宽频超声激励煤体孔隙改性及其对瓦斯解吸行为的调控机理

Mechanism of coal pore modification induced by broadband ultrasonic excitation and its regulation on gas desorption behavior

  • 摘要: 超声激励可有效改造煤体孔隙结构,提升煤层气产能与可采储量。为探究宽频超声波对煤体跨尺度孔隙演化及瓦斯解吸特性的影响,利用水环境宽频超声波激励试验系统,研究了25.0~82.5 kHz范围内5种频率超声激励下2种高阶煤的跨尺度孔隙结构演变与瓦斯解吸扩散规律,阐明了孔隙结构的频率响应差异机制。结果表明:超声波频率对微孔与中孔的影响具有煤种依赖性。CS煤微孔结构在超声激励后无明显变化,但其中孔扩孔效应随频率升高而增强;XT煤则发生微孔选择性重构(部分0.48 nm孔隙合并扩大为0.56 nm孔隙),导致总微孔容和比表面积下降,削弱了CO2吸附能力,同时其中孔平均孔径增大、孔隙结构合并重组。XT煤微孔与中孔的改造效果均与超声频率呈正相关。超声激励还诱导大孔显著发育,其扩孔幅度随频率升高呈先减后增的“U形”关系。随平衡瓦斯压力增大,煤的瓦斯吸附量逐渐增加,且吸附量与频率的负相关性愈加显著。煤样的吸附常数a值随频率升高呈线性衰减,在82.5 kHz时相比原煤降幅最大(CS煤18.27%,XT煤18.72%);CS煤吸附常数b值随频率增加呈先减后增的“U形”关系,而XT煤的b值与频率无明显相关性,这源于2种煤原生孔隙结构的差异,但二者b值均在82.5 kHz处出现次高峰值;扩散系数随频率增大亦呈先减后增趋势,增幅达10.66%~35.01%。宽频超声波对煤体的作用耦合了机械振动与空化效应,实现了跨尺度孔隙结构的精准调控:微孔及中孔改造以机械效应主导,大孔改造则由空化效应主导。研究成果为低渗煤层“瓶颈”孔段的超声精准调控、多频协同联动高效改性等超声高效增渗技术提供理论支撑。

     

    Abstract: Ultrasonic excitation can effectively transform the pore structure of coal and increase coalbed methane production capacity and recoverable reserves. In order to explore the influence of broadband ultrasound on the cross−scale pore evolution and gas desorption characteristics of coal, the cross−scale pore structure evolution and gas desorption and diffusion laws of two high−rank coals under five frequencies of ultrasonic excitation in the range of 25.0−82.5 kHz were studied using a water environment broadband ultrasonic excitation test system, and the frequency response difference mechanism of the pore structure was clarified. The results show that the effect of ultrasonic frequency on micropores and mesopores is coal−type dependent. The micropore structure of CS coal did not change significantly after ultrasonic excitation, but the pore expansion effect increased with the increase of frequency; XT coal underwent selective reconstruction of micropores (some 0.48 nm pores merged and expanded to 0.56 nm pores), resulting in a decrease in total micropore volume and specific surface area, weakening the CO2 adsorption capacity, while the average pore size of the pores increased and the pore structure merged and reorganized. The transformation effect of micropores and mesopores in XT coal is positively correlated with the ultrasonic frequency. Ultrasonic excitation also induces significant development of macropores, and the pore expansion amplitude shows a “U−shaped” change with increasing frequency, which first decreases and then increases. With the increase of equilibrium gas pressure, the gas adsorption of coal gradually increases, and the negative correlation between adsorption and frequency becomes more and more significant. The adsorption constant a value of the coal sample decays linearly with increasing frequency, and the largest decrease is at 82.5 kHz compared with the original coal (CS coal 18.27%, XT coal 18.72%); the adsorption constant b value of CS coal shows a “U−shaped relationship” with increasing frequency, which first decreases and then increases, while the b value of XT coal has no obvious correlation with frequency, which is due to the difference in the primary pore structure of the two coals, but the b values of both appear at 82.5 kHz. The diffusion coefficient also shows a trend of first decreasing and then increasing with increasing frequency, with an increase of 10.66%−35.01%. The effect of broadband ultrasound on coal body couples mechanical vibration and cavitation effect, realizing the precise regulation of cross−scale pore structure: micropore and mesopore transformation is dominated by mechanical effect, while macropore transformation is dominated by cavitation effect. The research results provide theoretical support for ultrasonic high−efficiency permeability enhancement technologies such as ultrasonic precise control of the “bottleneck” hole section of low−permeability coal seams and multi−frequency synergistic linkage high−efficiency modification.

     

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