Enhanced coalbed methane recovery by microwave-induced thermal fracture

Song Wu, Shen Li, Shuxia Yuan, Bintao Guo and Quansen Niu
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Abstract

The investigation on microwave-induced permeabilization and response of coal under microwave heating is of great significance for the industrial application of microwave heating technology instead of traditional heating in coalbed methane mining. Santanghu coal is used as a sample to measure the permeability and porosity of coal samples before and after microwave heating. The fracture changes of coal samples before and after heating are compared to observe the penetration effect of microwaves on coal samples. Based on the technology of directional drilling and continuous tubing technology in petroleum engineering, a technology of increasing the production of coalbed methane by microwave heating in a wide range of coal seams is proposed. The feasibility of this enhanced production method is validated through COMSOL Multiphysics simulations, which model the temperature field distribution within coal seams under various microwave parameters. This approach highlights the potential of microwave technology in coalbed methane recovery. The results show that: (1) the thermal field of coal samples under microwave heating is inhomogeneous. The average length and area of the cracks of the coal samples increased under microwave radiation, and the cracking of the coal samples confirmed the cracking effect of microwaves on the coal samples. (2) With prolonged microwave heating, coal samples exhibit an initial decrease followed by an increase in porosity and permeability, a trend attributed to the expansion of solid particles that occupy and reduce pore spaces. (3) The in-situ microwave heating technique for coalbed methane extraction overcomes the challenges of long-distance microwave transmission loss and methane backflow in transmission pipelines, utilizing continuous pipelines for extensive microwave heating of coal seams. (4) The microwave power and intermittent heating duration have a significant effect on the temperature field distribution of the coal seam, and when the heating duration is 60 days, 1600 W is used to have an effective temperature field distribution while avoiding the waste of heat. When the power is constant at 1600 W, the effective temperature range is wider when the intermittent heating duration is 60 days.
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通过微波诱导热裂缝提高煤层气回收率
研究微波加热下煤炭的透气性和响应,对于在煤层气开采中以微波加热技术替代传统加热技术的工业应用具有重要意义。以三塘湖煤为样品,测量煤样在微波加热前后的透气性和孔隙度。对比煤样加热前后的断裂变化,观察微波对煤样的穿透效果。以石油工程中的定向钻井技术和连续油管技术为基础,提出了在大范围煤层中通过微波加热提高煤层气产量的技术。通过 COMSOL 多物理场仿真,模拟了不同微波参数下煤层内的温度场分布,验证了这种增产方法的可行性。这种方法凸显了微波技术在煤层气回收中的潜力。结果表明(1) 煤样在微波加热下的热场是不均匀的。煤样裂纹的平均长度和面积在微波辐射下增加,煤样的裂纹证实了微波对煤样的裂纹效应。(2)随着微波加热时间的延长,煤样的孔隙率和透气性先下降后上升,这种趋势归因于固体颗粒的膨胀占据并减少了孔隙空间。(3) 煤层甲烷抽采的原位微波加热技术克服了长距离微波传输损耗和甲烷在传输管道中倒流的难题,利用连续管道对煤层进行大范围微波加热。(4)微波功率和间歇加热时间对煤层的温度场分布有显著影响,当加热时间为 60 天时,采用 1600 W 的微波功率可获得有效的温度场分布,同时避免热量浪费。当功率恒定为 1600 W 时,当间歇加热持续时间为 60 天时,有效温度范围较宽。
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