排序方式: 共有104条查询结果,搜索用时 15 毫秒
41.
通过采用柔性加筋注浆技术处理台后回填土现场试验研究并结合室内试验的方式,研究了柔性加筋注浆新技术处理湘西红砂岩土石混填台背的施工工艺特性、加固实现机制和加固效果。现场试验及质量测试表明,水平柔性加筋注浆新技术处理湘西红砂岩土石混填台背施工工艺简单、加固效果良好,具有较好的开发应用价值。同时,现场试验过程取得大量施工参数和试验数据,为改进该新技术的设计计算及施工参数、完善施工工艺获得素材; 对有效预防和减少桥头跳车现象的发生,保证行车的舒适和安全也提供了可供选择的新方式。 相似文献
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盐腔内回填碱渣沉降固结特性室内试验研究 总被引:1,自引:0,他引:1
碱渣回填到充满卤水的废弃盐腔后,颗粒会自由沉降到盐腔底部形成沉积层,进而在自重作用下固结。为了解盐腔内回填碱渣的沉降固结特性,以江苏淮安地区碱渣为对象,进行了沉降柱试验和固结试验。试验结果表明:(1)碱渣在卤水中的沉降过程可以分为3个阶段:絮凝阶段、沉降阶段和固结阶段。初始浓度对碱渣的沉降曲线和沉降速率有很大的影响。(2)碱渣颗粒分布、密度、含水率和孔隙比均呈现出分层特性,颗粒粒径、密度随深度的增加而增大,含水率、孔隙比随深度的增大而减小。(3)碱渣具有很高的压缩性,压缩系数a1-2为3.36 MPa-1。在压力范围小于100 kPa下,固结系数随固结压力的增加而显著减小。试验结果对了解盐腔内回填碱渣的沉降固结特性提供了参考,有利于指导回填施工工艺和碱渣的后期处理。 相似文献
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The shear stress–strain behaviour and shear strength parameters of the interface between cemented paste backfill (CPB) and rock are of practical importance in the optimal and safe design of CPB structures. An understanding of the shear behaviour and properties at this interface is also required to develop comprehensive interface models for CPB-rock analyses, interface design methods for the static and dynamic stability analysis of CPB structures, and building high performance CPB structures. In this study, direct shear tests were conducted to investigate the interface shear strength behaviour between CPB and rock. All tests were carried out in a standard direct shear test apparatus for a range of curing ages of 1 to 28 days for the CPB. The procedures of the laboratory tests will be described. Results will be presented for interface shear behaviour, including stress–strain curves, vertical deformation and shear strength parameters. The test results show that the shear strength parameters and behaviour of the CPB-rock interface are time-dependent and significantly influenced by the normal load. 相似文献
44.
This paper reviews the design and application of paste backfill in underground hard rock mines used as ground support for
pillars and walls, to help prevent caving and roof falls, and to enhance pillar recovery for improved productivity. Arching
after stope filling reduces vertical stress and increases horizontal stress distribution within the fill mass. It is therefore
important to determine horizontal stress on stope sidewalls using various predictive models in the design of paste backfill.
Required uniaxial compressive strength (UCS) for paste backfill depends on the intended function, such as vertical roof support,
development opening within the backfill, pillar recovery, ground or pillar support, and working platform. UCS design models
for these functions are given. Laboratory and backfill plant scale designs for paste backfill mix design and optimization
are presented, with emphasis on initial tailings density control to prevent under-proportioning of binder content. Once prepared,
paste backfill is transported (or pumped) and placed underground by pipeline reticulation. The governing elements of paste
backfill transport are rheological factors such as shear yield stress, viscosity, and slump height (consistency). Different
models (analytical, semi-empirical, and empirical) are given to predict the rheological factors of paste backfill (shear yield
stress and viscosity). Following backfill placement underground, self-weight consolidation settlement, internal pressure build-up,
the arching effect, shrinkage, stope volume, and wall convergence against backfill affect mechanical integrity.
An erratum to this article can be found at 相似文献
45.
关于岩石蠕变特性的研究已有诸多成果,但对胶结充填体的蠕变特性还缺乏系统地研究。在室内充填体单轴蠕变试验的基础上,利用Hoek-Kelvin模型表征充填体的蠕变特性,运用粒子群优化算法,对选用的蠕变模型的参数进行辨识,并研究各蠕变参数对应力水平的敏感程度。研究结果表明,在不同分级应力水平加载下,弹性模量EH和黏滞系数η变化较小,而参数EK对应力水平变化较敏感。利用FLAC3D软件二次开发所建立的蠕变模型,用开发的模型进行分级加载蠕变的数值模拟,计算结果与试验数据吻合。 相似文献
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充填采矿法是现代矿山广为采用的高效无废采矿法,充填钻孔是充填系统的"咽喉"。充填钻孔的使用寿命因素除了输送介质的物理特性、系统的力学特性、管道材料特性外,钻孔偏斜等施工质量成为决定性因素。充填倍线指标是充填钻孔设计的主要依据。充填钻孔施工方法与工序质量控制是保证充填孔质量的关键。在分析了影响充填钻孔使用寿命因素和充填钻孔施工难点的基础上,总结和介绍了充填钻孔的施工方法和质量控制措施。 相似文献
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After placement of cemented tailings backfill (CTB), which is a mixture of tailings (man‐made soil), water, and binder, into underground mined‐out voids (stopes), the hydration reaction of the binder converts the capillary water into chemically bound water, which results in the reduction of the water content in the pores of the CTB, thereby causing a reduction in the pore‐water pressure in the CTB (self‐desiccation). Self‐desiccation has a significant impact on the pore‐water pressure and effective stress development in CTB and paramount and practical importance for the stability assessment and design of CTB structures and barricades. However, self‐desiccation in CTB structures is complex because it is a function of the multiphysics or coupled (i.e., thermal, hydraulic, mechanical, and chemical) processes that occur in CTB. To understand the self‐desiccation behavior of CTB, an integrated multiphysics model of self‐desiccation is developed in this study, which fully considers the coupled thermal, hydraulic, mechanical, and chemical processes and the consolidation process in CTB. All model coefficients are determined in measurable parameters. Moreover, the predictive ability of the model is verified with extensive case studies. A series of engineering issues are examined with the validated model to investigate the self‐desiccation process in CTB structures with respect to the changes in the mixture recipe, backfilling, and the surrounding rock and curing conditions. The obtained results provide in‐depth insight into the self‐desiccation behavior of CTB structures. The developed multiphysics model is therefore a potential tool for assessing and predicting self‐desiccation in CTB structures. 相似文献