水力裂缝扩展行为的声发射特征实验研究

doi:10.13722/j.cnki.jrme.2018.0648

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Abstract

Former studies of hydraulic fracturing experiment are usually restricted to the description of fracture geometry and lack the analysis of pump pressure data. To solve the mentioned problems，triaxial hydraulic fracturing experiment is carried out. Combining acoustic emission data with the fracture geometry after experiment，the influences of vertical stress difference coefficient，fracturing fluid viscosity and displacement on hydraulic fracture propagation behavior are studied. The pump pressure signal is wavelet-decomposed to study the relationship between pressure characteristics and fracture propagation behavior. The results show that，vertical stress difference coefficient，fracturing fluid viscosity and displacement have large influences on fracture interaction behavior and fracture propagation velocity，thus affecting the ultimate fracture geometry. Moreover，the detailed information of pump pressure is consistent with the acoustic emission energy curve and fracture geometry. Therefore，it can be used to identify the fracture initiation and interaction behavior. This study provides some guidance for the hydraulic fracturing operation in field.

Key words： rock mechanics shale hydraulic fracturing acoustic emission wavelet analysis

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	Articles by authors
	FAN Meng1
	JIN Yan1
	FU Weineng1
	CHEN Mian1
	HAN Huifang2
	ZHOU Xiaojin2

Cite this article:

FAN Meng1,JIN Yan1,FU Weineng1, et al. Experimental study on fracture propagation behavior based on acoustic emission characteristics[J]. , 2018, 37(S2): 3834-3841.

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https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2018.0648 OR https://rockmech.whrsm.ac.cn/EN/Y2018/V37/IS2/3834

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