苏现波,赵伟仲,王乾,等. 煤矿采动影响体微生物采残煤与CO2−粉煤灰协同充填关键技术[J]. 煤炭学报,2024,49(1):400−414. DOI: 10.13225/j.cnki.jccs.YH23.0854
引用本文: 苏现波,赵伟仲,王乾,等. 煤矿采动影响体微生物采残煤与CO2−粉煤灰协同充填关键技术[J]. 煤炭学报,2024,49(1):400−414. DOI: 10.13225/j.cnki.jccs.YH23.0854
SU Xianbo,ZHAO Weizhong,WANG Qian,et al. Key technologies of microbial mining residual coal and CO2-fly ash co-filling in the impacted geological body of coal mining[J]. Journal of China Coal Society,2024,49(1):400−414. DOI: 10.13225/j.cnki.jccs.YH23.0854
Citation: SU Xianbo,ZHAO Weizhong,WANG Qian,et al. Key technologies of microbial mining residual coal and CO2-fly ash co-filling in the impacted geological body of coal mining[J]. Journal of China Coal Society,2024,49(1):400−414. DOI: 10.13225/j.cnki.jccs.YH23.0854

煤矿采动影响体微生物采残煤与CO2−粉煤灰协同充填关键技术

Key technologies of microbial mining residual coal and CO2-fly ash co-filling in the impacted geological body of coal mining

  • 摘要: 煤矿采空区是我国实现“双碳”目标的重要突破口,煤炭开采形成的、能够富集煤层气、为后期微生物活动和矿化充填提供底物和空间的地质体定义为采动影响体。以采动影响体为研究对象,提出了采动影响体微生物采残煤与CO2−粉煤灰协同矿化充填关键技术,并从必要性和可行性2个方面阐述了该技术在采动影响体资源二次开发、CO2安全封存以及燃煤电厂粉煤灰固废高效处置等的广阔前景。其总体思路是将采动影响体作为一个厌氧发酵“工厂”,高产高效产甲烷菌群作为“劳动者”对“工厂”已有的原材料——残煤、薄煤层和分散有机质以及注入的CO2进行加工,其“产品”是甲烷,进而实现微生物采残煤和CO2资源化。同时,CO2与碱性的粉煤灰结合,在实现了CO2矿化封存的同时,也实现了采动影响体的充填。该技术涉及的关键科学问题包括采动影响体类型划分与有机质特征、采动影响体原位条件下厌氧发酵产甲烷机制、微生物−CO2−粉煤灰协同矿化/固化机制以及微生物采残煤与充填关键技术示范工程建设。实验室物理模拟采动影响体原位条件实验表明其中残煤和富含有机质的泥页岩能够在微生物作用下生成生物甲烷,且添加少量的粉煤灰能够进一步强化甲烷的产出。物理模拟地下水补给的动态实验表明营养物质的补给对厌氧发酵系统的影响尤为重要,补给循环周期为14 d的厌氧发酵系统恰与产甲烷菌群繁殖的周期一致,能够保证厌氧发酵系统的持续高效运行。高钙粉煤灰−CO2−矿井水协同胶结的试件经过28 d的养护后抗压强度为12.31 MPa,其矿化封存潜力约为21.99 m3 CO2/t(粉煤灰),说明粉煤灰在实现采空区固化的同时能够实现CO2减排。此外,基于微生物采残煤与粉煤灰充填目的对工程试验靶区进行优选,地下水滞留区是CO2矿化和粉煤灰充填的最佳场所,因采掘活动自然形成的自然圈闭和人工充填形成的圈闭是较有利的工程试验靶区之一。针对这些靶区提出了微生物采残煤与CO2−粉煤灰协同充填关键技术,旨在为中国碳减排和采空区生态环境治理提供一条新的技术路径。

     

    Abstract: The gob of coal mine is an important area for achieving the goal of “dual carbon” in China. The geological body formed by coal mining, which can enrich coalbed methane and provide substrate and space for later microbial activities and mineralization filling is defined as the mining influence body. The proposed technologies include the residual coal extraction through mining influence body microorganisms and the co-mineralization and filling of CO2-fly ash. The broad prospects of the technology in the secondary development of mining, from the perspectives of necessity and feasibility, are elaborated upon regarding the safe storage of CO2 and efficient disposal of fly ash solid waste in coal-fired power plants. The overall concept is to utilize mining influence body as a anaerobic fermentation “factory” and microorganisms as “workers” to process the existing raw materials of the “factories”including residual coal, thin coal seams, dispersed organic matter, and injected CO2. The ultimate goal is to produce methane, thereby achieving the resource utilization of microbial mining for residual coal and CO2. The combination of CO2 and alkaline fly ash simultaneously achieves the mineralization storage of CO2 and the filling of mining influence body. The key scientific issues are involved in this technology encompass the classification of mining influence body and the characteristics of organic matter, elucidating the mechanism of anaerobic fermentation under in-situ conditions specific to mining influence body, investigating the cooperative mineralization mechanism of microbial-CO2-fly ash, as well as undertaking a demonstration project for constructing the key technology of microbial residual coal mining and filling. The laboratory physical simulation of the in-situ conditions of the mining influence body demonstrates that the residual coal and organic-rich mud shale have the capability to generate biomethane, with methane production further enhanced by a small quantity of fly ash. The dynamic experiment of simulated groundwater recharge demonstrates that the nutrient recharge significantly impacts the anaerobic fermentation system. Specifically, the system with a cycle period of 14 days was consistent with the cycle of methanogens, which can ensure the continuous and efficient operation of the anaerobic fermentation system. After a curing period of 28 days, the test specimen containing high calcium fly ash, CO2, and mine water exhibited a compressive strength of 12.31 MPa. Additionally, each ton of fly ash had the potential to store approximately 21.99 m3 of CO2 through mineralization, highlighting the dual benefits of CO2 emission reduction and goaf solidification achieved by utilizing fly ash. The engineering test target area was optimized based on the purpose of microbial coal residue mining and fly ash filling. Also, the groundwater retention area was identified as the optimal location for CO2 mineralization and fly ash filling. The natural trap formed by mining activities and the trap formed by artificial filling were one of the more favorable engineering test targets. The proposed technologies of microbial residual coal mining, CO2 and fly ash co-filling are aimed at providing a novel technical approach for carbon emission reduction and goaf ecological environment management in China.

     

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