深地砂岩铀矿溶浸开采体系孔裂-渗流透明表征与定向干预研究进展  

作　　者：王雷鸣[1,2] 李硕 尹升华 成亮[1,2] 张超 陈威 薛森淼 WANG Leiming;LI Shuo;YIN Shenghua;CHENG Liang;ZHANG Chao;CHEN Wei;XUE Senmiao(Key Laboratory of the Ministry of Education of China for High-Efficient Mining and Safety of Metal Mines,University of Science and Technology Beijing,Beijing,100083,China;School of Civil and Resource Engineering,University of Science and Technology Beijing,Beijing,100083,China)

机构地区：[1]北京科技大学金属矿山高效开采与安全教育部重点实验室,北京100083 [2]北京科技大学土木与资源工程学院,北京100083

出　　处：《绿色矿山》2024年第4期381-396,共16页Journal of green mine

基　　金：国家自然科学基金面上资助项目(52374112);国家自然科学基金青年资助项目(52204124);北京市自然科学基金面上资助项目(2232080)。

摘　　要：天然铀作为关键的战略资源,在国防和能源领域具有重要意义。随着浅层资源的枯竭,深地战略成为保障资源安全的关键。砂岩铀矿溶浸开采是一种在天然条件下,通过注入溶浸液与矿石发生化学反应,将铀元素由固相转化为液相的采矿方法。地浸采铀具有低成本、短周期、管道化、无人化等优势,已在全球范围内得到应用。然而,深地砂岩溶浸开采面临着高井深、高地温、高地应力、强扰动的“三高一扰动”复杂环境,矿层孔裂结构的多尺度特性致使溶液渗流多级化,渗流路径复杂且均匀渗透困难。为了解决相关问题,研究人员在深地砂岩铀矿溶浸开采体系孔裂结构表征、渗流行为可视化及定向干预与宏观调控等方面开展了大量的研究工作。阐述了深地铀矿地浸体系孔裂-渗流透明表征与定向干预研究进展,其中孔裂结构透明表征主要分为物理表征方法与三维重建技术;渗流可视化技术包括渗流试验行为研究与透明岩石的制备,并介绍了数值模拟技术在渗流可视化中的应用;随后进一步探讨了深地铀矿地浸体系定向干预与调控机制,包括物理调控、生物化学调控和砂岩铀矿储层改造等策略。此类研究提高了铀矿的浸出效率,降低了开采对环境影响,推动了绿色可持续铀资源开发。最后提出深地砂岩铀矿溶浸开采体系孔裂-渗流透明表征与定向干预研究瓶颈难题,并展望未来研究需要进一步深化对深地砂岩铀矿溶浸开采机理的认识,优化和完善孔裂结构透明表征与渗流行为可视化技术,创新出更为高效与环境友好的定向干预与调控策略。Uranium,as a pivotal strategic resource,holds significant importance in the fields of national defense and energy.With the depletion of shallow resources,the deep earth strategy emerges as a crucial means to ensure resource security.Sandstone uranium ore leaching mining,a method that harnesses natural conditions by injecting leaching solutions to chemically react with ores,transforming uranium from solid phase to liquid phase,has garnered global attention due to its advantages of low cost,short cycle time,pipelining,and unmanned operation.Nevertheless,deep sandstone uranium leaching confronts the"three highs and one disturbance"complex environment of high well depth,high geothermal temperature,high geostress,and intense disturbance,where the multi-scale nature of ore layer pore-fracture structures leads to multi-stage solution seepage,intricate seepage paths,and difficulties in uniform permeation.To tackle these challenges,researchers have extensively delved into pore-fracture structure characterization,seepage behavior visualization,as well as targeted intervention and macro-control in deep sandstone uranium mines.This paper delves into the current research status of pore fracture-seepage transparency characterization and directional intervention in the in-situ leaching system for deep uranium mining.Specifically,the transparency characterization of pore fracture structures is primarily categorized into physical characterization methods and 3D reconstruction technologies.The visualization of seepage processes encompasses studies on seepage experimental behaviors,the preparation of transparent rocks,and the application of numerical simulation techniques in enhancing seepage visualization.Furthermore,the paper explores the mechanisms of directional intervention and regulation within the in-situ leaching system for deep uranium mining,encompassing strategies such as physical control,biochemical regulation,and sandstone uranium reservoir modification.These research efforts have significantly improved uranium leachin

关 键 词：深地砂岩铀矿 溶浸开采 孔裂结构 渗流行为 透明表征 定向干预 

分 类 号：TD712[矿业工程—矿井通风与安全]