深部矿山地热与煤炭资源协同开发技术体系研究

Collaborative mining system of geothermal energy and coal resources in deep mines

  • 摘要: 深部煤炭资源开采已势在必行,但随着开采深度的增加,伴生着热能的释放,该热能作为地热资源的重要组成部分,是一种不受环境因素影响的可再生清洁能源。深部矿井开采带来的丰富地热可作为共生资源进行开采利用。基于此,本文总结了深部矿井地热资源的发展潜力以及地热与煤炭资源开采的现状,论述了深部矿井地热开发的必要性和可行性,创新了地热与煤炭资源协同开发的思路,阐述了矿山地热与煤炭资源协同开发的内涵与科学问题,围绕深部矿山岩热和水热资源开发这一主题,利用煤炭资源开采的采后空间及生产系统,提出了充填埋管采热、采空区储水采热、采动区封闭采热及深部原位钻井采热4种采热方法,探讨了深部矿山地热探测评价、深部大空间煤基固废吸热功能材料、多场环境下采场岩层移动特征及其控制、低品位热能的高效传输及阶梯利用和协同开发系统智能监测等技术的研究重点与难点。研究成果将为中国深部矿山地热与煤炭资源的协同开发提供技术支撑,为深部矿井资源系统开发提供理论与实践参考,促进我国深部矿井绿色矿山建设与多元经济型发展。

     

    Abstract: Coal resources are non-renewable one-time energy. With the increase in mining depth, thermal energy is released with the exploitation of deep coal resources. It is renewable and clean, unaffected by environmental factors, and is an important part of geothermal resources. The Chinese government attaches great importance to and encourages the development and utilization of clean energy. Therefore, this paper summarizes the development potential of geothermal resources in deep mines and the current situation of geotherm and coal mining, discusses the necessity and feasibility of geothermal development in deep mines, innovates a collaborative mining of geothermal energy and coal resources, and expounds the scientific and technical problems of the coordinated development of geothermal and coal resources in mines. The scientific problems primarily include the distribution characteristics and the supply law of geothermal sources in deep mines, the law of energy conduction and evolution in stopes, and the heat and mass transfer mechanism of low-grade geothermal energy. The technical problems mainly include the optimization method of the system for the coordinated development of geothermal and coal resources in deep mines, the method for the coordinated development of geothermal and coal resources in deep mines, etc. Focusing on the theme of the development of rock heat and hydrothermal resources in deep mines and considering the post-mining space and production system, this paper introduces four heat recovery methods: buried pipe heat recovery method in the backfilled stopes, water storage and heat recovery method in the goaf, heat recovery method in the closed fracture and caving zones, and in-situ drilling for the heat recovery method in deep aquifers. Keys and difficulties of this paper include the detection and evaluation of geothermal energy in deep mines, heat-absorbing functional materials of coal-based solid waste in deep and large spaces, the characteristics and controlling methods of the rock stratum movement in a multi-field environment in mine stopes, efficient transmission and stepped utilization system of low-grade heat energy, and the intelligent monitoring of geothermal energy and coal collaborative mining system. The results of this paper will provide technical support for the collaborative mining of geothermal energy and coal resources in deep mines in China, as well as provide a theoretical and practical reference for the development of a deep mine resources system in China and promote the construction of green mines and multi-economic development of deep mines in China.

     

/

返回文章
返回