Performance of Self-Healing Cementitious Composites Using Aligned Tubular Healing Fiber

From the perspective of improving the self-healing method in construction, a tubular healing fiber was adopted as a container to improve the encapsulation capacity, which was available using a micro-capsule as a container. Knowing the direction of the stresses to which structure members are subjected, this research investigated the influence of aligning tubular healing fibers parallel to intended stress into a cementitious composite to increase the self-healing capability. For that, a healing agent was encapsulated into a tubular healing fiber made with polyvinylidene of fluoride resin (PVDF). Then, the healing fiber was combined with steel fibers to align both fibers together parallel to the direction of an intended splitting tensile stress when subjected to a magnetic field in a cylindrical cementitious composite. The alignment method and the key point through which the alignment of the healing fibers could efficiently improve autonomic self-healing were investigated. Since the magnetic field is known to be able to drag steel to an expected direction, steel fibers were combined with the healing fibers to form a hybrid fiber that aligned both fibers together. The required mixture workability was investigated to avoid the sinking of the healing fibers into the mixture. The healing efficiency, according to the orientation of the healing fibers in the composite matrix, was evaluated through a permeability test and a repetitive splitting tensile test. The aligned healing fibers performed better than the randomly distributed healing fibers. However, according to the healing efficiency with aligned healing fibers, it was deduced that the observed decreasing effect of the container's alignment on the specimen's mechanical properties was low enough to be neglected.

Automated summary

This study combined tubular healing fibers with steel fibers to enhance the self-healing capability of cementitious composite materials by aligning healing fibers in the intended stress direction and investigating the impact of a magnetic field on fiber alignment. The efficiency of self-healing was evaluated through permeability and splitting tensile tests, showing that aligned healing fibers outperformed randomly distributed fibers. The observed decrease in mechanical properties due to fiber alignment was considered negligible.