It is the volume of air voids in the cement composites, excluding the pore space in the particles of the aggregates. Just two research works were found and both agreed that air content is moderately reduced with the aggregate of plastic particles [32,38].

This property is related to the workability of freshly mixed concrete and mortar. Workability makes reference to how easily cement composites can be mixed, transported, placed and finished without segregation [3].

A lower slump value was observed in many papers for concrete and mortar mixes with plastic particles, in comparison with conventional mixes [27,29,33,43]. This effect could be related to the angular and non-uniform shape of the shredded plastic which could result in a lower fluidity of the mix.

Other determinations related to concrete and mortar slump were performed with varied results. Saikia and De Brito and Ferreira et al. used different w/c values to achieve a constant slump value [39,42].

As they informed, a slightly lower w/c ratio for concrete with melted plastic particles and a much higher w/c rate for shredded plastic aggregates were needed, this rate being higher for coarse particles than for fine ones. Moreover, Albano et al. presented an inverse relation between water–cement rate and slump for the same plastic amount: slump is larger for a 0.5 w/c ratio than for a 0.6 ratio [33]. Choi et al., Yang et al. and Islam et al. reported a direct relation between the amount of plastic content and workability [32,44,46]. However, it is worth mentioning that melted particles were used in these research works. Few papers were obtained on the addition of fibres. Ghernouti et al. performed a slump test of concrete with aggregate of extruded fibres and they found a slump increase when fibre content rose [24].

Finally, it is necessary to discuss a result reported by Saikia and de Brito, Sharma and Pal Bansal and Senhadji et al. [5,7,54]. They presented an increase in the slump value as a result of the addition of plastic aggregate (either particles or fibres) and they concluded that such phenomenon occurred because of the presence of more free water in the mixes, since plastic particles do not absorb as much water as conventional aggregate.

All the papers analyzed agree that the mix density decreases with the increment of plastic particle content [28,31,32,34,37,39,42,52,54]. Particularly, Hannawi et al. reported that for mixtures with more than 20% of plastic content, the dry density was lower than 2000kg/m3, which is the minimum dry density required for structural lightweight concrete according to the RILEM LC2 classification [37].

Furthermore, some authors have analyzed this detriment in relation with other variables. Saikia and De Brito analyzed the influence of particle size on density [42]. Natural aggregate was replaced by shredded plastic, and for the three replacement percentages tested (5, 10 and 15%), the cement composites with larger particles showed lower density. However, the difference never exceeded 0.6%, so it was not significant. Choi et al. reported that density decrease was more marked for smaller water/cement ratios [32]. Hannawi et al. found a larger reduction for PC than for PET [37]. Kou et al. assessed the density of the mix as it was normally hardened, air dried and oven dried, and they found that in all cases, it decreased with the increase of plastic content [34]. Finally, Dweik et al. studied the density of mortar and concrete for equal contents of plastic, and they reported a larger reduction for the first one [31].

This property is determined as the maximum measured strength at 28 days of a specimen of concrete or mortar to compression axial load, and it is a fundamental property on which concrete is categorized. Fig. 4 represents compression strength at various water/cement ratios for different plastic contents. Only research works which include water/cement ratios, compression strength and plastic content have been considered for this graphic. Over 150 results from 23 publications are presented in the figure. The group of mixes that includes plastic considers any plastic type and any percentage, and fibres and particles do not get separated.

Fig. 4.

Compression strength at various w/c values.

(0.16MB).

A tendency line corresponding to 0% plastic content was obtained, with a coefficient of determination (R2) of 0.9439, and a potential function was used, as it was the one with the best fit. As it can be seen in Fig. 4, most of the results are below the trend line of 0% plastic replacement, which means that plastic content decreases compression strength.

Plastic content ranges were fixed at intervals of 10 percentage points, except for the first range (0% to 3%), which was very significant and mainly used for fibre dosing.

Conversely, Yin et al., Pereira et al. and Koo et al. did not report differences in compression strength with the addition of fibres, maybe because of the low dosage used (less than 1.5% per volume) [15,19,21]. This result was not influenced by fibre conformation type (line or diamond indentation). Besides, Borg et al. and Ghernouti et al. checked that fibre length does not have a significant impact on compression strength [24,26]. Foti analyzed fibres cut from PET bottles in two shapes, lamellar and circular, and found that for the same amount of fibres the second ones presented a greater decrease in compression strength [14].

As regards the influence of the shredded PET particle size, the consulted authors have disagreed. For larger, particles a lower compression strength reduction is shown by Marzouk et al. [28], while Saikia and De Brito and Ferreira et al. reported exactly the opposite [39,42]. Cordoba et al. found constant compression strength up to 1.5mm of particle size, but a reduction occurred for larger sizes [41].

Usually tensile strength is closely linked to compression strength and both show similar behaviour [5]. Tensile strength is generally determined indirectly with tests such as diametric compression of a concrete specimen. Different plastics types have been analyzed and distinct results were reported in the available literature. Batayneh et al., Albano, Frigione, Saikia and De Brito, Casanova and Vazquez, Rahmani et al. and Ferreira et al. reported that tensile strength decreased with the aggregate of recycled PET either as particles or fibres [27,33,36,38,39,42,43]. Moreover, Kou et al. reported a reduction in this property with the addition of waste PVC particles [34]. In contrast with the conclusions in the previous paragraph, Ghernouti et al. found an increase of 74% in tensile strength with the addition of plastic bag fibres [24]. Yin et al. stated that the improvement of this property could be a consequence of the capacity of fibres to arrest crack propagation in concrete [6]. Yang et al. also reported an improvement on tensile strength for a 15% replacement of natural aggregate with recycled PP particles [44]. The melamine case presented by Dweik et al. reported a maximum tensile strength for approximately 20% replacement [31].

The effect of plastic particle size on tensile strength was analyzed by Saikia and De Brito [42]. Although a reduction in tensile strength was observed with an increase of PET particle dosage, for smaller particles, such reduction was lower. Fibre length did not seem to affect tensile strength [24]. An interesting fact presented by Albano was a reduction in tensile strength with an increase of w/c ratio [33]. Ferreira et al. studied the influence of curing conditions on this property and found better results for outdoor environmental curing than for wet chamber and laboratory curing, though differences were small [39].

Flexural strength is defined as the ability of a structural member to resist failure under flexural load. As regards plastic particle aggregate, Rahmani et al. found a maximum flexural strength for a 4% replacement of natural sand with plastic particles, though Yang et al. obtained a maximum for a 15% replacement [43,44]. A possible cause could be the type and shape of plastic; while the first authors used shredded PET particles, the second ones used recycled PP pellets.

Some authors have found that flexural strength dropped with an increment of plastic particle aggregate volume [27,29,37,38,42,52]. According to Marzouk et al., for more than 50% of natural aggregate substitution with plastic particles, flexural strength fell strongly [28]. The effect observed in those studies may be due to the elastic characteristics of plastic and its low bond with cement [5].

Regarding the size of plastic particles, interesting results were obtained by Marzouk et al. [28]. They compared three particle sizes (5mm, 2mm and 1mm) and observed that for the same substituted volume, the larger ones showed a more similar behaviour to the reference mortar. However, Saikia and De Brito studied the inclusion of three different particles shapes, two shredded particles (10mm and 5mm) and a melted one (4mm) [42]. In every case, flexural strength presented a decreasing trend when plastic content rose, although the most important decrease was obtained for large shredded particles, followed by the small ones and finally, the melted particles.

Particular determinations were reported in the analyzed publications. Albano et al. studied flexural strength for concrete with plastic aggregate which had been exposed to heat sources and discovered that no noticeable changes were observed at 200°C, while at 400°C and 600°C strength dropped [33]. Ismail et al. calculated the flexural tenacity index of concrete, which is determined by the area under the load-strain curve [29]. The tests showed an arrest of micro-crack propagation with the introduction of plastic particles into concrete, which implies an increment of material tenacity.

Regarding the impact of fibres on flexural strength, Ochi et al. reported a minimum flexural strength value for a plastic aggregate of 0.5% in volume [8]. For higher values, the authors observed an upward trend on flexural strength but it was followed by an increment in standard deviation. These results seem to be in accordance with the ones reported by Pereira de Oliveira and Castro-Gomes [15].

Some research works have studied the influence of fibre shape. Foti tested short laminar fibres and circular fibres, and the last ones showed a better behaviour [14]. Spadea et al. reported that longer fibres are more effective that shorter ones [23]. Despite that, Ghernouti et al. did not find any differences between 20, 40 and 60 mm-long fibres [24].

Finally, a residual flexural strength provided by fibres after concrete failure, was reported in some studies. Borg et al. observed that higher fibre volumes provided better residual strength [26]. Yin et al. found differences in the post-cracking performance between line and diamond indented fibres [21]. While the first ones were pulled out the second ones were broken, which indicates that diamond indented fibres have better bonding. Furthermore, Fraternali et al. detected a beneficial effect of fibre waviness in terms of flexural strength [20]. Crimped fibres had better flexural performance than straight ones.

The elasticity modulus is defined as a stress to strain ratio value for hardened concrete according to ASTM C 469 and it can be influenced by the aggregate types. Tests performed by Koo et al. did not show important differences in the elasticity modulus when PET fibres were added to concrete [19]. However, Casanova and Vazquez and Ferreira et al. concluded that the elasticity modulus of concrete decreased when PET particles were added [38,39]. Such disagreement may be due to the differences on PET shape or on the dosage, while Koo et al. used around 0.5% in volume, Casanova and Vazquez used 17.5% and Ferreira et al. used 5 and 10% in volume [19,38,39].

Marzouk et al., Kou et al., Hannawi et al. and Yang et al. also reported a reduction in elasticity modulus with the addition of plastic particles [28,34,37,44]. Marzouk et al. attributed that to the reduction of composite bulk densities and to the decreasing celerity of ultrasonic wave propagation because of the disturbance produced by plastic presence [28]. At this point is important to mention that the authors reported they have studied many plastic types such as PET, PP, PC and PVC.

Some authors reported higher elasticity modulus for smaller water/cement ratios no matter the plastic amount included [33,43]. However, in both research studies the modulus observed for concrete with plastic aggregate was smaller than the concrete without plastic. These observations are presented in Fig. 5. In fact, Rahmani et al. reported an inverse linear relation when they plotted the elasticity modulus against PET percentage [43]. Some authors presented possible explanations for the elasticity modulus reduction. Albano et al., reported as a cause that PET is less resistant than sand and may deform to a lesser extent when an equivalent stress is applied, so shrinkage is partially related to the elastic deformation of the PET [33]. Rahmani et al. expressed the weak bond between the texture and PET particles can be mentioned as another reason for this phenomenon [43].

Fig. 5.

Modulus of elasticity for concrete with PET particles at various w/c values from references [33]: (a) and [43]: (b).

(0.23MB).

Albano et al. found that for a fixed particle size, a higher modulus is achieved with a smaller PET content [33]. In spite of that, Cordoba et al. reported a higher modulus for 2.5% of PET in volume than for 1% and 5%; that behaviour was observed for three different particle sizes (0.5mm, 1.5mm and 3mm) [41].

Some other important conclusions were found during the review. Saikia and De Brito studied the performance of three different plastic particle shapes, two sizes of shredded particles (10mm and 5mm) and one of melted particles [42]. In every case, the elasticity modulus showed a decreasing trend with an increment of plastic content; however, the strongest decrease was obtained for large shredded particles, followed by small ones and finally, by melted ones. Finally, Marzouk et al. compared different particle sizes (5mm, 2mm and 1mm) and found the highest modulus for the largest particle size [28].

Water absorption and available water. The water absorption establishes the suitability of a porous medium to be traversed by water. The increase in porosity is related to a greater vulnerability to aggressive agents. Albano et al. reported the water absorption percentage increased with the rise of content and size of PET particles [33]. Hannawi et al. reported the same behaviour when plastic particle content increased [37]. However, other researchers stated that volumetric substitutions of plastic aggregate decreased the rate of water absorption [28,52]. Finally, Akçaözoğlu et al. observed a higher water absorption in a mortar with only PET aggregates than in mortar with sand and PET aggregates; nevertheless, they concluded that in both cases the values were in the range corresponding to lightweight concrete [35]. All authors consulted seem to agree that aggregates have an influence on porosity, and therefore, this parameter could be important for the study of cement composite durability.

Carbonation. Carbonation is a slow process in which the slaked lime (calcium hydroxide) in the cement reacts with the carbon dioxide in the air to form calcium carbonate. Carbonation causes a drop in pH and that can lead to corrosion of the reinforcement and damage of the construction.

Koo et al. did not report significant differences in carbonation depth when recycled PET fibres were added to concrete [19]. Akçaözoğlu et al. studied two types of mortar, one with only plastic particle aggregate and another one with plastic particle and sand aggregate [35]. Carbonation depth was higher for the second one. Because of that, authors inferred that PET and sand do not combine sufficiently well as aggregates.

It was also concluded that carbonation depth may not be useful to characterize cement composite with plastic aggregates. Just two research works were found with a carbonation depth analysis, both included blast furnace slag as a replacement of a part of cement and no significant impacts were reported.

Alkali resistance. Mortar and concrete are highly alkaline, with a pH range from 12 to 13. Won et al. studied PET fibres in an alkaline environment [11]. They found that surface deterioration increased with time and that at 120 days the damage advanced throughout the whole section of fibres. Ochi et al. reported that alkaline environments affect PP fibres to a larger extend than they affect PET ones [8]. Spadea et al. also studied this property for nylon fibres, not observing signs of corrosion after 120h of immersion in sodium hydroxide solution [23].

Resistance to acid environments. Acids attack concrete by ion exchange. Due to moisture gradients, pH and concentration, the ions of the hydrated paste are replaced by the ones contributed by acids. These attacks produce mass loss, coherence loss, bonding capacity loss and non-removable efflorescence. Jafeshan Araghi et al. and Nikbin et al. studied the influence of the contact with sulphuric acid solution in concrete, with PET aggregate. They found a lower weight loss and better resistance of concrete to compression, with a higher plastic content (15%). That is the reason why they concluded that this percentage of dosage can be successfully used in acidic environments, such as sewers [45,47]. Benosman et al. also confirmed that the presence of PET aggregate lower the detrimental effects of acids on composites [55].

Shrinkage. Shrinkage can be quite significant in large cementitious areas but it is also important in smaller pieces, as it affects the element surface. To avoid that, steel reinforcing meshes have traditionally been used; however, in the latest years, they have been substituted by macro plastic fibres. Only a few research works were found on this topic. Kim et al. analyzed the influence of different fibre dosages and geometries in shrinkage cracking. They reported a significant reduction in shrinkage cracking for a 0.5% in volume of fibre content but below this dosage, there was no improvement [9].

The influence of plastic particles on drying shrinkage has also been reported in the available literature. Akçaözoğlu et al. observed a significant increase in drying shrinkage values of mortar with only PET aggregate with respect to mortar containing equal weight percentage of sand and PET [35]. They also reported a lineal relation between the amount of cement in the composite, and shrinkage. Moreover, Frigione noted that the replacement of sand with PET particles caused a slight increment in drying shrinkage [36]. He associated this behaviour with the elastic modulus, as when the elastic modulus is reduced, drying shrinkage increases. On the other hand, Kou et al. reported a decreasing trend of drying shrinkage with an increasing content of plastic and they justified this result considering that plastic particles do not absorb water and do not shrink, while sand actually does [34].

Abrasion resistance. It is the ability of a surface to resist wear by rubbing and friction. As it is well known, concrete with high compressive strength normally has high abrasion resistance. In spite of that, Saikia and De Brito observed a drop in compression strength and an improvement of abrasion resistance when plastic particles were incorporated [42]. They attributed the improvement to the high toughness and good abrasion behaviour of plastic, and also to the fact that fibres have a crack-arresting effect, which could be stronger than the reduction caused by compression strength.

Gas permeability. Gases, such as carbon dioxide or others with suspended ions may attack concrete, mortar and their steel reinforcing mesh. Hannawi et al. reported an increase in the permeability coefficient with the increment of plastic content and a greater effect for PET than for PC [37]. The reported conclusion was that such impact resulted from the weak bonding of cement and plastic.

Resistance to freezing and thawing. The effect of the freezing and thawing cycles is progressive and it affects the exposed surface (which is generally more porous) in the first place. The water that enters through pores freezes and increases its volume, thus generating tensions in the concrete. Won et al. reported that, under repeated freezing and thawing tests, concrete reinforced with recycled PET fibre showed better strength than concrete without plastic aggregate [11].

Thermal conductivity. Thermal conductivity is the unidirectional heat flow that is transmitted through a material, per length and temperature unit. Considering the International System of Units, it is given by Wm−1K−1. In the analyzed publications it is named in different ways, thermal conductivity, coefficient of thermal transmission, thermal transmittance and thermal insulation. The procedure for measuring this property is similar in the publications studied. It is done through an adiabatic box, which consists of a constant thermal source at one end and measures the temperature at the other end [49].

Fraternali et al. state that the reduction of the thermal conductivity of concrete reinforced with recycled fibres allows the production of structural components capable of reducing the environmental impact and improving the energy performance of buildings [13]. According to the results obtained, the percentage of improvement is 22% for PET and 27% for PP. Yesilata et al. also conclude that the addition of recycled materials (“square rubber”) improves up to 18.52% thermal insulation compared to traditional concrete [10]. The percentage of improvement with the addition of particles of PET bottles varies between 10.27% and 18.26%, depending on the geometry of the particles. Unlike previous authors, Dweik et al. incorporate melamine-formaldehyde (MF) as a substitute for sand in 20%, 40% and 60% [31]. When studying the behaviour of thermal conductivity, they observed that for the sample with 60% of MF, temperature was 30% lower than the control one. With 30% of MF, the temperature decreased by 15%. Benosman et al. also confirmed that the presence of PET was found to lower thermal conductivity [55].

Attache et al. analyses the behaviour of the aggregate of HDPE in low proportions 2, 4 and 6% (percentage in weight); at different ages of the samples (7, 14, 28, 90 and 120 days) and temperatures (20°C, 140°C, 250°C and 350°C). In all cases, the sample with the highest HDPE content showed a decrease in thermal conductivity [51].

All the publications analyzed agree on the fact that the addition of plastic material (PET, PP, MF, HDPE, etc.) to cement composite decreases thermal conductivity, resulting in more insulating materials for the same dimensions than without the addition of plastics. This result can be attributed to the low thermal conductivity of plastics (0.15Wm−1K−1) compared to natural sand (2Wm−1K−1) [40]. In the literature review by Ngo et al., thermal conductivities of various polymers are reported from 0.11 to 0.44Wm−1K−1; these values are significantly lower than the value of the natural aggregate [50].