Contribution of temperature measurements to the hydrogeological model in the Snowy 2.0 deep tunnels

IF 1.3 4区 工程技术 Q3 ENGINEERING, GEOLOGICAL
A. Dematteis, M. Thüring, Francisco Alvarado, Gabriele De Carli
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引用次数: 0

Abstract

This paper refers to experiences developed on the deep tunnels design of the Snowy 2.0 pumped-storage hydroelectric project in NSW, Australia. The 27 km long waterway and the Power Station Complex are about 800 m below ground, and in a complex tectonic and lithological setting. Long-term temperature monitoring in boreholes has been used to infer an empirical thermal model along the deep tunnels, which is presented as an example of input data for the ventilation design during construction, and for durability design during operation. An innovative aspect of this paper is related to the graphical interpretative method of borehole temperature logs that is proposed to infer downward or upward groundwater flows and predict the hydrogeological behavior of fractured and faulted zones that cross the tunnel alignment. A large campaign of thermal acquisition boreholes, performed using an ATV probe, identified local anomalies of the geothermal gradient, which were correlated to permeability and pressure data measured in the boreholes, to identify zones of greater permeability that intersect the tunnels. Furthermore, the application of thermal measurements during tunnel excavation is proposed as an additional tool for the prediction of water inflow or identification of zones to be pre-grouted and/or drained. Thematic collection: This article is part of the Leading to Innovative Engineering Geology Practices collection available at: https://www.lyellcollection.org/topic/collections/leading-to-innovative-engineering-geology-practices
温度测量对Snowy 2.0深隧道水文地质模型的贡献
本文参考了澳大利亚新南威尔士州Snowy 2.0抽水蓄能水电站深洞设计的经验。27公里长的水道和发电站综合体位于地下约800米处,处于复杂的构造和岩性环境中。钻孔中的长期温度监测已用于推断深隧道沿线的经验热模型,该模型作为施工期间通风设计和运营期间耐久性设计的输入数据示例。本文的一个创新方面与钻孔温度测井的图形解释方法有关,该方法用于推断向下或向上的地下水流量,并预测穿过隧道线形的断裂带和断层带的水文地质行为。使用ATV探头进行的大规模热采集钻孔活动,确定了地热梯度的局部异常,这些异常与钻孔中测量的渗透率和压力数据相关,以确定与隧道相交的渗透率更高的区域。此外,建议在隧道开挖过程中应用热测量作为预测进水或识别待预灌浆和/或排水区域的额外工具。专题集:本文是“引领创新工程地质实践”系列的一部分,可在以下网站获取:https://www.lyellcollection.org/topic/collections/leading-to-innovative-engineering-geology-practices
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来源期刊
CiteScore
3.40
自引率
14.30%
发文量
66
审稿时长
6 months
期刊介绍: Quarterly Journal of Engineering Geology and Hydrogeology is owned by the Geological Society of London and published by the Geological Society Publishing House. Quarterly Journal of Engineering Geology & Hydrogeology (QJEGH) is an established peer reviewed international journal featuring papers on geology as applied to civil engineering mining practice and water resources. Papers are invited from, and about, all areas of the world on engineering geology and hydrogeology topics. This includes but is not limited to: applied geophysics, engineering geomorphology, environmental geology, hydrogeology, groundwater quality, ground source heat, contaminated land, waste management, land use planning, geotechnics, rock mechanics, geomaterials and geological hazards. The journal publishes the prestigious Glossop and Ineson lectures, research papers, case studies, review articles, technical notes, photographic features, thematic sets, discussion papers, editorial opinion and book reviews.
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