TEMPLATE FOR ACADEMICA SCIENCE JOURNAL


 

  AL-QADISIYAH JOURNAL FOR    
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Vol. 11, No. 1  

ISSN: 1998-4456 

 

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EXPERIMENTAL INVESTIGATION ON THE FRESH AND 
HARDENED PROPERTIES OF CONCRETE INCORPORATING 

POLYVINYL 

 

Abo Dhaheer, M.S., 

Civil Engineering Department, College of Engineering, University of Al-Qadisiyah 
Al-Diwaniyah, Iraq 

E mail:  

shamelm2000@gmail.com         ;        mohammed.abodhaheer@qu.edu.iq 

 

Received on 22  January 2018   Accepted on 24 January 2018   Published on 14 May 2018 

DOI: 10.30772/qjes.v11i1.525 

 

Abstract: Polyvinyl alcohol (PVA) has undergone intensive research work that has led to 
confidence in its utilization in various applications. Nevertheless, its utilization as a 
construction material in the concrete industry still needs to be fully addressed. In this 
paper, an experimental study was dedicated to investigate the influence of PVA on the 
fresh and hardened properties of concrete. Three different strength grades, represented 
by water to cement ratios (w/c), of 0.4, 0.5 and 0.6, with four different PVA dosages of 1, 
2, 3 and 4%, by mass of cement, were employed in the preparation of the concrete mixes. 
Concerning the fresh properties, results showed that there was a significant contribution of 
PVA to the workability in all produced mixes, irrespective of w/c ratio. In addition, the initial 
and final setting time of cement pastes modified with 2% PVA were longer than that of the 
control paste. In term of the hardened properties, results demonstrated that the 
compressive (fcu) and splitting tensile (fst) strengths of concrete are dominated by amounts 
of PVA in the mix and w/c ratios. With the high and moderate w/c ratios, they increased 
when up to 2% PVA was used, and thereafter decreased. However, with the low w/c, PVA 
did not provide any improvement in the strength, but instead, it decreased the strength 
when more than 2% was added. The findings revealed also that increasing PVA content 
resulted in a significant reduction in total water absorption (TWA) of concrete specimens. 
The larger the PVA contents the lower is the TWA of the specimens. 

                                                         

Keywords: polyvinyl alcohol, compressive strength, tensile strength, slump test, total 
water absorption 

INTRODUCTION 

The reason why concrete is by far one of the most widely utilized construction material is that it can be 
formed in preferred formwork with a superior durability, strength, ability to withstand extreme environments 
and in-situate fabrication. Nevertheless, being heterogeneous and porous material, plain and reinforced 
concrete structures could be prone to inherent defects such as voids, micro-cracks and water-filled pores [1]. 

mailto:mohammed.abodhaheer@qu.edu.iq


 

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These defects, even prior to load application, can become a serious issue in the concrete structures 
influencing their strength and durability performance [2].  

A judicious choice to overcoming or minimizing the adverse influence of the aforementioned 
shortcomings is by utilizing fine materials [3-6] and polymers [7-11]. The fine materials assist in modifications 
of the concrete microstructure, resulting in a least porosity and dense matrix [6]. However, the fine materials, 
in order to be effective, need to be added in relatively large amounts, in which the concrete will be more 
costly. On the other hand, polymers, unlike fine materials, can be used in small amounts to enhance the 
performance of cement paste, cement mortar and concrete products [7-11]. For this reason, different types 
of polymer additives in the field of concrete industries have been tried, such as; re-dispersible polymer 
powders, liquid resins, monomers and water-soluble polymers [7]. Among the water-soluble polymers, 
polyvinyl alcohol (PVA) has been introduced and exploited in the field of cement-based products [11-17].  

Reviewing the research work regarding the fresh properties, studies have indicated that up to a certain 
limit, the incorporation of PVA has positive influences on concrete workability and water retention ability 
[12,14,16]. However, the influences of PVA towards the hardened properties of cement-based products have 
been found to have inconsistent results. In some research work, it was concluded that the addition of PVA is 
accompanied with an improvement of the mix compressive strength [15, 18-19]. According to Mannan et al. 
[18] and Kou and Poon [19], treatment of oil palm shell aggregate and recycled aggregate with PVA showed 
an improvement in strength performance of concrete specimens. However, Kim et al. [12] reported that PVA 
can reduce the compressive strength of cement mortar as it increases the air voids content. Regarding the 
flexural strength, Allahverdi et al. [11] reported that with a lower w/c ratio, the cement pastes modified with 
PVA showed a slight decrease in flexural strength. Kim et al. [12] concluded that with the addition of PVA, no 
significant changes were observed in flexural strength of cement mortar samples. However, different results 
were also found in a previous study [20] in which the PVA modified cement mortar samples showed a 
noticeable increase in their flexural strength as compared with unmodified samples. For more details 
regarding the rule of PVA on cement-based products, we refer the researcher to recently published paper 
[13], where the state of the art review on this topic has been deeply discussed.  

Due to the inconsistent findings and limited literature published about the influence of PVA on the 
properties of concrete, its characteristics behavior and performance still need to be thoroughly addressed. 
Beside that, since no research work (to the best knowledge of the author) has locally been reported until 
now, it is not clear whether or not the performance of concrete mixes containing PVA is still the same when 
locally available materials are used. Therefore, more laboratory work, in this regard, are crucial to drawing 
reliable conclusions. In this paper, the goal was to experimentally investigating the role of two compositional 
parameters – PVA dosage and strength grade (i.e., w/c ratio) - of concrete mixes in their fresh and hardened 
properties. These mixes, which comprised locally sourced building materials, were examined in the fresh 
state using setting time and workability tests, and in the hardened state by performing compressive strength, 
splitting tensile strength and total water absorption tests. 

1. EXPERIMENTAL PROGRAM 

1.1. MATERIALS 

In this research a locally available type I cement, commercially known "Crista", was used. It satisfies 
Iraqi specification (IQS) No.5/1984 [21]. Crushed coarse aggregate of 20 mm size and 2.63 specific gravity 
was used. The fine aggregate (natural sand) with a maximum grain size of 4.75 mm and a specific gravity of 
2.60 was used. Both the fine and coarse aggregates satisfy IQS No.45/1984 [22]. A solution of PVA was 
prepared by watery dissolving the polymer; 60 g of PVA was boiled in 1000 ml water. The solution was then 
subjected to heating over a period of 10 hours with continuous stirring in a temperature of 100C, and it was 
then kept overnight at ambient temperature in the lab. 

 



 

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1.2. MIX PROPORTIONING 

In this study, a series of concrete mixes using three different w/c ratios of 0.6, 0.5 and 0.4 were 
carried out. They were designated MixL, MixM and MixH for relatively low, medium and high compressive 
strengths, respectively. The constituent materials of the prepared mixes were initially chosen with the aid of 
British mix design procedure [23]. However, the actual constituents (as will be explained later in sectios 3.1 
and 3.3) depended on (1) the amount of the mixing water that allowed the slump values of control mixes to 
vary between 30-60 mm, and (2) the amount of fine aggregate that was adjusted to keep the mass of coarse 
aggregate constant in all prepared mixes. The mix proportions (per cubic metre) were presented in Table 1. 
PVA dosages were 1, 2, 3 and 4% by mass of cement. PVA solution had been replaced by an equivalent 
amount of mixing water and mixed with it before they were added to the remaining ingredients in the mixer.  

 
Table 1. Constituent materials of the tested concrete mixes, kg/m3 

Mix 

designation 
(w+PVA)/c*  Cement 

Fine 

aggregate 

Coarse 

aggregate 
Water PVA 

% PVA by 

cement weight 

Mix0L 

0.6 335 760 1050 

202.0 0.0 0 

Mix1L 198.7 3.4 1 

Mix2L 195.3 6.7 2 

Mix3L 192.0 10.1 3 

Mix4L 188.6` 13.4 4 

Mix0M 

0.5 380 745 1050 

190.0 0 0 

Mix1M 186.2 3.8 1 

Mix2M 182.4 7.6 2 

Mix3M 178.6 11.4 3 

Mix4M 174.8 15.2 4 

Mix0H 

0.4 445 730 1050 

178.0 0.0 0 

Mix1H 173.6 4.5 1 

Mix2H 169.1 8.9 2 

Mix3H 164.7 13.4 3 

Mix4H 160.2 17.8 4 

(w+PVA)/c* : Figure in parenthesis refers to substitution of PVA by an equivalent amount of the mixing water such 
that w/c ratio becomes (w+PVA)/c. 

 

1.3. TEST PROCEDURE 

In the present study, experimental tests for the fresh and hardened mixes were carried out, including: 
initial and final setting times, slump, compressive strength, splitting tensile strength and total water 
absorption. The initial and final setting time tests were conducted on cement pastes according to ASTM 
C191-82 [24]. The slump of fresh concrete was measured using the standard slump test apparatus 
according to ASTM C143 [25]. For each concrete mix, three cubes of 150 mm and six cylinders of 100 × 200 
mm were cast to determine the compressive strength (fcu), splitting tensile strength (fst), and total water 
absorption (TWA), respectively. All specimens were cast in steel moulds and then demolded after 24 hours 



 

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and cured in water until the age of 28 days. fcu, fst and TWA were measured according to B.S. 1881 [26], 
ASTM C496-86 [27] and ASTM C-642 [28], respectively.  

 

2. RESULTS AND DISCUSSION 

2.1. WORKABILITY 

To investigate the effect of PVA on the workability of fresh concrete mixes, slump test was 
performed in this study. From an engineering perspective, water content is considered the most important 
parameter affecting the workability of fresh concrete. To take this issue into consideration, the amounts of 
water contents in the control mixes (Mix0L, Mix0M and Mix0H) were adjusted by performing trial mixes to 
maintain slump values in the range of 30-60 mm. To get more precise results of the slump test, PVA solution 
was replaced by an equivalent amount of the water used in the mixes such that w/c ratio was represented by 
(w+PVA)/c. Another important parameter of the fresh concrete workability, which cannot be overlooked, is 
the volume fraction of coarse aggregate (CA). It forms more than 33% of the total mix volume. In order to 
eliminate any possible influence of this parameter on the fresh properties, CA amounts were kept 
constant for all prepared mixes.  

The results of slump test of the present study have been presented in Table 2 and graphically 
plotted in Figures 1-2. Figure 1 shows that there is a significant improvement in the workability of fresh 
concrete for all produced mixes, regardless of the mix w/c ratio. Increasing PVA up to 4%, increases the 
slump values, with respect to control mix, from 62 to 83 mm, from 35 to 67 mm and from 41 to 85 mm for w/c 
ratios of 0.4, 0.5 and 0.6 respectively. As indicated in Figure 2, the maximum relative slump to the control 
mix (at 4% PVA) is about 148, 191 and 207 for w/c ratios of 0.4, 0.5 and 0.6 respectively. As mentioned 
above, the workability of control mixes depended on trail mixes to reach the target slump range. This could 
explain the reason behind the difference in slump values of the control mixes prepared with the chosen w/c 
ratios.      

The positive effect of PVA on the workability is in agreement with results of a study carried out by 
Allahverdi et al. [11] and Kim et al. [12]. The improved workability with the addition of PVA is very likely 
attributed to the enhancement of concrete matrix due to the ‘‘ball bearing” effect of the water-soluble polymer 
[11, 13]. The other key reason behind that enhancement in fresh concrete workability could be the 
deflocculating influence of PVA on the cement particles in addition to its lubricating effect on the fine and 
coarse aggregates in the mix. Accordingly, it would be worthwhile to examine the role of PVA to be used as 
a water reducing admixture (plasticizer), which in turn, would result in decreasing water demands for a 
particular mix workability, and thereby, improving its strength. 

 

Table 2. Slump test results of the fresh mixes 

w/c=0.6 w/c=0.5 w/c=0.4 

Mix 

designation 

Slump 

mm 

Mix 

designation 

Slump 

mm 

Mix 

designation 

Slump 

mm 

Mix0L 41 Mix0M 35 Mix0H 62 

Mix1L 51 Mix1M 40 Mix1H 76 

Mix2L 68 Mix2M 56 Mix2H 84 

Mix3L 82 Mix3M 63 Mix3H 80 

Mix4L 85 Mix4M 67 Mix4H 83 

 

 



 

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Figure 1: Slump test of the fresh mixes versus PVA dosages at different w/c ratios 

 

 

Figure 2: Relative slump to the control mix at different PVA dosages and w/c ratios 

 

2.2. SETTING TIME 

The results of the initial and final setting time of the produced mixes using Vicat apparatus [24] are 
given in Table 3 and Figures 3-4. Apparently from Figure 3, both setting times increase when up to 2% PVA 
is added, and thereafter decrease. With respect to the control mix, they increase from 74 to 89 min and from 
267 to 300 min, corresponding to an increase of 20% and 12%, respectively, when up to 2% PVA is used. 
However, above this percentage, the initial setting time of cement paste remains longer than that of the 
control paste. As clearly seen in Figure 4, the relative initial and final setting time reach about 116% and 



 

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98% of the control mix, respectively, when 4% PVA is added. A possible justification for that increase in the 
setting time is that the microstructure of cement paste matrix could be altered with the presence of PVA, 
which acts as an agent for inhibiting the hydration of cement particles. 

It is worth emphasising that the workability and setting time of concrete can be considered as the two 
key issues influencing its fresh state and hardened state as well [23]. This is of prime importance when 
planning to cast a concrete mix in a hot weather. Without paying attention to this issue, concrete will 
practically experience a difficulty in its construction process such as, transporting, handling, placing and 
finishing. Based on the above results, the use of PVA in concrete industries, particularly in the climates that 
are characterized by long hot and dry summers, is expected to offer a simultaneous potential in workability 
(as plasticizer) and in setting time (as a retarder admixture). Thus, the influences of aforementioned 
circumstances on the construction process of fresh concrete can be mitigated. In this regard, it is, however, 
necessary to use an optimum dosage of PVA because its high amount (as will be seen later), might result in 
negative consequences on the concrete strength. 

 

Table 3. Initial and final setting time test results 

% PVA 

by cement weight 

Setting time, min. 

Initial Final 

0 74 267 

1 83 285 

2 89 300 

3 87 269 

4 86 261 

 

 

Figure 3: Initial and final setting times of cement pastes at different PVA dosages 



 

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Figure 4: Relative setting time to the control mix at different PVA dosages  

 

2.3. COMPRESSIVE STRENGTH 

The compressive strength (fcu) is considered to be the most important property of concrete structures 
that provides an indication of their general performance [23]. This property is primerly determined by the 
water to cement ratio (w/c) under particular parameters. In addition to w/c ratio, concrete mixes are also 
influenced by the amounts of coarse aggregate (CA) as it typically occupies more than a third of the concrete 
volume. Consequently, changes in CA contents can affect the workability and strength as well. That is, for 
this reason, the masses of CA in all produced mixes were kept constant (see Table 2). This will exclude any 
possible effect of this ingredient material on the concrete strength, allowing the w/c ratio and PVA dosage to 
be the most important mix parameters controlling its strength. Keeping the amount of CA constant, the fine 
aggregate (FA) was adjusted in all produced mixes such that the total mix volume worked out to be 1 m3, 
accordingly.  

The results of compressive strength (fcu) at the age of 28 days are shown in Table 4 and plotted for 
all w/c ratios in Figures 5-6. It is indicated that, fcu seems to be dominated by the amounts of PVA in the mix 
and the w/c ratios. With the high w/c ratio (i.e. 0.6), fcu increases moderately (about 11%) when up to 2% 
PVA is used (Mix2L) and thereafter decreases, but it remains approximately the same as the control mix at 
the maximum PVA dosage. For the mix with 0.5 w/c, fcu increases marginally (3%) when up to 2% PVA is 
used, and then decreases, as clearly seen in Figure 6. The increase in fcu with the addition of PVA could be 
due to the chemical interaction between the PVA and cement particles that results in improving mix 
microstructure and formation some new compounds in the cement matrix [12]. From the other side, in the 
mixes with a w/c ratio of 0.4 (Mix1H-Mix2H), which possess the lowest w/c ratio among the produced mixes, 
the addition of PVA does not provide improvements in the compressive strength, but instead, it decreases 
the strength when more than 2% is added. At 4% PVA (Mix4H), fcu registered about 90% of the control mix 
(Figure 6). 

 

 

 

 

 



 

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Table 4. Hardened properties test results 

Mix  

designation 

fcu 

MPa 

fst 

MPa 

TWA 

% 

Mix0L 24.5 2.25 5.10 

Mix1L 26.8 2.53 4.78 

Mix2L 27.2 2.47 4.05 

Mix3L 26.0 2.35 3.60 

Mix4L 24.8 2.28 3.38 

Mix0M 31.4 3.41 4.35 

Mix1M 31.1 3.56 4.17 

Mix2M 30.4 3.59 3.75 

Mix3M 30.1 3.26 3.23 

Mix4M 29.5 3.05 3.15 

Mix0H 42.4 4.55 3.44 

Mix1H 42.0 4.61 3.35 

Mix2H 41.7 4.46 3.23 

Mix3H 38.6 4.28 2.78 

Mix4H 38.0 3.72 2.63 

 

 

Figure 5: Compressive strength versus PVA dosages at different w/c ratios 

 



 

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Figure 6: Relative fcu to the control mix at different PVA dosages and w/c ratios 

 

2.4. SPLITTING TENSILE STRENGTH 

The splitting tensile strength (fst) of the prepared mixes (using cylinders of 100 x 200 mm) is 
indicated in Table 4 and Figures 7-8. The influence of PVA on fst is found to be almost similar to that of 
compressive strength. With w/c ratio of 0.6, the presence of PVA in the concrete mixes demonstrates an 
increase of about 12% in their fst when up to 2% PVA is added (Mix1L and Mix2L), then it decreases as PVA 
percentage increases. The improved microstructure due to the formation of new compounds in the cement 
matrix could be the reason behind that enhancement in fst [12]. However, in 3% and 4% PVA (Mix3L and 
Mix4L), less enhancement in fst is observed.  

Apparently from Figure 8, fst is found to have a marginal increase (about 5%) in the mixes with 0.5 
w/c ratio, but it has no changes in that of 0.4 w/c ratio when up to 2% PVA is added. Beyond this percentage, 
the produced mixes suffer from a reduction in their tensile strength, and this reduction is more pronounced 
when using 4% PVA (Mix4H). This could be justified by incomplete hydrolysis of PVA due to the relatively 
lower amounts of provided water (160 kg), which is exhausted in the workability and hydration of the 
relatively high amount of cement (445 kg) in Mix4H. For comparison, Allahverdi et al [11] reported that fst of 
cement paste mixes with 0.3 w/c ratio was found to be two folds of the reference mix when about 2% PVA 
was used.  

 



 

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Figure 7:Splitting tensile strength versus PVA dosages at different w/c ratios 

 

 

Figure 8: Relative fst to the reference mix at different PVA dosages and w/c ratios 

 

 

 



 

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2.5. TOTAL WATER ABSORPTION 

From an engineering point of view, porosity or water absorption is one of the important key 
parameters From an engineering point of view, porosity or water absorption is one of the important key 
parameters controlling concrete durability. In other words, any reduction in the concrete porosity can yield to 
an improvement in its durability performance [23]. From the test results presented in Figures 9-10, it can be 
noticed that with the increase in PVA contents, there is a considerable reduction in the total water absorption 
(TWA) of the concrete mixes for all w/c ratios. As clearly seen in Figure 10, TWA of concrete specimens with 
4% of PVA can be reduced by approximately 24%, 28% and 34% for 0.4, 0.5 and 0.6 w/c ratios, 
respectively, in comparison with the control mixes. Here, it is, however, worth mentioning that while 4% of 
PVA is the optimum amount for reducing TWA, the concrete specimens, in term of strength, reach their best 
performance when up to 2% PVA is used. For comparison, the results of TWA in this study are in agreement 
with the findings reported in [11-12].  

The positive influences of PVA on TWA are very likely related to the improved concrete 
microstructure, which in turn is significantly affected by the interfacial transition zone (ITZ) between the 
cement paste and aggregate [16]. The ITZ of concrete mixes treated with PVA becomes denser and more 
uniform as compared with the untreated mixes [13]. Accordingly, promising findings in term of durability 
performance of concrete specimens subjected to different curing conditions can be expected. In this regard, 
an extensive experimental study by the author is ongoing.  

 

 

Figure 9: Total water absorption versus PVA dosages at different w/c ratios 

 



 

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Figure 10: Relative TWA to the control mix at different PVA dosages and w/c ratios 

 

CONCLUSIONS 

The main findings of the presented study indicate that PVA modified concrete mixes are accompanied 
with improvements in their fresh and hardened properties, alike. These can be summarized as follows: 

 
1. The initial and final setting time of the cement pastes increase when up to 2% PVA is added, and 

thereafter decrease. However, PVA is comparatively more effective in increasing the initial than final 
setting time. 
 

2. There is a significant improvement in concrete workability with increasing the dosage of PVA, 
irrespective of the mix w/c ratio, although the improvement is less pronounced in the mixes with a 
relatively low w/c ratio. 

 
3. The compressive (fcu) and splitting tensile (fst) strengths of concrete are controlled by the amounts of 

PVA in the mix and the w/c ratios. With the high and moderate w/c ratios, they increase when up to 2% 
PVA is added. However, with the low w/c, PVA does not provide any improvement in the strength, but 
instead, it decreases it when more than 2% is used. 

 
4. The porosity of concrete specimens is considrably reduced with the addition of PVA at all w/c ratios. The 

higher the PVA content the lower is the total water absorption. Here, it is interesting to mention that while 
2% of PVA is the optimum amount for both compressive and splitting tensile strength, concrete 
specimens in term of porosity as well as workability reach the best performance when PVA is increased 
to 4%.  

 



 

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ACKNOWLEDGMENT  

The author is thankful to Mr. Alshemary (senior lecturer in the Chemical Engineering Department - the 
University of Al-Qadisiyah) for preparing the PVA used in this research work. The author is also grateful to 
the technical staff of concrete laboratory of Engineering Consultant Bureau in the College of Engineering - 
the University of Al-Qadisiyah- for their assistance during the testing period. 

 

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