尾矿储存设施远程监测的地球观测数据和卫星InSAR:以澳大利亚Cadia矿为例

Adam Thomas, S. Edwards, J. Engels, H. McCormack, V. Hopkins, R. Holley
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引用次数: 7

摘要

尾矿储存设施是矿物加工的重要基础设施,但它们具有重大的物理、化学和生物危害,因此必须严格和负责地选址、管理和关闭。例如,尾矿可以通过许多过程(如天坑、地震、强降雨和洪水事件以及风)、不合格的设计和施工以及渗漏来分散。需要持续监测卫星对地观测的稳定性和行为,而这样做的一个非常有效的方法是通过卫星对地观测。EO行业正在见证一场技术革命。大型和长寿命的卫星传感器一直是国家空间机构和商业卫星制造商的主要产品,现在,由那些雄心勃勃、每天拍摄整个地球的公司制造的低成本、短寿命的“立方体卫星”星座正在补充这些传感器。带有合成孔径雷达(SAR)传感器的卫星也在收集大量数据,其额外的好处是能够在白天或夜间以及不同的天气条件下这样做。这些数据选项和功能的范围为tsf提供了新的数据分析技术的开放机会。其中之一是卫星干涉SAR (InSAR);(一种用于绘制地表高度随时间变化的毫米精度图的技术),采矿公司已经使用这种技术来降低其运营中的风险。从监测tsf的稳定性到评估自然灾害的影响,InSAR可以快速准确地定位高风险地区和结构,以确定需要通过地基方法进行后续调查的地区和结构。为了展示EO数据和InSAR在识别破坏前后矿山活动和TSF变形方面的应用,作者将介绍澳大利亚新南威尔士州Cadia矿山的案例研究,该矿山于2018年3月9日发生了局部TSF破坏。InSAR结果表明,在坍塌前一年,整个TSF大坝都观测到了低震级的沉降信号。2018年1月,观测到明显的行为变化,下沉集中在2018年3月9日最初失败的区域。此外,崩塌后的InSAR测量显示,破坏区两侧的下沉速度增加。对中分辨率和高分辨率卫星图像的审查表明,故障是分阶段发生的,在2018年3月9日至少两天后发生了一次初始故障,然后又发生了一次后续故障。它还强调了在大坝坍塌之前可能与大坝抬升有关的建筑活动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Earth observation data and satellite InSAR for the remote monitoring of tailings storage facilities: a case study of Cadia Mine, Australia
Tailings storage facilities (TSFs) are an essential infrastructure of mineral processing, but they represent a significant physical, chemical and biological hazard and must, therefore, be strictly and responsibly sited, managed and closed. Tailings can, for example, be dispersed by many processes (such as sinkholes, earthquakes, intense rainfall and flood events, and wind), substandard design and construction, and seepage. The stability and behaviour of TSFs needs to be continuously monitored and one highly effective way of doing this is through satellite Earth observation (EO). The EO industry is witnessing a technological revolution. Large and long-lifespan satellite sensors that have been the staple of national space agencies and commercial satellite manufacturers are now being complemented by constellations of low-cost, short-lifespan ‘cube sats’ by companies with the ambition to image the whole earth daily. Satellites with synthetic aperture radar (SAR) sensors are also collecting high volumes of data, with the added benefit of being able to do so day or night and in different weather conditions. The range of data options and capabilities these provide open opportunities for novel data analysis techniques for TSFs. One of these is satellite InSAR (interferometric SAR; a technique used to map millimetric-precision changes in ground height over time), which is already used by mining companies to reduce risk in and of their operations. From monitoring the stability of TSFs, through to assessments of impacts of natural hazards, InSAR allows rapid and accurate targeting of high-risk areas and structures to identify those that require subsequent investigation through ground-based methods. To demonstrate the application of EO data and InSAR in identifying pre- and post-failure mine activities and TSF deformation, the authors will present a case study across Cadia mine, New South Wales, Australia, which had a localised TSF failure on 9 March 2018. The InSAR results presented show that low-magnitude subsidence signals were observed across the TSF dam during the year preceding the collapse. In January 2018 a notable change in behaviour was observed, with a concentrated area of subsidence focused on the region which initially failed on 9 March 2018. Furthermore, post-collapse InSAR measurements show an increased rate of subsidence for regions either side of the failure zone. Review of medium- and high-resolution satellite images show that the failure was phased, with an initial failure and then a subsequent failure at least two days after 9 March 2018. It also highlights what might be construction activity associated with a dam raise prior to failure.
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