Circular Economy
 Flexural tensile strength: the studies conducted to evaluate the flexural tensile strength in concretewith PFledtotheconclusionthattheresistancedecreasesastheamountofaddedfibers increases (López-Buendía, 2013, Pelisser, 2012). This decrease tends to be reduced using low percentagesofplasticfibers(Ruiz-Herrero, 2016).
Durability: the addition of plastic fibers in the concrete, affects the durability of the mixture and, particularly, on shrinkage, porosity, and the possibility of entering gaseous or liquid substances into the concrete. Regarding the shrinkage, the results of the tests carried out byvariousscholarsareconflicting.Some showedadecreaseinshrinkageoftheconcretewithPF with an increase in the fibers content (Karahan, 2011). On the contrary, others have seen an increase in shrinkage with the increase of the plastic aggregate (Kim, 2010). The tests conductedontheporosityoftheconcretecontainedPFsshowsthattheporosityincreaseas the amount of PF rises (Karahan, 2011). According to the previous studies (Kakooei, 2012), the dosage of PF not have a significant influence on the possibility of entry of gaseous or liquid substances into concrete.
3. Results and conclusions
The use of plastic and recycled plastic macro fibers certainly leads to positive results with regard to the protection of the environment as it significantly reduces the amount of waste taken to landfill. As it has been shown, many research works have been developed with the main objective of reusing recycled plastic fibers as a construction material. This research field is gaining widespread attention due to the large amount of plastic materials that our society consumes daily. The conclusions of the present work are that it is feasible to revalue plastic wastes as recycled plastic fibers for being used in concrete manufacturing, improving the concrete properties. More conflicting (and certainly to be continued and deepen) are the research on the physical and mechanical characteristics of the mixture between concrete and plastic fibers. In order to obtain univocal results, thus realizing a fully usable material in the field of structural and non-structural constructions, and with characteristics equivalent or superior to concrete made only with natural aggregate. Thus, the road ahead is to continue in the investigations and experiments in this framework.
4. Acknowledgment
Thanks to all the authors who have carried out the studies and experiments mentioned in the present work.
5. References
European Parliament (2018), Directorate General for Communication - Spokesperson: Jaume Duch Guillot, The circular economy package: new EU targets for recycling. Available on-line: http://www.europarl.europa.eu/pdfs/news/expert/2017/1/story/20170120STO59356/20170120STO5935 6_en.pdf.
Fraternali F., Spadea S., Berardi V.P. (2014), Effects of recycled PET fibres on the mechanical properties and seawater curing of Portland cement- based concretes. Constr. Build. Mater. 61, 293–302.
Gu L., Ozbakkaloglu T. (2016), Use of recycled plastics in concrete: A critical review. Waste Management, 51, 19-42.
Kakooei S., Akil H.M., Jamshidi M., Rouhi J., (2012), The effects of polypropylene fibers on the properties of reinforced concrete
structures. Constr. Build. Mater. 27, 73–77.
Karahan O., Atis C.D. (2011), The durability properties of polypropylene fiber reinforced fly ash concrete. Mater. Des. 32, 1044–
1049.
Kim S.B., Yi N.H., Kim H.Y., Kim J.H.J., Song Y.-C., (2010), Material and structural performance evaluation of recycled PET fiber
reinforced concrete. Cement Concr. Compos. 32, 232–240.
Li V.C., Kanda T. (1998), Engineered cementitious composites for structural applications. J Mater Civil Eng ASCE, 1998;10(2):66–9. López-B u e n d í a A.M., Romero-Sánchez M.D., Climent V., Guillem C. (2013), Surface treated polypropylene (PP) fibres for reinforced
concrete. Cem. Concr. Res. 54, 29–35.
P e l i s s e r F., Montedo O.R.K., Gleize P.J.P., Roman H.R. (2012), Mechanical properties of recycled PET fibers in concrete. Mater. Res. 15,
679–686.
R i c h a r d s o n A.E. (2006), Compressive strength of concrete with polypropylene fibre additions. Struct. Surv. 24, 138–153.
Ruiz-H e r r e r o J.L., Nieto D.V., Lopez-Gil A., Arranz A., Fernandez A., Lorenzana A., Meriono S., De Saja J.A., R o d r i g u e z M.A.
(2016), Mechanical and thermal performance of concrete and mortar cellular materials containing plastic waste. Constr. Build. Mater. 104, 298–310.
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