Vázquez-Rodríguez Francisco Javier, Elizondo-Villareal Nora, Verástegui Luz Hypatia, Tovar Ana Maria Arato, López-Perales Jesus Fernando, León José Eulalio Contreras de, Gómez-Rodríguez Cristian, Fernández-González Daniel, Verdeja Luis Felipe, García-Quiñonez Linda Viviana, Castellanos Edén Amaral Rodríguez
Facultad de Arquitectura (FARQ), Universidad Autónoma de Nuevo León (UANL), 66450 San Nicolás de los Garza, N.L., México.
Facultad de Físico Matemáticas (FFM), Universidad Autónoma de Nuevo León (UANL), 66450 San Nicolás de los Garza, N.L., México.
Materials (Basel). 2020 May 1;13(9):2090. doi: 10.3390/ma13092090.
In the present work, the effect of mineral aggregates (pumice stone and expanded clay aggregates) and chemical admixtures (superplasticizers and shrinkage reducing additives) as an alternative internal curing technique was investigated, to improve the properties of high-performance concrete. In the fresh and hardened state, concretes with partial replacements of Portland cement (CPC30R and OPC40C) by pulverized fly ash in combination with the addition of mineral aggregates and chemical admixtures were studied. The physical, mechanical, and durability properties in terms of slump, density, porosity, compressive strength, and permeability to chloride ions were respectively determined. The microstructural analysis was carried out by scanning electronic microscopy. The results highlight the effect of the addition of expanded clay aggregate on the internal curing of the concrete, which allowed developing the maximum compressive strength at 28 days (61 MPa). Meanwhile, the replacement of fine aggregate by 20% of pumice stone allowed developing the maximum compressive strength (52 MPa) in an OPC-based concrete at 180 days. The effectiveness of internal curing to develop higher strength is attributed to control in the porosity and a high water release at a later age. Finally, the lowest permeability value at 90 days (945 C) was found by the substitutions of fine aggregate by 20% of pumice stone saturated with shrinkage reducing admixture into pores and OPC40C by 15% of pulverized fly ash. It might be due to impeded diffusion of chloride ions into cement paste in the vicinity of pulverized fly ash, where the pozzolanic reaction has occurred. The proposed internal curing technology can be considered a real alternative to achieve the expected performance of a high-performance concrete since a concrete with a compressive strength range from 45 to 67 MPa, density range from 2130 to 2310 kg/m, and exceptional durability (< 2000 C) was effectively developed.
在本研究中,研究了矿物集料(浮石和膨胀黏土集料)和化学外加剂(高效减水剂和减缩剂)作为一种替代内部养护技术对改善高性能混凝土性能的影响。研究了在新拌状态和硬化状态下,用粉煤灰部分替代波特兰水泥(CPC30R和OPC40C)并添加矿物集料和化学外加剂的混凝土。分别测定了坍落度、密度、孔隙率、抗压强度和氯离子渗透性等物理、力学和耐久性性能。通过扫描电子显微镜进行微观结构分析。结果突出了膨胀黏土集料的添加对混凝土内部养护的影响,其使得混凝土在28天时能达到最大抗压强度(61MPa)。同时,用20%的浮石替代细集料能使基于OPC的混凝土在180天时达到最大抗压强度(52MPa)。内部养护对提高强度的有效性归因于对孔隙率的控制以及后期较高的水分释放。最后,通过用20%的孔隙中饱和了减缩剂的浮石替代细集料以及用15%的粉煤灰替代OPC40C,发现混凝土在90天时具有最低的渗透值(945C)。这可能是由于氯离子在发生火山灰反应的粉煤灰附近向水泥浆体中的扩散受阻。所提出的内部养护技术可被视为实现高性能混凝土预期性能的一种切实可行的替代方法,因为有效地制备出了抗压强度范围为45至67MPa、密度范围为2130至2310kg/m且耐久性优异(<2000C)的混凝土。
