Study and Microanalysis on the Effect of the Addition of Polypropylene Fibres on the Bending Strength and Carbonization Resistance of Manufactured Sand Concrete

• Published in: Polymers Vol. 15; no. 9; p. 2139
• Main Authors: Tan, Yan, Ma, Chong, Zhao, Ben, Xiong, Wei, Chen, Xingxiang, Yu, Jiangtao
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 29.04.2023; MDPI
• Subjects: Bend strength; bending strength; Business metrics; Calcium carbonate; Carbon dioxide; Carbonization; carbonization depth prediction model; carbonization resistance; Cement; Composite materials; Concrete; Concrete mixing; Crack propagation; Curing; Erosion resistance; Factorial design; Fiber reinforced concretes; Fiber reinforced polymers; manufactured sand concrete; Mathematical models; Mechanical properties; Microstructure; Phase composition; Photomicrographs; Polypropylene; polypropylene fibre; Polyvinyl alcohol; Prediction models; Response surface methodology; response surface model; Sand; Sand & gravel; Sand, gravel and stone industry; Scanning electron microscopy; Stone & clay industries; Storage modulus; Stress concentration; X-ray diffraction; China; manufactured sand concrete; polypropylene fibre; carbonization depth prediction model; bending strength; carbonization resistance; response surface model
• ISSN: 2073-4360; 2073-4360
• DOI: 10.3390/polym15092139

To popularize the complete replacement of natural sand with manufactured sand, a study was performed to determine the effect of adding polypropylene fibres (PPFs) to increase the bending strength and carbonization resistance of manufactured sand concrete (MSC). A 2 × 3 factorial design with the content and length of PPF as variables was used to establish a carbonization depth prediction model and a response surface model (RSM). The phase composition and microstructure of polypropylene-fibre-reinforced manufactured sand concrete (PPF-MSC) were analysed using X-ray diffraction (XRD) and scanning electron microscopy (SEM). The results show the addition of PPF with different contents and lengths increases the bending strength of PPF-MSC to varying degrees, while reducing the carbonization depth and increasing the dynamic elastic modulus after 28 days of carbonization. The highest bending strength (6.12 MPa) and carbonization resistance of PPF-MSC are obtained by the addition of 1 kg/m of 12 mm PPF, while the carbonization depth and an increase in the dynamic elastic modulus after 28 days of carbonization are maintained at a minimum of 2.26% and 1.94 mm, respectively. A prediction model was established to obtain a formula for the PPF-MSC carbonization depth in terms of the content and length of PPF and the carbonization time. The following results were obtained from the RSM: compared to the PPF length, the PPF content has a larger impact on the PPF-MSC bending strength and a smaller impact on the PPF-MSC carbonization resistance; there is no significant interaction between the content and length of PPF; and the predicted and measured values are close, indicating that the model is highly reliable. A comparison of the XRD patterns and SEM micrographs of PPF-MSC and MSC after 28 days of carbonization show a lower peak intensity of CaCO in the pattern for the carbonized area for PPF-MSC than for MSC and considerably fewer surface pores and cracks in PPF-MSC than in MSC. These results indicate that the addition of PPF increases the compactness of MSC and creates an effective resistance to the erosion by water molecules and carbon dioxide (CO ), thus enhancing the bending strength and carbonization resistance of MSC.