Your search keyword '"Jiang, Zhizhong"' showing total 12 results

1. Extraction and identification of spectrum characteristics of coal and rock hydraulic fracturing and uniaxial compression signals

Author

Qian, Ya′nan, Li, Quangui, Hu, Qianting, Jiang, Zhizhong, Liu, Ronghui, Li, Jie, Li, Wenxi, and Yu, Changjun

Published

2023

2. Acoustic Emission Response Mechanism of Hydraulic Fracturing in Different Coal and Rock: A Laboratory Study

Author

Li, Quangui, Qian, Yanan, Hu, Qianting, Jiang, Zhizhong, Xu, Yangcheng, Shang, Xueyi, Ling, Faping, Liu, Ronghui, and Li, Wenxi

Published

2022

3. Acoustic emission characteristics in hydraulic fracturing of stratified rocks: A laboratory study

Author

Wang Xiaoguang, Liu Le, Hu Liangping, Quangui Li, Xuelong Li, Yunpei Liang, Qianting Hu, Ling Faping, Xiaobing Wu, Jiang Zhizhong, and Xu Yangcheng

Subjects

business.industry, General Chemical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Hydraulic fracturing, 020401 chemical engineering, Acoustic emission, Natural gas, Ultimate tensile strength, Geotechnical engineering, Stress conditions, 0204 chemical engineering, Rock failure, 0210 nano-technology, business, Geology

Abstract

Acoustic emission (AE) is a popular technique to monitor the process of rock failure during hydraulic fracturing for unconventional natural gas production. It contains abundant information that will be useful to study in-depth the nature of hydraulic fracturing. In this study, we focused on the AE count, energy, peak frequency, crack classification, and location recorded from four rock specimens subjected to a specific triaxial stress condition. We found the multi-frequency-response phenomenon of AE, and proposed the multi-frequency-response index to indicate the moment of the macrohydraulic crack formation. Furthermore, it was found that the power law distribution index of AE energy of non-stratified specimen was bigger than that of stratified specimens during hydraulic fracturing. The tensile crack dominated in all hydraulic fracturing tests. Our results are of significance for understanding hydraulic fracturing in stratified rocks.

Published

2020

4. Underground microseismic monitoring of a hydraulic fracturing operation for CBM reservoirs in a coal mine

Author

Qianting Hu, Quangui Li, Wang Xiaoguang, Jiufu Chen, Jiang Zhizhong, Xu Yangcheng, and Xuelong Li

Subjects

Microseism, Coalbed methane, business.industry, lcsh:T, Coal mining, coalbed methane, complex mixtures, hydraulic fracturing, lcsh:Technology, General Energy, Hydraulic fracturing, Mining engineering, stimulated area, lcsh:Q, microseismic monitoring, Safety, Risk, Reliability and Quality, business, lcsh:Science, Geology

Abstract

Hydraulic fracturing can evidently improve the coalbed methane production in underground coal mines, but it is difficult to delimit the stimulated area accurately. In order to evaluate the stimulated area, microseismic (MS) monitoring technique is proposed to investigate the seismic responses of the induced fractures of hydraulic fracturing. Three coal seams were targeted to be treated in a coal mine. An array of geophones was set along the underground roadway to detect the MS signals caused by HF. In order to verify the result of MS monitoring, water content of each coal seam has been measured before and after HF treatment. The results showed that a series of MS events were detected during the entire HF process, and a sharp MS event usually occurred during the first hour of HF process. The energy of the sharp MS event had higher magnitude than others. The MS distribution exhibited complex morphological features. The directionless MS response was distributed over a radius of less than 40 m but tended to be significantly conjugated with a radius of more than 40 m. HF could stimulate both the coal seam and the rock layers nearby. The achievable stimulated area in the coal seam was determined to be 50 m × 50 m according to the MS density and water content. The stimulated area in terms of MS density was easily found to be broader than the area of water direct intrusion. The present study indicated that MS monitoring technique could potentially be used for evaluation of HF in underground coal mine.

Published

2019

5. Induced stress evolution of hydraulic fracturing in an inclined soft coal seam gas reservoir near a fault

Author

Qingguo Wang, Jiang Zhizhong, Yongjin Ran, Quangui Li, Xiaoguang Wang, Qianting Hu, Shengli Tong, and Wu Wenbin

Subjects

geography, geography.geographical_feature_category, business.industry, 020209 energy, Borehole, Coal mining, Energy Engineering and Power Technology, Drilling, 02 engineering and technology, Radius, Fault (geology), Geotechnical Engineering and Engineering Geology, Stress (mechanics), Fuel Technology, Hydraulic fracturing, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Extraction (military), Geotechnical engineering, 0204 chemical engineering, business, Geology

Abstract

Hydraulic fracturing is an efficient technique for enhancing coal seam gas production. Induced stress (or stress shadow) of hydraulic fracturing has been popularly studied recent years. In this study, induced stress was measured in a field during the process of hydraulic fracturing. It was found that the induced stress evolution was closely related to the increase of injection volume. The relation between the average induced stress value and the injection volume was fit by the Michaelis-Menten equation well. When carried out the injection operation, we found that the induced stress increased significantly within the radius of 70 m around the hydraulic fracturing borehole. The induced stress also dropped occasionally during the injection process, which indicated some large fractures’ propagation. When the injection operation was finished, the induced stress began to decrease slowly. The subsequent drilling of gas extraction could release the induced stress. In addition, the induced stresses caused by adjacent fracturing boreholes (spacing was 50 m) substantially influenced each other. The induced stress acted earlier in the upper part of the coal seam than the lower part influenced by the steep incidence of the coal seam. Furthermore, the orientation of the induced stress distribution was eventually parallel to the maximum horizontal principal stress direction controlled by a nearby large fault, although the initial orientation was arbitrary. The results are helpful for hydraulic fracturing evaluation and optimization and numerical simulation research.

Published

2021

6. Experimental investigation on crack competitive extension during hydraulic fracturing in coal measures strata

Author

Wang Xiaoguang, Fazhi Yan, Wu Xiaobin, Jiang Zhizhong, Xu Yangcheng, Yan-Qing Wu, Qianting Hu, Liu Le, and Quangui Li

Subjects

animal structures, Coalbed methane, 020209 energy, General Chemical Engineering, Borehole, Energy Engineering and Power Technology, 02 engineering and technology, complex mixtures, Hydraulic fracturing, 020401 chemical engineering, Mining engineering, otorhinolaryngologic diseases, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Pressure drop, business.industry, Organic Chemistry, Coal mining, Coal measures, respiratory tract diseases, Permeability (earth sciences), Fuel Technology, Acoustic emission, embryonic structures, business, Geology

Abstract

Hydraulic fracturing is an effective method to improve the permeability of coal seams and enhance extraction of coalbed methane (CBM). Evolution of cracks in coal seam becomes increasingly complex when one borehole is drilled through multiple coal seams. In this work, physical models with two coal seams having different uniaxial compressive strength (UCS) ratios and height ratios were prepared to study the competitive initiation and extension of cracks based on pump pressure, acoustic emission (AE) source location, and crack morphology. The results showed that, a competitive relationship exists between the two coal seams in terms of crack extension. The pump pressure curves of all specimens presented four stages: (I) fluid-filling stage, (II) pressure rise stage, (III) pressure drop stage, and (IV) pressure stabilization stage. Compared with the pure specimen, the crack initiation pressure of specimens with two coal seams reduced generally. The AE source locations were first generated and mainly distributed in the softer coal seam, resulting in the formation of a complex crack network, whereas only a few cracks were generated in the harder coal seam, as observed after cutting the specimens. In seams with different height ratios, the AE source locations and tracers indicated that cracks preferentially developed and extended in the thinner coal seam. The higher the height ratio of the two coal seams, the more difficult it was for cracks to extend simultaneously in two coal seams. The research results will help improve the permeability of CBM reservoirs when subjecting multiple coal seams to hydraulic fracturing.

Published

2020

7. Acoustic emission characteristics in hydraulic fracturing of stratified rocks: A laboratory study.

Author

Jiang, Zhizhong, Li, Quangui, Hu, Qianting, Liang, Yunpei, Xu, Yangcheng, Liu, Le, Wu, Xiaobing, Li, Xuelong, Wang, Xiaoguang, Hu, Liangping, and Ling, Faping

Subjects

*HYDRAULIC fracturing, *ACOUSTIC emission, *NATURAL gas, *NATURAL gas production, *ROCKS

Abstract

Acoustic emission (AE) is a popular technique to monitor the process of rock failure during hydraulic fracturing for unconventional natural gas production. It contains abundant information that will be useful to study in-depth the nature of hydraulic fracturing. In this study, we focused on the AE count, energy, peak frequency, crack classification, and location recorded from four rock specimens subjected to a specific triaxial stress condition. We found the multi-frequency-response phenomenon of AE, and proposed the multi-frequency-response index to indicate the moment of the macrohydraulic crack formation. Furthermore, it was found that the power law distribution index of AE energy of non-stratified specimen was bigger than that of stratified specimens during hydraulic fracturing. The tensile crack dominated in all hydraulic fracturing tests. Our results are of significance for understanding hydraulic fracturing in stratified rocks. Unlabelled Image • Multi acoustic emission characteristics were combined to explain the rock failure of hydraulic fracturing. • A stratified formation was particularly studied comparing with the single stratum. • The multi-frequency-response index was proposed to indicated the macrohydraulic crack formation. • The type of ruptured stratum was diagnosed with the statistics of acoustic emission energy. [ABSTRACT FROM AUTHOR]

Published

2020

8. Microseismic activity characteristics and range evaluation of hydraulic fracturing in coal seam.

Author

Qian, Yanan, Li, Quangui, Jiang, Zhizhong, Hu, Qianting, Wu, Wenbin, Liu, Yu, Li, Liangwei, Zhang, Zhichao, Yu, Changjun, and Li, Wenxi

Subjects

HYDRAULIC fracturing, WAVELET transforms, SIGNAL-to-noise ratio

Abstract

Accurately evaluating hydraulic fracturing (HF) activity characteristics and impact range is critical to optimizing the HF scheme design. This study proposes an adaptive threshold peak detection method and a wavelet transform-support vector machine (WT-SVM) polarity analysis method based on microseismic (MS) monitoring data from a coal mine in Guizhou, China. The results show that the adaptive threshold peak detection method effectively improves the accuracy and stability of the P-wave initial arrival pickup for low signal-to-noise ratio (SNR) signals. The main frequency band of the MS signal of HF is focused on 150–300 Hz. The improved particle swarm optimization algorithm was used by introducing a random-weight strategy to determine the high-density impact areas of the HF within approximately 20 m on both sides of the fracturing borehole. Density cloud map analysis revealed a small area of the blank zone at the junction of the fracturing section, which provided a basis for fracturing parameter design and scheme optimization. The directional characteristics of the MS waveform were quantitatively described by polarity analysis, where the dip angle distribution ranged from 39° to 49°, the strike angle ranged from 61° to 74°, the slip angle was concentrated near 44°, and the stretch angle ranged from 61° to 74°. The WT-SVM proposed in this study overcame the effects of low SNR signals and the limitations of a small-area station network; 62% of the shear ruptures and 38% of the tensile ruptures of the HF were obtained. Shear cracks were the primary expression of the HF rupture type. • The adaptive threshold peak detection method is proposed to pick initial arrival. • The polarity analysis of microseismic waveform directionality was performed. • The WT-SVM polarity analysis method of the seismic mechanism is proposed. [ABSTRACT FROM AUTHOR]

Published

2024

9. Underground microseismic monitoring of a hydraulic fracturing operation for CBM reservoirs in a coal mine.

Author

Jiang, Zhizhong, Li, Quangui, Hu, Qianting, Chen, Jiufu, Li, Xuelong, Wang, Xiaoguang, and Xu, Yangcheng

Subjects

*HYDRAULIC fracturing, *COALBED methane, *COAL mining, *SEISMIC response, *RESERVOIRS, *COAL, *SALTWATER encroachment

Abstract

Hydraulic fracturing can evidently improve the coalbed methane production in underground coal mines, but it is difficult to delimit the stimulated area accurately. In order to evaluate the stimulated area, microseismic (MS) monitoring technique is proposed to investigate the seismic responses of the induced fractures of hydraulic fracturing. Three coal seams were targeted to be treated in a coal mine. An array of geophones was set along the underground roadway to detect the MS signals caused by HF. In order to verify the result of MS monitoring, water content of each coal seam has been measured before and after HF treatment. The results showed that a series of MS events were detected during the entire HF process, and a sharp MS event usually occurred during the first hour of HF process. The energy of the sharp MS event had higher magnitude than others. The MS distribution exhibited complex morphological features. The directionless MS response was distributed over a radius of less than 40 m but tended to be significantly conjugated with a radius of more than 40 m. HF could stimulate both the coal seam and the rock layers nearby. The achievable stimulated area in the coal seam was determined to be 50 m × 50 m according to the MS density and water content. The stimulated area in terms of MS density was easily found to be broader than the area of water direct intrusion. The present study indicated that MS monitoring technique could potentially be used for evaluation of HF in underground coal mine. [ABSTRACT FROM AUTHOR]

Published

2019

10. Real-time microseismic evaluation of coalbed methane reservoir stimulation based on improved metaheuristic inversion strategy.

Author

Li, Wenxi, Li, Quangui, Hu, Qianting, Qian, Yanan, Yang, Huiming, Jiang, Zhizhong, and Yu, Changjun

Subjects

COALBED methane, HYDRAULIC fracturing, METAHEURISTIC algorithms

Abstract

For the enhancement of coalbed methane production, the microseismic source location plays a crucial role in evaluating fracture information during hydraulic fracturing (HF). A swift and precise microseismic source location is essential for optimizing HF schemes. This optimization necessitates an inversion strategy characterized by low computational costs and high optimization accuracy. In this study, we propose an SM-MFO inversion strategy that functions in parallel with the simplex (SM) algorithm and is founded on the original moth flame optimizer (MFO) algorithm. This strategy was validated through gas blast microseismic monitoring field tests to assess the source location performance of the SM-MFO inversion strategy, followed by its application in real-time evaluation of staged HF for the Xinji 1# horizontal well. The results reveal that within the SM-MFO inversion strategy, SM can prevent local convergence by leveraging the capabilities of MFO. Conversely, MFO can bolster local search abilities with the assistance of SM. As a result, both the convergence speed and global optimization abilities of the strategy are enhanced. In field tests, the average location error of the SM-MFO algorithm was 18.11 m. This figure is more favorable compared to the errors in the MFO algorithm (22.15 m) and the SM algorithm (35.83 m). Moreover, the SM-MFO inversion strategy facilitates real-time evaluation of HF with a computational cost of just 1.01 s for a single microseismic event. Upon analysis of the overall incidence across the nine stages in the radial direction, a span of 270 m is attained, with fewer frequency of fractures observed in the southeast direction at each respective stage Additionally, the geometric parameters of the fractures and the stimulated reservoir volume (SRV) exhibit a positive correlation with the total fluid volume. The injected fluid volume peaks in the second and sixth stages, leading to fracture mesh dimensions of 312 m and 316 m, respectively. In summary, the total SRV of the Xinji 1# horizontal well is 201.7 × 105 m³, and the reservoir stimulation effect aligns with the anticipated results. This work highlights the efficacy of the SM-MFO inversion strategy in enhancing the efficiency and accuracy of microseismic source location for hydraulic fracturing, contributing valuable insights to the field. • An improved moth flame optimizer (SM-MFO) algorithm was proposed for microseismic source location. • The SM-MFO algorithm outperforms the original algorithm in terms of stability, computational efficiency, and accuracy. • The azimuthal distribution of induced fractures was interpreted based on microseismic events. [ABSTRACT FROM AUTHOR]

Published

2023

11. Induced stress evolution of hydraulic fracturing in an inclined soft coal seam gas reservoir near a fault.

Author

Hu, Qianting, Jiang, Zhizhong, Li, Quangui, Wu, Wenbin, Wang, Qingguo, Wang, Xiaoguang, Ran, Yongjin, and Tong, Shengli

Subjects

COALBED methane, HYDRAULIC fracturing, GAS reservoirs, MICHAELIS-Menten equation, CRACK propagation (Fracture mechanics), LONGWALL mining

Abstract

Hydraulic fracturing is an efficient technique for enhancing coal seam gas production. Induced stress (or stress shadow) of hydraulic fracturing has been popularly studied recent years. In this study, induced stress was measured in a field during the process of hydraulic fracturing. It was found that the induced stress evolution was closely related to the increase of injection volume. The relation between the average induced stress value and the injection volume was fit by the Michaelis-Menten equation well. When carried out the injection operation, we found that the induced stress increased significantly within the radius of 70 m around the hydraulic fracturing borehole. The induced stress also dropped occasionally during the injection process, which indicated some large fractures' propagation. When the injection operation was finished, the induced stress began to decrease slowly. The subsequent drilling of gas extraction could release the induced stress. In addition, the induced stresses caused by adjacent fracturing boreholes (spacing was 50 m) substantially influenced each other. The induced stress acted earlier in the upper part of the coal seam than the lower part influenced by the steep incidence of the coal seam. Furthermore, the orientation of the induced stress distribution was eventually parallel to the maximum horizontal principal stress direction controlled by a nearby large fault, although the initial orientation was arbitrary. The results are helpful for hydraulic fracturing evaluation and optimization and numerical simulation research. [Display omitted] • Induced stress of hydraulic fracturing is practically examined in a field. • Average induced stress value can be predicted by Michaelis-Menten equation. • Induced stresses caused by adjacent fracturing boreholes influence each other. • Induced stress area orientation is controlled by fault. [ABSTRACT FROM AUTHOR]

Published

2021

12. Experimental investigation on crack competitive extension during hydraulic fracturing in coal measures strata.

Author

Hu, Qianting, Liu, Le, Li, Quangui, Wu, Yanqing, Wang, Xiaoguang, Jiang, Zhizhong, Yan, Fazhi, Xu, Yangcheng, and Wu, Xiaobin

Subjects

*COAL, *ANTHRACITE coal, *ACOUSTIC emission, *HYDRAULIC fracturing, *COALBED methane, *COMPRESSIVE strength

Abstract

Hydraulic fracturing is an effective method to improve the permeability of coal seams and enhance extraction of coalbed methane (CBM). Evolution of cracks in coal seam becomes increasingly complex when one borehole is drilled through multiple coal seams. In this work, physical models with two coal seams having different uniaxial compressive strength (UCS) ratios and height ratios were prepared to study the competitive initiation and extension of cracks based on pump pressure, acoustic emission (AE) source location, and crack morphology. The results showed that, a competitive relationship exists between the two coal seams in terms of crack extension. The pump pressure curves of all specimens presented four stages: (I) fluid-filling stage, (II) pressure rise stage, (III) pressure drop stage, and (IV) pressure stabilization stage. Compared with the pure specimen, the crack initiation pressure of specimens with two coal seams reduced generally. The AE source locations were first generated and mainly distributed in the softer coal seam, resulting in the formation of a complex crack network, whereas only a few cracks were generated in the harder coal seam, as observed after cutting the specimens. In seams with different height ratios, the AE source locations and tracers indicated that cracks preferentially developed and extended in the thinner coal seam. The higher the height ratio of the two coal seams, the more difficult it was for cracks to extend simultaneously in two coal seams. The research results will help improve the permeability of CBM reservoirs when subjecting multiple coal seams to hydraulic fracturing. [ABSTRACT FROM AUTHOR]

Published

2020