冲积层中劈裂注浆现场模型试验

程盼; 邹金锋; 李亮; 罗伟; 赵炼恒; 赵娟

doi:10.3799/dqkx.2013.066

冲积层中劈裂注浆现场模型试验

doi: 10.3799/dqkx.2013.066

程盼^1,,
邹金锋¹,
李亮¹,
罗伟¹,
赵炼恒¹,
赵娟²

1.
中南大学土木工程学院, 湖南长沙 410075
2.
云南铜业三木矿业有限责任公司, 云南昆明 650041

基金项目:

国家自然科学基金项目 51078359

湖南省交通科技项目 201018

贵州省交通运输厅科技项目 2010-122-009

湖南省研究生科研创新项目 CX2011B098

详细信息

作者简介:
程盼(1985-), 男, 博士研究生, 主要从事隧道限排水和注浆工程方面的研究. E-mail: chengpan1020@163.com

中图分类号: TU472.6
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- 被引次数: 0
出版历程
- 收稿日期: 2012-07-19
- 刊出日期: 2013-05-15

Experiment of Fracture Grouting in Alluvium with Physical Model

1.
School of Civil Engineering, Central South University, Changsha 410075, China
2.
Yunnan Copper Group Sanmu Mining Industry Co., Ltd., Kunming 650041, China

摘要

摘要: 河流堤坝多位于深厚冲积层上, 而冲积层含砂石量大等特点对堤坝防渗、稳定性是不利的, 对堤坝进行注浆加固是必要的, 而研究浆液在冲积层中的分布扩散规律是首要任务.基于传统注浆理论, 通过现场注浆模型试验, 得出浆液在冲积层中的分布扩散规律、浆液劈裂机理、土的加固特性以及注浆加固过程中应注意的问题.指出浆液在冲积层中一般先沿土石分界面进行充填、劈裂, 并以水平向劈裂为主.在注浆过程中宜采用多次重复注浆方式以达到提高加固效果的目的.对冲积层中堤坝注浆加固有一定的参考与指导作用.
- 冲积层 /
- 模型试验 /
- 劈裂注浆 /
- 扩散分布规律 /
- 加固效果 /
- 工程地质
Abstract: Dams are mainly located at the deep alluvium, where large amount of sand and gravel is adverse to prevention of seepage and maintenance of stability of the dams. Therefore it is necessary to reinforce the dams by grouting, and the primary task is to do research on the laws of diffusion and distribution of the slurry in the alluvial layer. The present study is based on the traditional theory of grouting and the laws of diffusion and distribution of the slurry, the slurry splitting mechanism, the characteristics of soil reinforcement are obtained. In addition, it is found by on-site grouting model tests that the slurry is generally filling and splitting along the interface between the earth and rock, and mainly splitting in the horizontal direction in grouting reinforcement process. To improve the reinforcement effect, the repeated injection should be adopted in grouting process. The study results will facilitate future dam grouting reinforcement projects in alluvial layer.
- alluvium /
- model test /
- fracture grouting /
- regulation of diffusion and distribution /
- effect of reinforcement /
- engineering geology

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图 1 模型槽现场

Fig. 1. Model tank on-site

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图 2 注浆管及动力触探测点布置(单位：mm)

Fig. 2. The layout of grouting pipe and dynamic penetration test point

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图 3 注浆压力随时间变化

Fig. 3. Values of grouting pressure changed with time

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图 4 浆脉基本走向

Fig. 4. The basic trend of pulp veins

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图 5 开挖后填料中存留的劈裂缝

Fig. 5. The cleavage crack remained after the excavation

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图 6 轻型动力触探原位测试

Fig. 6. The result of light dynamic penetration test

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表 1 填料物理力学性质参数

Table 1. Physical mechanical parameters of fillers

项目指标	密度(g·cm^-3)	含水量(%)	孔隙比	C(kPa)	Φ(°)	压缩系数	压缩模量(MPa)
注浆前	1.99	12.7	0.380	42.5	35	0.20	6.65
注浆后上层土	2.10	10.4	0.325	64.4	35	0.12	10.96
注浆后下层土	2.10	12.5	0.350	57.3	33	0.13	10.28
注：压缩模量为100~200 kPa压力作用下所对应值.

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