Recycled Expanded Polystyrene as Lightweight Aggregate for Environmentally Sustainable Cement Conglomerates

Petrella, Andrea; Mundo, Rosa Di; Notarnicola, Michele

doi:10.3390/ma13040988

Cited by 46 publications

(23 citation statements)

References 60 publications

(75 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The presence of voids and loose packing of the elements resulted in weaker bonding observed between the elements, and hence corresponding decrease in compressive strength. This trend is similar to that observed in previous research [20]. Figure 7 shows the scanning electron micrograph (SEM) of the sample with 90% OPC and 10% PPA/POL.…”

Section: Scan Electron Microscopysupporting

confidence: 89%

Assessment of cement concrete partially replaced with polystyrene and plantain peel ash

Aderinola¹,

Yusuf²,

Omotayo³

2020

Nig. J. Tech.

View full text Add to dashboard Cite

This study assessed the effect of partial replacement of cement with plantain peel ash (PPA) and Polystrene (POL) on the compressive strength of concrete as a means of managing waste. Concrete specimens were prepared with a mix ratio of 1:2:4 (cement: sand: granite) water/cement ratio of 0.6, thereafter cement was partially replaced with PPA, POL and PPA/POL in increasing percentages of 5, 10, 15 and 20% by weight. Physical, chemical and microstructural analyses were also conducted on the aggregates and materials used. Workability of the concrete specimens was observed to improve upon addition of PPA and POL separately but not with blended PPA/POL while compressive strength decreased with addition of the three compounds. The observed results can be attributed to the lack of sufficient cementitious properties in the materials, and hence, the study discourages the use of these materials as they do not significantly improve concrete strength. Keywords: Plantain Peel Ash (PPA), Polystyrene (POL), Compressive Strength, Sustainable Waste Management

show abstract

Section: Scan Electron Microscopysupporting

confidence: 89%

Assessment of cement concrete partially replaced with polystyrene and plantain peel ash

Aderinola¹,

Yusuf²,

Omotayo³

2020

Nig. J. Tech.

View full text Add to dashboard Cite

show abstract

“…The sand replacement with tire rubber determined the formation of voids in the composite ( Figure 5C) at the organic/inorganic interface due to the unfavorable adhesion of the aggregate to the cement paste [49][50][51][52][53][54], with a decrease of the specific mass and increase of the porosity of the samples with respect to the references ( Table 1). The hydrophobic tire rubber with its organic compounds can explain the poor adhesion to the inorganic and hydrophilic cement matrix, on the contrary to what was observed with the sand in the reference sample with a good adhesion of this aggregate to the cement paste [55].…”

Section: Resultscontrasting

confidence: 69%

“…Th sults were totally ascribed to the hydrophobic nature of the organic aggregate in the higher porosity with respect to the reference and the bare perlite samples. The and the bulk of the bare perlite samples showed a fast water absorption and a hydr behavior ( Figures 13B and 14B) due to the hydrophilic porous domains of the in aggregate and of the cement paste, a result also observed in the case of the referen mortars [23,55]. In the case of the rubber/perlite sample (P/TRF), the water absorpti significantly lower than the perlite and reference samples but higher than the TR m (≈20% on the side surface, ≈20% on the fracture surface), thanks to the opposite con…”

Section: 14 X For Peer Reviewsupporting

confidence: 52%

Lightweight Cement Conglomerates Based on End-of-Life Tire Rubber: Effect of the Grain Size, Dosage and Addition of Perlite on the Physical and Mechanical Properties

Petrella¹,

Notarnicola²

2021

Materials

Self Cite

View full text Add to dashboard Cite

Lightweight cement mortars containing end-of-life tire rubber (TR) as aggregate were prepared and characterized by rheological, thermal, mechanical, microstructural, and wetting tests. The mixtures were obtained after total replacement of the conventional sand aggregate with untreated TR with different grain sizes (0–2 mm and 2–4 mm) and distributions (25%, 32%, and 40% by weight). The mortars showed lower thermal conductivities (≈90%) with respect to the sand reference due to the differences in the conductivities of the two phases associated with the low density of the aggregates and, to a minor extent, to the lack of adhesion of tire to the cement paste (evidenced by microstructural detection). In this respect, a decrease of the thermal conductivities was observed with the increase of the TR weight percentage together with a decrease of fluidity of the fresh mixture and a decrease of the mechanical strengths. The addition of expanded perlite (P, 0–1 mm grain size) to the mixture allowed us to obtain mortars with an improvement of the mechanical strengths and negligible modification of the thermal properties. Moreover, in this case, a decrease of the thermal conductivities was observed with the increase of the P/TR dosage together with a decrease of fluidity and of the mechanical strengths. TR mortars showed discrete cracks after failure without separation of the two parts of the specimens, and similar results were observed in the case of the perlite/TR samples thanks to the rubber particles bridging the crack faces. The super-elastic properties of the specimens were also observed in the impact compression tests in which the best performances of the tire and P/TR composites were evidenced by a deep groove before complete failure. Moreover, these mortars showed very low water penetration through the surface and also through the bulk of the samples thanks to the hydrophobic nature of the end-of-life aggregate, which makes these environmentally sustainable materials suitable for indoor and outdoor elements.

show abstract

“…In the papers by Petrella and coworkers [12,13], recycled materials, such as end-of-life tire rubber (TR), porous glass (PG) and expanded polystyrene (EPS) were used as aggregates for the production of unconventional cement mortars. A cheap and environmentally safe process was employed, since no pre-treatment of the renewable aggregates was carried out.…”

Section: Waste Products For Construction Materialsmentioning

confidence: 99%

“…For that purpose, six papers were related to the preparation of innovative composite materials. Specifically, five papers reported the reuse of end-of-life tire rubber, porous glass, expanded polystyrene, slags, fly ashes and sheep's wool fibers for the preparation of cement conglomerates [12][13][14][15][16], while the last one reported the reuse of amorphous silica nanoparticles for the preparation of composites with natural rubber [17]. Moreover, five papers were related to the treatment of wastes for environmental applications.…”

Section: Introductionmentioning

confidence: 99%

Novel Bioderived Composites from Wastes

2020

Self Cite

View full text Add to dashboard Cite

show abstract

Recycled Expanded Polystyrene as Lightweight Aggregate for Environmentally Sustainable Cement Conglomerates

Cited by 46 publications

References 60 publications

Assessment of cement concrete partially replaced with polystyrene and plantain peel ash

Assessment of cement concrete partially replaced with polystyrene and plantain peel ash

Lightweight Cement Conglomerates Based on End-of-Life Tire Rubber: Effect of the Grain Size, Dosage and Addition of Perlite on the Physical and Mechanical Properties

Novel Bioderived Composites from Wastes

Contact Info

Product

Resources

About