salehi and Mazloom, 2019) . It should be 

noted that only three studies were intended to study the effect of slag powder behaviour in this 

study (representing 7 of all 167 mixtures collected from literature) and this could make the 

model lacks to evaluate the effect of slag compared to the other mineral admixtures. This is also 

confirmed by high RMSE (3.93) and low R2 (0.85) compared to L-box model parameters 

developed with MP and Pz, as shown in Table 3. 

The effect of Cm, MP and Pz on slump flow is plotted in Figure 3. It was observed the same 

impact of marble powder as limestone on flowability but the optimum substitution is not clearly 

shown. This might be explained by the increases in paste volume and cohesiveness of SCC 

mixture caused by the lower density of marble powder. The increase in flowability with the 



 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138 133 

 

 

increase in MP is due also to its pore-filling effect (Boukhelkhal et al., 2016; Praveenkumar et al., 

2017).  

 It can be also seen that the increase of Pz proportion leads to a decrease in slump flow diameter 

and mixtures made with high content of Pz exhibit the lowest flowability, this phenomenon is 

attributed to the higher water demand of Pz particles in order to achieve a suitable workability 

(Menadi and Kenai, 2018). This is in agreement with the findings of other researchers (Belaidi et 

al., 2012; Omrane et al., 2017; Ahmad et al., 2019).  

 

Fig.4. Ternary plot of L-Box ratio (%) as function of 
Cm, Lim and Pz proportions. 

 

Fig. 5. Ternary plot of L-Box ratio (%) as function    of 
Cm, MP and Slag proportions. 

Ternary contour graph illustrated in Figure 4 presents the effects of Lim and Pz proportions on 

the L-Box ratio. It is evident that L-Box ratio increases to a maximum value with 10-15% of Lim. 

The replacement of cement by limestone filler will broaden the particle size distribution and 

filling up the interstitial void that increases wet packing density of mixture and therefore the 

maximum passing ability increases (Lai et al., 2019). It can be also seen from figure 4 that while 

the Pz content increases, the L-Box ratio increases. This may be explained by the fact that all 

modelling concrete mixtures were designed at fixed SP dosage, resulting in Pz contained 

mixtures to have better viscosity and consequently the passing ability increased (Ghafoori et al., 

2016). 

The Variations in L-Box ratios, with respect to Cm, MP and Slag variations are given in Figure 5. 

The acceptable values of passing ability according to EFNARC guideline was with 10% of MP in 

binary systems Cm-MP and more 35% of slag in Cm-Slag binary systems, beyond these 

combinations, L-box ratios are less than 80% which is out the range prescribed (EFNARC, 2002). 

MP particles provide better filling effect to increase packing density, resulting in a slower 

horizontal flow in the L-box and therefore a low passing ability (Alyousef et al., 2019). Beyond 

this optimum, L-Box ratio decreases with the increase in MP contents in binary and ternary 

systems. The large amount of MP result in a high paste volume, while exhibiting a decrease in the 

viscosity of SCC mixture (Alyousef et al., 2018). It is remarkable from Figure 5 that the amount of 

slag proportion does not appear to have a significant effect on predicting L-Box ratio in binary 

system Cm-Slag, which is confirmed by the highest RMSE value (8.68) as mentioned in Table 3.  



134 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138  

 

 

 

 
Fig. 6. Ternary plot of V-funnel time (s) as function of 

Cm, Pz and Slag proportions. 

 

 
Fig. 7. Ternary plot of V-funnel time (s) as function of 

Cm, Lim and MP proportions. 

The effect of Pz and Slag proportions on the flow time of V-funnel is illustrated in Figure 6 , all V-

funnel measurements are in the recommended range (EFNARC, 2002). As seen in this figure, the 

flow time increases with increasing Pz and Slag content. Adjoudj et al (2014) show an increase 

the viscosity when using high levels of natural pozzolan and blast furnace slag. These results are 

further confirmed by other researchers (Salhi et al., 2020; Yahiaoui et al., 2017; Belaidi et al., 

2012; Boukendakdji et al., 2009). 

Figure 7 presents the variation of V-funnel time as a function of limestone and marble powder 

content. From the obtained results, it can be seen that Limestone leads to an increase in flow 

time of V-funnel while the effect of MP is inconspicuous in this case. This can be explained by the 

effect of limestone on the enhancement of viscosity, as a result of its contribution in modifying 

the grading of the solid particles in mixture suspension and modified the water quantity 

available for the hydration process (Ede et al., 2019; Youness et al., 2020). Similar results were 

also reported by other researchers (Benabed et al., 2012; Babikir and Ahmed, 2020; Daoud and 

Mahgoub, 2020). 

Ternary contour plots showing in Figures 8 and 9 illustrate the variations of static stability with 

respect to MP, Pz and Lim proportions. Results show that Pi values decreased with the increase 

of MP, Pz and Lim in binary and ternary combinations. Tennich et al (2015) and Hameed et al 

(2016) show that the segregation resistance was increased with the increase in MP contents and 

the viscosity becomes satisfactory. Limestone filler provides large specific surface area 

accessible to unit volume of water due to its small particle size, which helps to reduce 

segregation and bleeding (Li et al., 2018). Menadi and Kenai (2018) found that SCC mixtures 

containing Pz with weight substitution level of 10 or 15% satisfy the fresh-state behaviour 

requirements related to high segregation resistance. 



 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138 135 

 

 

 

Fig. 8. Ternary plot of sieve stability Pi (%) as 
function of Cm, MP and Pz proportions. 

 

Fig. 9. Ternary plot of sieve stability Pi (%) as 
function of Cm, MP and Lim proportions. 

 

Fig. 10. Ternary plot of Rc28 (MPa) as function of Cm, 
Lim and MP proportions. 

 

Fig. 11. Ternary plot of Rc28 (MPa) as function of Cm, 
Lim and Pz proportions. 

In Figures 10 and 11, compressive strength at 28 days of SCC made with all possible binary and 

ternary combinations of Cm, Lim, MP and Pz were plotted. It is clear that the increase in Lim, MP 

and Pz contents decrease the compressive strength at 28 days. A partial replacement of cement 

by limestone filler causes a decrease in clinker content, and therefore the decrease of 28-day 

compressive strength (Akbar, 2014; Ayat et al., 2018). The slower evolution of strength at 28 

days shown in Figure 11 also caused by the slow pozzolanic reaction of PZ compared to C3S 

hydration of ordinary Portland cement (Senhadji et al., 2012; Belaidi et al., 2012). 

4. Conclusion 

In this paper, ANNs were developed to predict the effect of mineral admixtures on fresh and 

hardened properties of SCC considering Algerian experience. Following conclusions based on 

experimental results can be listed as below: 



136 Sahraoui and Bouziani, J. Build. Mater. Struct. (2021) 8:128-138  

 

 

 A high flowability was observed for SCC mixtures containing 15-25% of limestone filler 

as partial substitution of cement. 

 L-Box ratio increases to a maximum value with 10-15% of Lim and high Pz contents. 

 An acceptable passing ability remains within the limits prescribed by EFNARC can be 

obtained with 10% of MP and up to 35% of slag in Cm-MP and Cm-Slag binary systems 

respectively. 

 The time of flow measured with V-Funnel test increased with increasing Pz and Slag 

contents. 

 Static segregation decreased with the increase of Lim, MP and Pz and all studied 

modelling mixtures proves the standard condition prescribed by AFGC 

recommendations (Pi index lower than 15%). 

 A reduction in mechanical compressive strength with increasing Lim, MP and Pz 

contents for all possible binary and ternary combinations. 

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