Optimised mix designs for self-healing concrete
- Autores: Hary Hermawan
- Directores de la Tesis: Pedro Serna Ros (dir. tes.), Elke Gruyaert (dir. tes.)
- Lectura: En la Universitat Politècnica de València ( España ) en 2023
- Idioma: inglés
- Tribunal Calificador de la Tesis: Jean-marc Tulliani (presid.), Marta Roig Flores (secret.), Veerle Vandeginste (voc.)
- Programa de doctorado: Programa de Doctorado en Ingeniería de la Construcción por la Universitat Politècnica de València
- Materias:
- Enlaces
- Tesis en acceso abierto en: RiuNet
- Resumen
Concrete has been widely used as a major material for infrastructure works. The durable character and the advantageous price-quality ratio compared to other materials have made concrete indispensable in the modern era. However, cracks in concrete structures are inevitable and are known as one of the inherent weaknesses of concrete, thereby making a threat to the durability of infrastructure which can lead to unsafe conditions. There are many repair techniques to seal and heal the cracks, but these approaches are costly and time-consuming. Therefore, during past years, many researchers searched for alternatives to solve these problems by developing a new generation of concrete namely self-healing concrete. Self-healing technologies have proven to effectively close cracks partially or fully in the cementitious system. However, studies on the concrete level are still rather limited and in most cases, the mix designs were not optimized for the introduction of healing agents.
Based on a comprehensive literature, it was revealed that not all healing/sealing agents induce positive effects to the concrete properties. Consequently, an optimization of the mix designs is necessary to guarantee that these agents do not negatively affect the concrete properties to some extent. In this PhD dissertation, a wide range of healing/sealing agents were utilized such as bacteria (BAC), crystalline admixture (CA), biomasses, micro- and macro-encapsulated agents. Prior to the introduction of these agents into the concrete, the compatibility between healing/sealing agents and cementitious materials was evaluated to serve as a basic input for designing the concrete mixtures.
The optimizations of concrete mix designs were carried out depending on the choice of the agents and the research objectives. When using CA, it was found that increasing the CA dosage and cement content in the mix design improved the healing efficiency (HE) and sealing efficiency (SE). Varying the water-cement ratio (w/c) did not give a remarkable improvement of HE and SE. A deep insight in the bond properties between the steel reinforcement and the self-healing concrete matrix was achieved. The inclusion of healing agents (i.e., BAC, CA, biomasses) possessed a bond strength improvement with the highest enhancement of 57% attained by the CA addition. Although the presence of a longitudinal crack critically reduced the bond strength, a bond restoration was achieved due to self-healing effects. Dual effects of using microcapsules were found, confirming a significant reduction of mechanical strength and a significant sealing improvement. Therefore, the mix design parameters were optimized to compensate the strength reduction via full factorial designs. With respect to the inert structure, the incorporation of macrocapsules tended to disturb the packing of aggregates. Hence, a modified particle packing model was developed to predict the voids ratio of aggregate-capsules mixtures.
All in all, the outcome of this PhD research can serve as a guidance to understand the contribution of mix design parameters affecting the self-healing concrete properties. This potentially helps researchers and engineers to formulate their concrete mixtures for self-healing application.
