Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Survival and activation behavior of microcapsules in self-healing asphalt mixture
Highlights The survival rate of microcapsules during mixing and compaction of asphalt mixture was measured. The survival rate of microcapsules could be improved by reducing the microcapsule size and the mixing temperature. The bigger microcapsules were more easily activated by the stress at the crack tip. It is suggested that the size of MUF microcapsules should be controlled within 15 μm ~ 25 μm.
Abstract Microcapsule technology exhibits great potential in improving the healing efficiency of asphalt mixture and prolonging the service life of the pavement. The capsule should be kept intact in the mixing and compaction process of asphalt mixture, whereas broken to release the healing agents in time when cracks encounter it. This paper aims to investigate the survival and activation behavior of microcapsules in asphalt mixture during construction and service period. By means of the in situ polymerization method, the microcapsules of various sizes were prepared and their particle size distribution, core material content, shell permeability, and other properties were characterized. Based on the quantitative analysis principle of Fourier transform infrared spectrometer (FTIR), the influence of microcapsule size and mixing temperature on the survival rate of microcapsules was analyzed. Meanwhile, the morphology and size distribution of surviving microcapsules was obtained via fluorescence microscope (FM). In addition, the morphologies of microcapsules before and after the bitumen bond strength (BBS) test and dynamic shear rheological (DSR) test were observed by FM to examine the releasing behavior of microcapsules. Finally, the fatigue-rest-fatigue test was performed to investigate the influence of microcapsule size on the healing efficiency of aged asphalt mastic. The results showed that the survival rate could be improved by reducing the construction temperature and the microcapsules size. The loss of microcapsules was more likely to happen in the mixing process rather than in the compaction process. Microcapsules with larger sizes were easier to be activated to remarkably enhance the healing efficiency of the aged asphalt mastic. Notably, the microcapsules with appropriate size are recommended to be added to the mixtures to ensure that the microcapsules survive in the construction process and are activated when cracks appeared.
Survival and activation behavior of microcapsules in self-healing asphalt mixture
Highlights The survival rate of microcapsules during mixing and compaction of asphalt mixture was measured. The survival rate of microcapsules could be improved by reducing the microcapsule size and the mixing temperature. The bigger microcapsules were more easily activated by the stress at the crack tip. It is suggested that the size of MUF microcapsules should be controlled within 15 μm ~ 25 μm.
Abstract Microcapsule technology exhibits great potential in improving the healing efficiency of asphalt mixture and prolonging the service life of the pavement. The capsule should be kept intact in the mixing and compaction process of asphalt mixture, whereas broken to release the healing agents in time when cracks encounter it. This paper aims to investigate the survival and activation behavior of microcapsules in asphalt mixture during construction and service period. By means of the in situ polymerization method, the microcapsules of various sizes were prepared and their particle size distribution, core material content, shell permeability, and other properties were characterized. Based on the quantitative analysis principle of Fourier transform infrared spectrometer (FTIR), the influence of microcapsule size and mixing temperature on the survival rate of microcapsules was analyzed. Meanwhile, the morphology and size distribution of surviving microcapsules was obtained via fluorescence microscope (FM). In addition, the morphologies of microcapsules before and after the bitumen bond strength (BBS) test and dynamic shear rheological (DSR) test were observed by FM to examine the releasing behavior of microcapsules. Finally, the fatigue-rest-fatigue test was performed to investigate the influence of microcapsule size on the healing efficiency of aged asphalt mastic. The results showed that the survival rate could be improved by reducing the construction temperature and the microcapsules size. The loss of microcapsules was more likely to happen in the mixing process rather than in the compaction process. Microcapsules with larger sizes were easier to be activated to remarkably enhance the healing efficiency of the aged asphalt mastic. Notably, the microcapsules with appropriate size are recommended to be added to the mixtures to ensure that the microcapsules survive in the construction process and are activated when cracks appeared.
Survival and activation behavior of microcapsules in self-healing asphalt mixture
Li, Bin (Autor:in) / Sun, Guoqiang (Autor:in) / Sun, Daquan (Autor:in) / Lu, Tong (Autor:in) / Ma, Jianmin (Autor:in) / Deng, Yue (Autor:in)
26.05.2020
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
| Taylor & Francis Verlag | 2023
Microcapsules for self-healing of asphalt mixture without compromising mechanical performance
| British Library Online Contents | 2017
Microcapsules for self-healing of asphalt mixture without compromising mechanical performance
| Online Contents | 2017
Microcapsules for self-healing of asphalt mixture without compromising mechanical performance
| British Library Online Contents | 2017