Abstract

To increase the engineering applications of basalt fiber, the characteristics of the shear mechanical properties and the influence mechanisms of the fiber length ( L f ) and volume fraction ( V f ) for short basalt fiber reinforced epoxy resin polymer composites were investigated. The following results were obtained: (1) The first critical loads on all the shear load–displacement curves are close to the same value due to having the same interface bonding of the fiber–matrix; (2) the shear strength, deformation, and energy dissipation capacity all increase with increasing V f ; however, when L f is 6 or 9 mm, these increases are slower, whereas when L f is 3 mm, these values increase at an approximately constant rate; and (3) the shear elastic modulus of the samples reaches its maximum value when L f is 3 mm and V f is 25%; however, it increases more quickly when L f is 6 or 9 mm. The failure mode of the samples with the larger L f values is mainly debonding between the fiber and matrix; when V f is high, the fibers can easily bundle, which reduces the adhesion between the fibers and matrix. In addition, the main failure mode of the 3-mm-long fiber samples is fiber pull-out; when V f is high, the short fibers that are not pulled out significantly increase the deformation ability.