Abstract
In this study, the specimens of cemented sand were prepared by reinforcing it separately with different contents (0.5%, 1.0%, 1.5%, and 2.0%) of three different polymer fibers (polyamide, polyester, and polypropylene) prepared as filaments of different lengths (6, 9, and 12 mm). Then, these specimens were tested, and the improvement effects of the three fibers on the engineering-mechanical behavior of the cemented sand were analyzed and compared. The different microstructures and chemical compositions of the fiber-reinforced cemented sand specimens were investigated using electron microscopy and X-ray diffraction. Compression tests were performed to obtain the stress-strain curves of the specimens. Comparative analysis was performed on the variation patterns of the mechanical parameters (such as unconfined compressive strength and peak strain) of the specimens. Quantitative analysis was performed on the effect of fiber content and fiber filament length on the failure mode of the specimens. It was shown that the inclusion of fibers led to a change from brittle failure to ductile failure. The macro- and microexperimental results revealed that polypropylene fiber had the best improvement effect on the mechanical behavior of the cemented sand, followed by polyester fiber and polyamide fiber. In particular, the cemented sand specimen reinforced with 1.5% polypropylene fiber prepared as 9 mm length filaments had a brittleness index of 0.0578, exhibited ductile failure (in contrast to the brittle failure of the nonreinforced cemented sand), and yielded the highest unconfined compressive strength and shear strength among the specimens.
Highlights
Fiber-reinforced cemented sands have been widely studied in recent years
Khorami et al [6] attempted to optimize the production of fiber-cement board (FCB) using polypropylene and acrylic fibers and found that compared to conventional FCBs, FCBs improved with the two fibers exhibited better compressive, shear, and flexural strengths and toughness
Orasutthikul et al [13] compared the mechanical behaviors of mortars reinforced separately with short filaments of recycled polyamide, poly(ethylene terephthalate), and polyvinyl alcohol
Summary
Studies have shown that different chemical fibers have different improvement effects on sands [1,2,3,4,5]. Some scholars [17,18,19] have conducted some comparative tests on the reinforcing properties of the polyvinyl alcohol fiber to cement materials. In this study, cemented sand was reinforced separately with three different polymer fibers obtained from waste textile products—polyamide, polyester, and polypropylene fibers—at different contents and different filament lengths. E structures and bonding strengths of the fiber-reinforced cemented sand specimens were tested and analyzed using electron microscopy and X-ray diffraction (XRD). E mechanism underlying the effect of the fibers on the failure mode (brittle or ductile) of the cemented sand was investigated by analyzing the variations in the stiffness coefficients and brittleness indexes of the specimens. E structures and bonding strengths of the fiber-reinforced cemented sand specimens were tested and analyzed using electron microscopy and X-ray diffraction (XRD). en, unconfined compression tests were performed to compare the mechanical parameters (such as unconfined compressive strength and peak strain) of the specimens. e mechanism underlying the effect of the fibers on the failure mode (brittle or ductile) of the cemented sand was investigated by analyzing the variations in the stiffness coefficients and brittleness indexes of the specimens. is study will provide theoretical inputs for the selection of polymer fibers for the reinforcement of cemented sands and will be of reference value for future studies on the microdynamics and mechanical failure modes of fiber-reinforced composite materials
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