AI Article Synopsis
- The study explores how the orientation and density of basalt fibers (BF) in concrete affect its mechanical properties, highlighting a gap in existing research on BF morphology.
- Using innovative methods, the research investigates the relationship between the amount of BF (0-7.5 kg/m) and its morphological characteristics, finding that optimal mechanical properties occur at around 3 kg/m of BF.
- Advanced imaging techniques (NMR and CT) reveal that clustering of BF leads to increased macro-pores in the concrete, which negatively impacts performance and enhances chloride ion permeability.
Article Abstract
The orientation, distribution, and contact point density of BF (basalt fiber) in the concrete matrix play significant roles in the mechanical properties of BF concrete, but represent a weak point in current research. It is meaningful to study the morphological characteristics of BF in concrete. In this study, the transparent model test and joint blocking method were innovatively adopted to investigate the correlation of dosage with the BF morphological parameters and concrete mechanical properties. A focus on a BF dosage of 0-7.5 kg/m and the contribution index of fibers C was defined. Furthermore, NMR and CT techniques were used to observe the changes in the microstructure of BF concrete. The experimental results show that the BF contribution index C reaches the largest value when the BF content is around 3 kg/m, approximately 2.7; in this case, the mechanical properties of BF concrete were also optimal, and the C was only 2.34 when the BF content was 7.5 kg/m. NMR and CT test results show that there is a strong correlation between the BF morphological parameters and the distribution of pore structure in the concrete matrix. The overlapping contact of BF clusters led to the penetration of pores, which led the macro-pore proportion to increase dramatically. The increase in the macro-pore proportion is the main reason for the deterioration in concrete performance. In addition, these macro-pores may have adverse effects on the chloride ion permeability of BF concrete.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9029998 | PMC |
| http://dx.doi.org/10.3390/ma15082788 | DOI Listing |
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