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11.
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
12.
Cemented paste backfill (CPB) is a mixture of dewatered tailings, hydraulic binders and water. In addition to contributing to the stability of mine workplaces, CPB greatly benefits the environment by minimizing surface tailings disposal. Hence, it has become one of the most commonly used ways in mine backfilling around the world. Temperature can significantly affect the mechanical properties of cemented backfill. A source of heat in CPB is produced by binder hydration. Hence, a FLAC based numerical model is developed to predict and analyse the heat developed by hydrating CPB structures. To validate the model, results of the developed model are compared with three case studies (mathematical, laboratory, and field investigations). The validation results show a good agreement between the developed model and these cases. The effects of stope geometry, thermal properties of both rock and CPB, filling rate, binder content and initial boundary conditions are also investigated. 相似文献
13.
下向分层进路充填采矿法中,进路充填顶板的稳定对回采过程安全性至关重要,而分层充填体叠加载荷计算一直是顶板稳定性分析的难点。在充分考虑采动岩体荷载、矿体倾角、相邻分层间回采进路的交错布置、充填体与围岩的接触等工程实际后,推导了进路顶板平衡微分方程,求解得到进路顶板静荷载的理论值。结合回采工艺建立了“多跨梁”力学模型,并得到了回采进路顶板拉应力的理论计算公式,分析得到影响进路顶板稳定性的4个重要理论因素:顶板上部载荷σ v、回采进路跨度l、1:4充填体的厚度h、充填体自身抗拉强度[σt]。为充分考虑进路顶板静载荷和回采爆破动载荷影响,利用FLAC3D对多因素影响下的顶板稳定性进行了数值模拟正交计算。根据模拟结果,分析了各因素对顶板拉应力的影响规律,利用多元非线性回归的方法建立了多因素组合影响下顶板稳定性评价模型。该模型应用到某铜矿试验采场的实际生产,具有较好的指导作用。 相似文献
14.
布筋尾砂胶结充填体顶板力学性状试验研究 总被引:4,自引:0,他引:4
胶结充填体顶板的稳定性是决定下向分层胶结充填回采断面尺寸的主要因素,结合武山铜矿工程实际,采用相似模拟与现场监测手段,研究了下向分层胶结充填法充填体顶板的破坏模式、变形特征、充填体内钢筋受力特征等。相似模拟试验结果表明,钢筋布置方式不影响顶板的最终破坏形式,竖直布置钢筋与水平布置钢筋相比,更有利于提高顶板整体稳定性。应变监测结果表明,充填体顶板应变状态十分复杂,与通常将下向胶结充填体顶板简化为梁的计算结果有较大不同,垂直方向上应变表现为拉伸应变,而沿分条和垂直分条方向应变均呈现拉、压交错变化。在竖直布置的8根钢筋上布置了24个钢筋测力计,得到了钢筋受力与开采时间的关系曲线,据此将钢筋受力划分为4个阶段,即起始受拉阶段、相对稳定阶段、拉压变化阶段、承载阶段,其中承载阶段钢筋首先承受最大压力,充填体暴露为顶板后,钢筋由受压状态变为受拉状态,并急剧上升到最大拉力,即表现出悬吊作用,并且,进路与分条连接处钢筋承受拉力最大。 相似文献
15.
在胶结充填采矿法中,胶结充填体弹性系数和其不接顶高度是空区顶板安全的重要影响因素。基于柔性支护原理,把顶板变形分为两个阶段:顶板在覆岩自重应力作用下产生挠曲变形;顶板与胶结充填体接触后共同承载顶板覆岩自重应力;并据此分别建立了力学模型。以广西盘龙铅锌矿为工程分析实例,研究在不同胶结充填体弹性系数和不接顶高度条件下顶板挠度的变化规律。结果表明:当胶结充填体弹性系数k≥0.1 GN/m3时,不接顶高度h是影响顶板挠度的主要因素,当胶结充填体弹性系数k较小时,弹性系数k是影响顶板挠度的主要因素;当k≥0.1 GN/m3且h≤300 mm时,胶结充填体能有效控制顶板岩层移动和降低储存在其中的应变能。现场勘探结果与理论计算基本吻合,验证了研究成果的可靠性。 相似文献
16.
Martin Fahey Matthew Helinski Andy Fourie 《Geotechnical and Geological Engineering》2011,29(5):709-723
Paste backfill used to provide ground support in underground mining is generated from full-stream tailings and is almost always
placed underground with cement. For the backfill, both the rate of strength development and the final strength are important
considerations for design, particularly when the backfill is subsequently exposed in the stope-mining sequence. There is strong
evidence that strengths measured on specimens obtained from coring the in situ cemented backfill are much greater than laboratory-cured
specimens with the same cement content. The paper reviews some of the experimental evidence showing that one of the major
reasons for the different strength is the difference in effective stress acting on the backfill during curing. Laboratory
specimens are (almost) always cured under zero total stress, so no effective stress develops. In contrast, backfill in a stope
may cure under high effective stress, which develops due to either “conventional” consolidation in free-draining backfills,
or to the so-called “self-desiccation” mechanism in fine-grained fills. Evidence is presented showing how the final strength
is affected by applying stress to specimens at different stages of curing and at different rates. It is shown that a fully-coupled
analysis of the filling behaviour is required to determine the appropriate effective stress regime to apply in curing laboratory
specimens, where “fully-coupled” in this context means taking account of the interaction of consolidation/drainage rate, filling
rate and cement hydration rate. Curing protocols for laboratory specimens are proposed, which would ensure that the strengths
obtained are representative of in situ conditions. 相似文献
17.
充填法采矿是维护矿山稳定、控制地压变化以及限制围岩变形的最有效的手段方法,这种方法被大量地应用于金属矿山的开采工程当中。充填体作为矿体采出后的替代物,充入地下采空区后经过相变-固结-承压-提供反力-与围岩相互作用等阶段,与上覆岩层、下部矿体以及周围围岩形成了一个共同抵抗外部压力又相互作用的系统。这个系统在矿山开采状态下如何维护自身稳定以及相互作用所产生的变形破坏等都是需要进行研究的问题。金川镍矿二矿区已经进行了几十年的充填开采作业,逐渐形成了体积非常巨大的充填体,而进入深部开采工程后,上覆巨大充填体的受力稳定问题直接关系到矿山的安全生产。本文结合金川二矿区开采实际,在精确刻画充填体三维形态特征的基础上,采用数值模拟方法分析了大型充填矿山充填体的力学行为。模拟结果表明:充填体在开采时会出现整体受压变形,最大剪应力是导致充填体与围岩发生局部破坏的主要因素,对此根据充填体整体塑性屈服区域的分布和剪应力分布情况,确定了破坏失稳的危险区域。 相似文献
18.
A fully coupled multi-physics finite element model has been used to conduct a back-analysis of a stope filling case history at the Kanowna Belle (KB) mine in Western Australia. The model captures a number of important characteristics of mine backfill behaviour, including the evolution of strength and consolidation properties with cement hydration, the impact of chemical shrinkage (self-desiccation) and de-saturation. Material parameters for the constitutive model have been calibrated using published laboratory test data. A reasonable match between ideal and actual elements of response as revealed through in-situ measurements of total stress and pore pressure was obtained using these initial parameters. A parametric study was then performed which showed that the backfill strength parameters (friction angle, dilation and cohesion), the chemical volume shrinkage, the rate of cement hydration and the water retention properties all have a significant influence on the calculated states of stress within the stope. 相似文献
19.
基于国内外研究现状和岩质滑坡案例,总结出岩质滑坡的水力致灾机制,归纳考虑水力作用下的岩质斜坡主要失稳破坏模式,评述了岩质斜坡稳定性分析方法。岩质滑坡的水力致灾机制主要由于水对滑体产生的静水压力(岩体侧面的推力、滑面的扬压力和岩体的浮力)和动水压力(向坡外的渗透力)作用。从渗流—应力耦合的角度可较全面评价水渗流对坡体稳定性的影响。斜坡的岩体结构决定了水力作用方式和坡体的失稳破坏形式,考虑水力作用下的岩质斜坡失稳破坏形式主要有:顺层滑动、平推式滑动、楔形体滑移和危岩的崩塌。对于水力作用下岩质斜坡的稳定性分析方法主要有极限平衡法、有限元强度折减法、基于断裂力学的危岩稳定性分析法和渗流—应力耦合模型分析法,其中前两种方法应用较为广泛。 相似文献
20.
Mining backfill is commonly used in underground mines. A critical concern of this practice is to evaluate the pressures and total stresses in backfilled stopes to ensure a safe and economic design of barricades, constructed to retain the backfill. When a slurried backfill is placed in a mine stope, excess pore water pressure (PWP) can instantaneously generate and progressively dissipate. The dissipation of the excess PWP and consolidation lead to the development of effective stresses, which in turn lead to an arching effect in the backfilled stope. Until now, arching effect has been largely considered for stress estimation in dry or submerged backfill. The former corresponds to the final state at the end process of the drainage and consolidation of the backfill with a pervious while the latter with an impervious barricade. However, previous studies have shown that the most critical moment for the stability of barricades is during the stope filling. Therefore, the design of barricades requires a proper estimation of the pressure and total stresses during the filling operation. This in turn needs joint consideration of the arching effect and consolidation of the backfill. In this paper, a new solution is developed to evaluate the pressures and stresses in backfilled stopes during the filling operation of cohesionless backfill by considering the self-weight consolidation and arching effect. The proposed solution is validated by numerical modeling with Plaxis2D. It can thus be used to evaluate the pressures and stresses in backfilled stopes during the stope filling with an impervious barricade. 相似文献