普朗铜矿区冰碛物重塑样工程力学性能试验研究

    EXPERIMENTAL STUDY ON ENGINEERING MECHANICAL PROPERTIES OF MORAINE RESHAPED SAMPLE IN PULANG COPPER MINE AREA

    • 摘要: 为有效防治普朗铜矿井下泥石流灾害,实现地表冰碛物注浆固结改性,开展地表冰碛物工程力学性能研究。采用小型直剪仪与大型粗粒土直剪仪相结合的方式,研究了不同粒级组成时冰碛物试样的抗剪强度、黏聚力c、内摩擦角φ的变化规律,采用土骨架理论与Mohr-Coulomb准则对其强度机制进行分析。结果表明:随着粒径的增加,试样的黏聚力c先降低后增加,内摩擦角φ呈指数型增长;冰碛物试样为弹-塑-蠕性体,随着粒径及垂压的增加,剪应力-应变曲线随垂压的增加由应变微软化转变为显著应变软化;随着粒径增加,试样承载结构逐渐由细颗粒为主的镶嵌结构转变为粗颗粒为主的骨架结构;粗颗粒对试样抗剪强度影响逐渐提高,试样抗剪强度从以黏聚力为主转变为以摩擦力为主。

       

      Abstract: To support debris-flow disaster prevention and surface moraine modification by grouting consolidation in the Pulang Copper Mine, this study investigated the engineering mechanical properties of surface moraine. Shear strength, cohesion(c), and internal friction angle(φ)of moraines with different grain-size compositions were examined using a combination of small direct-shear apparatus and large-scale direct-shear equipment for coarse-grained soils. Soil skeleton theory and the Mohr-Coulomb criterion were applied to analyze the strength mechanism. The results show that as particle size increases, cohesion c first decreases and then rises, while the internal friction angle φ increases exponentially. The moraine samples exhibit elastic-plastic-creep behavior. Moreover, an increase in particle size and vertical pressure shifts the shear stress-strain curve from slight hardening to stress softening. As particle size increases, the load-bearing structure of the sample transitions from a fine-particle-dominated mosaic structure to a coarse-particle-controlled skeleton structure. Coarse particles progressively govern the shear strength of the sample, shifting the dominant resistance from cohesion-based to friction-based.

       

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