Response Patterns of Acoustic Wave Characteristics to Reservoir Petrophysical Parameters in Different Bedding Directions: A Case Study of Low- and Middle-Rank Coals in Xinjiang, China

IF 3.7 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY ACS Omega Pub Date : 2024-09-19 DOI:10.1021/acsomega.4c05176
Liang Du, Chao Jia, Haichao Wang, Pichen Sun, Yifan Chen, Hongmei Su, Chuanjian Cheng, Xuchao Huang, Zhengshuai Wang, Peng Lai, Bo Wang, Zhenpeng Hu
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Abstract

The physical properties of coal reservoirs, important parameters for evaluating the production potential of coalbed methane (CBM) resources, can be assessed nondestructively and in real-time using acoustic wave technology. In this study, we collected 48 low- and middle-rank coal samples oriented in different bedding directions from seven typical coal mines, encompassing the Zhunan, Tuha, and Kuqa-Bay coalfields in Xinjiang, China. We clarified the characteristics of the physical parameters (apparent density, fracture, porosity, and permeability) and acoustic wave of coal variations through acoustic wave, porosity, and permeability experiments, revealing the response law of acoustic wave characteristics to the physical parameters of coal. The results indicated that the acoustic wave velocity and dynamic elastic modulus (Ed) of coal samples oriented in the perpendicular bedding direction are larger than those oriented in the parallel bedding direction; however, the dynamic Poisson’s ratio (μd) of coal samples oriented in different bedding directions does not significantly differ. The existence of fractures significantly reduces the acoustic wave velocity and Ed of the coal. The greater the apparent density of coal, the tighter its structure, resulting in a faster acoustic wave velocity. The larger the porosity of coal, the greater its internal voids, leading to a more pronounced attenuation of acoustic energy and a slower acoustic wave velocity. The more developed and interconnected the bedding fractures of coal bodies oriented in the parallel bedding direction, the higher their permeability, resulting in a smaller decrease in acoustic wave velocity. Conversely, the more developed the bedding fractures of coal bodies oriented in the perpendicular bedding direction, the more pronounced their attenuation of acoustic wave velocity. Finally, the regression equations for Ed with the square of P-wave velocity (VP2) and μd with the square ratio of VP to S-wave velocity (VP2/VS2) were established for coal. The study findings can help evaluate and predict the reservoir quality of coal seams, assess CBM, and improve the safety and efficiency of its extraction.

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不同埋藏方向声波特征对储层岩石物理参数的响应模式:中国新疆中低阶煤案例研究
煤储层的物理性质是评估煤层气(CBM)资源生产潜力的重要参数,利用声波技术可以对煤储层的物理性质进行非破坏性的实时评估。在这项研究中,我们从中国新疆竹南煤田、吐哈煤田和库车湾煤田等 7 个典型煤矿采集了 48 个不同层位方向的中低阶煤样。通过声波、孔隙度和渗透率实验,阐明了煤的物理参数(表观密度、断裂、孔隙度和渗透率)和声波的变化特征,揭示了声波特征对煤的物理参数的响应规律。结果表明,垂直层理方向煤样的声波速度和动态弹性模量(Ed)均大于平行层理方向的煤样;但不同层理方向煤样的动态泊松比(μd)无明显差异。裂缝的存在大大降低了煤的声波速度和 Ed 值。煤的表观密度越大,结构越紧密,声波速度越快。煤的孔隙率越大,内部空隙越大,导致声能衰减越明显,声波速度越慢。煤体在平行层理方向上的层理裂隙越发达、越相互连接,其渗透率就越高,从而导致声波速度的下降幅度越小。反之,煤体垂直层理方向的层理裂隙越发育,对声波速度的衰减越明显。最后,建立了煤的 Ed 与 P 波速度的平方(VP2)和 μd 与 VP 与 S 波速度的平方比(VP2/VS2)的回归方程。研究结果有助于评估和预测煤层的储层质量,评估煤层气,提高煤层气开采的安全性和效率。
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来源期刊
ACS Omega
ACS Omega Chemical Engineering-General Chemical Engineering
CiteScore
6.60
自引率
4.90%
发文量
3945
审稿时长
2.4 months
期刊介绍: ACS Omega is an open-access global publication for scientific articles that describe new findings in chemistry and interfacing areas of science, without any perceived evaluation of immediate impact.
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