高压条件下间断级配珊瑚砂–砾混合料力学特性与颗粒破碎研究

doi:10.3724/1000-6915.jrme.2025.0821

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摘要南海岛礁吹填地基中的珊瑚砂地基粒组多样，局部地层呈现出砂–砾混合状态。通过开展多组高压排水三轴剪切试验，分析在不同围压、含砾量、相对密度条件下，均匀级配和间断级配珊瑚砂–砾混合料的颗粒破碎及剪切特性。试验结果表明，含砾量与密实度对剪切强度有显著影响。在低围压下主应力–轴向应变曲线的初始斜率较为陡峭，但随围压升高趋于平缓，峰值主应力比随有效围压增加呈递减趋势。在高压下体变呈现剪缩趋势，且随围压增大而增强。试样的内摩擦角随相对密实度的提高而增大，当砾石含量为25%时达到最大值，同时对应的表观黏聚力最小。颗粒破碎程度随围压的增大而增强，粒径分布演化呈现先陡后缓的变化规律。此外，峰值主应力比随着相对破碎指数的增加而逐渐减小。通过幂函数建立了峰值滑动摩擦角与相对破碎指数的关系。最后通过对珊瑚砂–砾混合料在高压下的应力–剪胀关系研究，揭示了高压与低压情况下含砾量对剪胀关系的影响，研究结果为岛礁吹填地基建设提供理论参考。

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	吴杨1
	王传智1
	张涛2*
	李能1
	崔杰1

关键词 ：土力学, 珊瑚砂&ndash, 砾混合料, 高压三轴, 颗粒破碎, 含砾量, 峰值滑动摩擦角

Abstract：The coral sand foundations in dredged and reclaimed foundations of South China Sea islands exhibit complex gradation characteristics, with localized strata presenting a sand-gravel mixture. This study investigates the particle breakage and shear characteristics of uniformly graded and gap-graded coral sand-gravel mixtures through a series of high-pressure drained triaxial tests. Experiments were conducted under varying confining pressures, gravel contents, and relative densities. Results demonstrated that gravel content and density significantly influenced the shear strength. Under low confining pressures, the stress-strain curves showed a steeper initial slope, which gradually moderated as the confining pressure increased. The peak principal stress ratio decreased with increasing effective confining pressure. Volumetric strains under high pressures exhibited contractive behavior, intensifying with higher confining pressures. The internal friction angle increased with relative density, peaking at 25% gravel content, while the corresponding apparent cohesion was minimized. Particle breakage intensified with rising confining pressure, and the evolution of particle size distribution followed a pattern characterized by an initially rapid transition followed by gradual stabilization. Furthermore, the peak principal stress ratio decreased progressively with an increase in the relative breakage index. A power function relationship is established between the peak mobilized friction angle and the relative breakage index. Finally, analysis of the stress-dilatancy relationship under high pressure revealed distinct mechanisms of dilatancy behavior under high- versus low-pressure conditions, highlighting the significant impact of gravel content. These findings provide theoretical support for the design and construction of dredged foundation engineering in island and reef environments.

Key words： soil mechanics coral sand-gravel mixtures high pressure triaxial test particle breakage gravel content peak mobilized friction angle

引用本文:

吴杨1，王传智1，张涛2*，李能1，崔杰1. 高压条件下间断级配珊瑚砂–砾混合料力学特性与颗粒破碎研究[J]. 岩石力学与工程学报, 2026, 45(6): 1869-1879.
WU Yang1, WANG Chuanzhi1, ZHANG Tao2*, LI Neng1, CUI Jie1. Mechanical behavior and particle breakage of gap-graded coral sand-gravel mixtures under high pressure. , 2026, 45(6): 1869-1879.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0821 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I6/1869

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