Optimizing Aggregate Packing Density for Enhanced Compressive Strength in Biocemented Materials
Researchers significantly improved the compressive strength of biocemented materials by optimizing the packing density of aggregate mixtures. They employed the Modified Andreassen model to design an optimal particle size distribution curve, which was validated through compaction experiments. The optimized mix exhibited higher aggregate packing density during biomineralization, leading to reduced cementation solution consumption. Subsequently, an improved stop-flow pressure-based injection method was used for biomineralization experiments to investigate the impact of varying cementation solution pressure and concentration on biomineralization depth and compressive strength. Results showed that optimal UACP content, pressure, and concentration yielded high-strength, homogeneous biomineralized specimens, with a maximum compressive strength of 57.4 MPa – significantly exceeding previous studies. Lower flow rates and higher aggregate packing density were also found to be beneficial for achieving higher ultrasonic wave velocities and compressive strengths.