PSI - Issue 66

Jonathan Duarte Oliveira et al. / Procedia Structural Integrity 66 (2024) 313–319 Author name / Structural Integrity Procedia 00 (2025) 000 – 000

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structural and nonstructural performances of the conventional pervious concrete through the use of nanostructures addition and mixture optimization. Acknowledgements The author of this work tanks the continuous help of FAPERGS, CNPq and CAPES, Brazilians research agencies, giving scholarships to the students that develop this research and supporting the research project of the professors. The work of Sabrina Vantadori is supported by Italian Ministry of University and Research (PRIN: Progetti di Ricerca di Rilevante Interesse Nazionale - Bando 2022) Project code Prot. 2022X5L45T, University of Parma Research Unit. References American Concrete Institute. 2010. Report on Pervious Concrete. Farmington Hills, MI, ACI 522R-10. American Society for Testing and Materials. 2012. Standard Test Method for Density and Void Content of Hardened Pervious Concrete. West Conshohocken, PA, ASTM C1754/C1754M. Associação Brasileira de Normas Técnicas. 2021. Agregado graúdo – Determinação da densidade e da absorção de água. Rio de Janeiro, NBR 16917. Associação Brasileira de Normas Técnicas. 2022. Agregados – Determinação da composição granulométrica – Método de ensaio. Rio de Janeiro, NBR 17054. Associação Brasileira de Normas Técnicas. 2022. Agregados para concreto – Requisitos. Rio de Janeiro, NBR 7211. Associação Brasileira de Normas Técnicas. 2019. Cimento Portland - Determinação da resistência à compressão de corpos de prova cilíndricos. Rio de Janeiro, NBR 7215. Chockalingam, T., Vijayaprabha, C., Raj, J. L. 2023. Experimental study on size of aggregates, size and shape of specimens on strength characteristics of pervious concrete. Journal of Construction and Building Materials 385, 131320. https://doi.org/10.1016/j.conbuildmat.2023.131320. Ente Italiano di Normazione. 2003. Prova sul calcestruzzo indurito - Resistenza alla compressione dei provini. Milano, Italia, UNI EN 12390-3. Fédération Internationale du Béton / International Federation for Structural Concrete. 1990. fib Model Code for Concrete Structures. Lausanne, Switzerland, CEB-FIP 1990. Feng, B., Zhang, Y., Bourke, R. 2021. Urbanization impacts on flood risks based on urban growth data and coupled flood models. Natural Hazards 106, p. 613 – 627. https://doi.org/10.1007/s11069-020-04480-0. GCP Applied Technologies. 2024. V-MAR® VSC500. Cambridge: GCP Applied Technologies. https://gcpat.com/en/solutions/products/v-mar admixtures/v-mar-vsc500-data-sheet. GOM GmbH. 2019. GOM Correlate. Braunschweig: GOM GmbH. https://www.zeiss.com/metrology/en/software/metrology-software.html. Helene, P., Terzian, P. 1992. Manual de Dosagem e Controle do Concreto. PINI, São Paulo. IBGE, Instituto Brasileiro de Geografia e Estatística. 2021. Censo Demográfico 2020: Resultados gerais da distribuição da população. Brasília. https://www.ibge.gov.br. Iturrioz, I., Miguel, L. F. F., Riera, J. R., 2009. Dynamic fracture analysis of concrete or rock plates by means of the Discrete Element Method. Latin American Journal of Solids and Structures 6, 229 – 245. Khankhaje, E., Kim, T., Jang, H., Rafieizonooz, M. 2023. Laboratory evaluation of heavy metal removal from stormwater runoff by pervious concrete pavement containing seashell and oil palm kernel shell. Construction and Building Materials 400, 132648. https://doi.org/10.1016/j.conbuildmat.2023.132648 Kosteski, L. E., Barrios D'Ambra, R., Iturrioz, I., 2012. Crack propagation in elastic solids using the truss-like discrete element method. I. International Journal of Fracture 174, 139. doi: 10.1007/s10704-012-9684-4. Kosteski, L. E., Iturrioz, I., Ronchei, C., Scorza, D., Zanichelli, A., Vantadori, S., 2024. Experimental and combined finite-discrete element simulation of the fracture behaviour of a rigid polyurethane foam. Engineering Fracture Mechanics 296, 109818. doi: 10.1016/j.engfracmech.2023.109818. Oliveira, J. D., Costa, F. B. P. 2024. Desempenho hidráulico e mecânico do concreto permeável: análise dos efeitos do fenômeno de entupimento e das técnicas de manutenção. Revista Caribeña de Ciências Sociales 13, n. 2, p. 01-19. https://doi.org/10.55905/rcssv13n2-025. Pereira da Costa, F. B., Haselbach, L. M., da Silva Filho, L. C. P. 2021. Pervious concrete for desired porosity: Influence of w/c ratio and a rheology modifying admixture. Construction and Building Materials 268, 121084. https://doi.org/10.1016/J.CONBUILDMAT.2020.121084. Puglia, V. B., Kosteski, L. E., Riera, J. D., Iturrioz, I. 2019. Random field generation of the material properties in the lattice discrete element method. Journal of Strain Analysis for Engineering Design 54, p. 030932471985884-246. Riera, J. D. 1984. Local effects in impact problems on concrete structures. In: Proceedings of the Conference on Structural Analysis and Design of Nuclear Power Plants, Porto Alegre, Brazil. Rodrigues, P. C., de Sales Braga, N. T., Arruda Junior, E. S., Cordeiro, L. de N. P., de Melo, G. da S. V. 2022. Effect of pore characteristics on the sound absorption of pervious concretes. Case Studies in Construction Materials 17, 1-16. Shan, J., Zhang, Y., Wu, S., Lin, Z., Li, L., Wu, Q. 2022. Pore characteristics of pervious concrete and their influence on permeability attributes. Construction and Building Materials 327, 126874. https://doi.org/10.1016/j.conbuildmat.2022.126874.