How the Pressure Build-Up Affects the Penetration Length of Grout-New Formulation of Radial Flow of Grout Incorporating Variable Pressure

J. Funehag, J. Claesson
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引用次数: 1

Abstract

For around two decades of research and development in the field of grouting in hard jointed rock, the design process has taken some leaps forward. Stille and Gustafson, 2005 and Funehag and Gustafson 2008, shows how a grouting design can be computed. A grouting design in hard rock can based on the penetration length of grout in rock fractures. The design comprises considerations of the fracture apertures in the rock mass, the type of grout and its rheological properties and how the grout is injected i.e pressure and grouting times. When knowing these parameters an optimized geometry fitting the design is made. Thorn, et al, 2014 describes a fundamental analysis with a comprehensive tool to retrieve the fracture distribution and aperture distribution of the fractures crossing a cored borehole. The data needed about the core is geological mapping and hydraulic section tests. In Gustafson, Claesson and Fransson, (2013) a full derivation of a radial Bingham flow in a slit is described for constant pressure. By optimizing with a specific pressure and an efficient grouting time (efficient time means the time when the pressure has reached the designed pressure) a prognosis a more realistic time consumption for grouting can be computed. However, the time it takes to reach a certain pressure is dependent on the capacity of the pump and the how large the fractures widths are. For poorly chosen pumps together with large fractures the time to reach the design pressure can be significant. The overall objective for this new formulation was to involve the grouting pressure as a variable rather than constant. A pressure build-up mimic more a realistic pumping scenario which enables better prognosis of grouting works. This paper brings up this new formulation of the radial Bingham flow with variable injection pressure in slit. The benefits of this new formulation is that it can easily be integrated in other computer programs. One program that uses this new formulation is a grouting simulator owned and developed by Edvirt AB. The simulator has been used to pedagogically demonstrate how a variable pressure and restrictions in grout flow (the pump capacity) affect the penetration length. Further, the results show that it can be used to predict suitable pump capacity to fit the coming grouting works.
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压力积聚如何影响浆液侵彻长度——变压力浆液径向流动新公式
在硬节理岩体注浆领域,经过近二十年的研究和发展,设计过程取得了长足的进步。Stille and Gustafson(2005)和Funehag and Gustafson(2008)展示了如何计算注浆设计。可根据岩体裂隙中浆液的侵彻长度进行硬岩注浆设计。该设计包括考虑岩体的裂缝孔径、注浆类型及其流变特性以及注浆方式(即压力和注浆时间)。当知道这些参数后,就进行了优化的几何拟合设计。Thorn等人,2014年描述了一种基本分析方法,该方法使用一种综合工具来检索穿过取心井眼的裂缝分布和裂缝孔径分布。岩心所需的资料是地质填图和水力断面试验。在Gustafson, Claesson和Fransson,(2013)中,描述了恒定压力下狭缝中径向宾厄姆流的完整推导。通过对特定压力和有效注浆时间(有效时间是指压力达到设计压力时的时间)进行优化,可以预测出更符合实际的注浆时间。然而,达到一定压力所需的时间取决于泵的容量和裂缝宽度的大小。对于选择不当的泵和大裂缝,达到设计压力的时间可能很长。这个新公式的总体目标是将注浆压力作为一个变量而不是常数。压力累积模拟更真实的泵送场景,可以更好地预测注浆工程。本文提出了缝内变注入压力径向宾厄姆流动的新公式。这种新公式的好处是它可以很容易地集成到其他计算机程序中。使用这种新配方的一个程序是由Edvirt AB拥有和开发的注浆模拟器。该模拟器已用于教学演示如何改变压力和注浆流量的限制(泵容量)影响渗透长度。结果表明,该模型可用于预测合适的灌浆能力,以适应即将到来的灌浆工程。
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