Your search keyword '"COAL gas"' showing total 10,204 results

1. Application of multi-index grey target decision method in prediction of coal temperature in goaf.

Author

Zhu, Xingpan and Wen, Hu

Subjects

SPONTANEOUS combustion, COAL combustion, DECISION theory, FIRE prevention, COAL gas

Abstract

The index gas analysis is an important method of predicting coal spontaneous combustion (CSC). The temperature programmed experiment was used to simulate the CSC process in goaf, and the characteristics of each index gas and coal temperature change were investigated. The corresponding relationship between the target center distance and the coal temperature was determined using the multi-index weighted gray target decision theory. The findings indicate that the selected gases (CO, C2H4, C2H6) and gas combination (format fire coefficient (R), φ(CO)/φ(CO2), φ(C2H4)/φ(CH4), φ(C2H4)/φ(C2H6)) can be used as index gases for CSC prediction. The critical temperature was 70°C and the dry cracking temperature was 110°C. The combined action of coal and oxygen is divided into three stages: slow oxidation (30–70°C), accelerated oxidation (70–110°C), and strong oxidation (after 110°C). The combination of the programmed temperature experiment and the weighted gray target decision theory model determines the relationship between the off-target distance and the coal temperature. The lower the degree of CSC, the better the decision scheme, and the smaller the off-target distance. The results of Xiaobaodang's experimental analyses are applied to the field, and the actual coal temperature in the goaf is predicted to be between 37–62°C. The risk level of CSC in the goaf is determined more intuitively and precisely, providing a theoretical foundation for improving the mining area's fire prevention and extinguishing scheme. [ABSTRACT FROM AUTHOR]

Published

2024

2. Study on the failure and acoustic emission characteristics of coal under graded cyclic loading and unloading stress paths.

Author

Duan, Minke, Lu, Meijuan, Ban, Ruiqi, Yang, Ke, Lyu, Xin, Jiang, Changbao, Hu, Xuelong, and Tang, Jinzhou

Subjects

*CYCLIC loads, *STRAINS & stresses (Mechanics), *LOADING & unloading, *COAL mining, *COAL gas, *GAS seepage, *ACOUSTIC emission

Abstract

To study the influence of cyclic disturbance stress on the mechanical behavior of coal during mining, a gas containing coal fluid-solid coupling servo seepage experimental system was used to conduct experimental research on the acoustic emission (AE) characteristics of gas containing coal under two stress paths of graded cyclic loading and unloading. The AE characteristics of coal damage and failure processes under different cyclic stress paths were analyzed. The research results indicate that: (1) The overall characteristics of AE signals for both graded cyclic loading and unloading paths are basically the same. With increasing of the amount of graded cyclic loading or unloading, the AE count reaches its maximum value when reaching failure, and the cumulative ringing calculation of AE increases exponentially. (2) The AE signals under the graded cyclic loading or unloading path exhibit obvious zoning characteristics. In the low and medium stress regions, the AE signal basically satisfies the Kaiser effect, while reaching the high stress region before failure, the AE signal exhibits a significant Felicity effect. (3) The concentration coefficient of AE and the intensity coefficient of the Kaiser effect have been newly defined. They are used to quantitatively characterize the extent of the Kaiser effect of AEs under graded cyclic stress. It was found that as the variation of graded cyclic stress increases, the concentration coefficient and Kaiser effect intensity coefficient both show a decreasing trend. (4) Combining the AF and RA values of AE, it was found that the coal failure signals of the two stress paths were basically similar, that is, the overall failure was mainly tensile failure, and the signals of cyclic unloading tensile failure were significantly more than those of cyclic loading. The AE signal characteristics studied in this article are of great significance for predicting coal power disasters. [ABSTRACT FROM AUTHOR]

Published

2024

3. Synergistic Inhibiting and Sealing Material for Preventing the Compound Disaster of Gas and Coal Spontaneous Combustion: Ratio Optimization and Inhibition Test.

Author

Tang, Zongqing, Zhang, Huana, Deng, Jun, Yang, Shengqiang, Xu, Guang, Zheng, Wancheng, and Chang, Ping

Subjects

SPONTANEOUS combustion, COAL combustion, CHEMICAL properties, COAL gas, FREE radicals

Abstract

The spontaneous combustion and gas explosion induced by crushed small coal pillars and the residual coal of adjacent goaf will cause a large amount of coal loss and casualties of workers. Moreover, it also seriously pollutes the environment and aggravates the greenhouse effect. To effectively block small coal pillars and fracture zones of adjacent old workings is the key to prevent gas and coal spontaneous combustion in small coal pillars. However, the commonly used blocking materials at present are easy to shrink and chap after air drying, and they have no chemical inhibitory property. Thus, these materials cannot realize the coordinated prevention of gas and coal spontaneous combustion. In this paper, a low-cost and eco-friendly Synergistic Inhibiting and Sealing Material (SISM)with strong inhibitory properties is proposed. The optimal ratio of the material was determined by experiments. The inhibitory properties of the material are analyzed by testing and comparing the generation rate of free radical and CO generation rate. The experimental results showed that the optimal molar ratio of main antioxidant and auxiliary antioxidant was 5:2, and the optimal mass ratio of synergistic antioxidant and high water material was 1:8. Secondly, SISM can prevent or delay the production of new free radicals during coal spontaneous combustion, significantly reduce the concentration of free radicals in coal and finally delay the process of coal spontaneous combustion. Thirdly, both physical and chemical inhibitory properties are taken into account when preparing SISM. Hence, it can maintain both high inhibitory properties in the whole temperature range and the inhibition effect on coal-oxygen compound reaction, which is significantly better than MgCl2 and yellow mud (YM) with only physical inhibition. [ABSTRACT FROM AUTHOR]

Published

2024

4. Analysis of dominant flow in tectonic coal during coalbed methane transport.

Author

Zhu, Xinyu, Su, Erlei, Cheng, Zhiheng, Ni, Xiaoming, Chen, Liang, Zhang, Jinhu, and Wang, Hongbing

Subjects

*GAS well drilling, *COAL gas, *GAS extraction, *DIFFUSION coefficients, *GAS flow, *COALBED methane

Abstract

Diffusion and seepage are the main flow forms of coal seam gas transport, and are one of the key factors in the selection of gas extraction improvement methods. Changes in the physical structure of tectonic coal make gas transport more complex during coalbed methane extraction. In this paper, we develop a multi-field coupled model of methane transport in coal seams, taking into account the effects of tectonics, and theoretically analyze the dominant flow patterns for methane extraction. Then, the evolution of gas dominated flow is analyzed for different initial pressures, initial permeabilities, and initial diffusion coefficients of tectonic and intact coal seams. The results show that the amount of daily methane seepage in tectonic coal increases with the initial pressure of the coal reservoir, but decreases with the initial diffusion coefficient of the coal reservoir. Methane seepage in tectonic coal has a longer control time than in intact coal at different initial pressures, initial permeabilities, and initial diffusion coefficients of the coal reservoir. For different coal reservoir initial pressures, coal reservoir initial permeabilities, and coal reservoir initial diffusion coefficients, the maximum seepage control time for tectonic coal is 20, 17, and 15 times longer than for intact coal, respectively. Finally, the discrepancies of methane dominant flow in tectonic coal and intact coal during methane extraction were analyzed by using the double bottleneck flow model, and methods for methane enhanced extraction in tectonic coal and intact coal were discussed. The results presented in this paper may provide a theoretical reference for the extraction of differentiated gas in coal seams. [ABSTRACT FROM AUTHOR]

Published

2024

5. Interaction behavior between hydraulic fractures and interface in coal-rock complex rock layer: Experimental study and application exploration.

Author

Li, Bo, Shi, Zhen, Zhang, Junxiang, Wang, Nannan, Li, Qinghai, and Li, Feng

Subjects

*DISTRIBUTION (Probability theory), *HYDRAULIC fracturing, *COAL mining, *GAS well drilling, *COAL gas

Abstract

To achieve long-term and efficient gas extraction in soft, low-permeability coal seams, this study conducted hydraulic fracturing experiments on coal-rock complexes under true triaxial conditions. The pattern of hydraulic fractures (HFs) was reconstructed based on the fractal dimension concept. The results indicate that the tendency of the complex rock layers to initiate fractures toward the coal weakens the trend of increasing fracture initiation pressure with rising geostress. When HFs interact with the interface, the extension pressure significantly decreases. With the lateral pressure coefficient decreasing, HFs tend to extend toward the coal and be captured by the interface, transitioning from a single-wing to a double-wing shape and approaching a symmetrical conjugate state. Only when the vertical principal stress is sufficiently large can HFs separate from the interface. Based on the derived distribution function of induced stress in the coal-rock matrix around the HFs, the displacement conditions of the coal, rock, and interface were examined. The interaction process of rock layer HFs and the interface was divided into three stages: deflection, capture, and separation. The applicability of this study to high-gas soft coal seams was discussed, and a gas management plan involving roof fracturing and full-period extraction was proposed, with the aim of providing a theoretical foundation for the co-extraction and efficient utilization of coal and gas in mines. [ABSTRACT FROM AUTHOR]

Published

2024

6. Experimental study on characteristics of gas seepage in broken coal and rock.

Author

Hao, Dingyi, Tu, Shihao, Zhang, Lei, Zhao, Hongbin, and Xu, Shikun

Subjects

*DARCY'S law, *GAS seepage, *COAL gas, *GAS well drilling, *GAS extraction

Abstract

The characteristics of gas seepage in broken coal and rock composed of different particle sizes and grades were investigated in this study. On the basis of Darcy's law and non‐Darcy seepage theory, equations of gas permeability in the nonlinear seepage of broken coal and rock, as well as the porosity of broken coal and rock, under triaxial compression were determined. The stress loading path of gas seepage in broken coal and rock was developed. The characteristics of gas seepage in broken coal and rock composed of different particle sizes and grades were analyzed, and the results showed that the gas permeability after compression was proportional to the particle size of the broken coal and rock. Under triaxial compression, the gas permeability of the broken coal and rock composed of graded‐particle sizes was lower than that of the broken coal and rock composed of different single‐particle sizes. The gas permeability of the broken coal was lower than that of the broken rock mass, and the gas permeability and porosity of the broken coal and rock can be described by the exponential decay function. At a constant porosity, the gas permeability of the broken coal and rock was proportional to the size grading index under triaxial compression. The coefficient of viscosity and gravity of the flow are key factors influencing the flow permeability in broken coal and rock. This study provides a reference for on‐site practice such as the efficient extraction of gas in goafs. [ABSTRACT FROM AUTHOR]

Published

2024

7. 常温干法脱硫剂研究进展与展望.

Author

唐朝勇, 闫飞飞, 练以诚, and 杨超

Subjects

GAS as fuel, MOLECULAR sieves, OCCUPATIONAL hazards, COAL gas, ENERGY consumption, BIOGAS

Abstract

Copyright of Low-Carbon Chemistry & Chemical Engineering is the property of Low-Carbon Chemistry & Chemical Engineering Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

8. 不同变质程度煤在胶质体阶段的碳结构演变探究.

Author

许恒光, 田露, 戚悦昕, 徐秀丽, 窦金孝, and 余江龙

Subjects

COKING coal, FOURIER transform infrared spectroscopy, COKE (Coal product), COAL gas, COAL sampling

Abstract

Copyright of Low-Carbon Chemistry & Chemical Engineering is the property of Low-Carbon Chemistry & Chemical Engineering Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

9. Ultrasonic Technology for Hydrocarbon Raw Recovery and Processing.

Author

Myltykbayeva, Zhannur, Mussabayeva, Binur, Ongarbayev, Yerdos, Imanbayev, Yerzhan, and Muktaly, Dinara

Subjects

SHALE oils, OIL shales, COAL gas, PERMEABILITY, POLLUTION

Abstract

This review discusses recent research findings spanning the last two decades concerning ultrasonic technologies applicable to the oil, gas, and coal sectors. Various experiments conducted in laboratories have demonstrated the efficacy, cost-effectiveness, and environmental friendliness of ultrasound in recovering and processing oil, bitumen, coal, and oil shale. Ultrasound enhances formation permeability, coal gas permeability, and oil viscosity, particularly when delivered in short, powerful pulses at medium frequencies. Combining ultrasound with traditional recovery methods has shown promising results, boosting recovery efficiency by up to 100%. At the same time, ultrasonic treatment reduces the use of traditional reagents, thereby reducing environmental pollution. Moreover, ultrasound treatment shows potential in tasks such as separating oil–water emulsions, desulfurization, dewaxing oil, coal enrichment, and extracting valuable metals from metal-bearing shales through hydrometallurgical leaching. However, the widespread industrial implementation of ultrasonic technology necessitates further field and mathematical research. [ABSTRACT FROM AUTHOR]

Published

2024

10. Numerical Analysis of Leakage and Diffusion Characteristics of In-Situ Coal Gas with Complex Components.

Author

Liu, Enbin, Zhou, Lianle, Tang, Ping, Kou, Bo, Li, Xi, and Lu, Xudong

Subjects

*NATURAL gas reserves, *COAL gas, *COAL gasification, *PIPELINE transportation, *WIND speed

Abstract

To alleviate the shortage of natural gas supply, the in-situ conversion of coal to natural gas is more beneficial for advancing the clean and efficient use of energy. Since in-situ coal gas contains complex components, such as H2, CH4, and CO, their leakage poses a serious risk to human life and property. Currently, the area of consequence of the harm caused by a leak in a gathering pipeline transporting in-situ coal gas has not been clarified. Therefore, this paper adopted the method of numerical simulation to pre-study the concentration distribution of each component and determined that the main components of concern are CO and H2 components. Afterward, the diffusion law of in-situ coal gas is analyzed and studied under different working conditions, such as wind speed, temperature, pipe diameter, leakage direction, and leakage aperture ratio. The results indicate that when a pipeline leak occurs, the CO component has the largest influence range. With increasing wind speed, the warning boundary of CO rapidly expands downwind, then gradually diminishes, reaching a peak value of 231.62 m at 7 m/s. The range of influence of the leaked gas is inversely proportional to temperature and directly proportional to pipe diameter and leakage aperture ratio. When the gas leaks laterally, the diffusion early warning boundary value of each component is maximal. Among them, the leakage aperture ratio has a significant impact on the concentration distribution of in-situ coal gas, whereas the effect of temperature is relatively minor. This study contributes to an understanding of the leakage and diffusion characteristics of in-situ coal gas-gathering pipelines. [ABSTRACT FROM AUTHOR]

Published

2024

11. Main control factors of coalbed methane occurrence differences in adjacent coal seams - a case study of Luling coal mine, Huaibei Coalfield, China.

Author

Zheng, Siwen, Wang, Liang, Chen, Dapeng, Liu, Yuanyuan, and Jiang, Changbao

Subjects

COALBED methane, COAL mining, GAS distribution, COAL gas, GAS migration, GAS bursts

Abstract

Coalbed methane (CBM) is a natural gas resource related with coal deposits. In general, Gas status parameters gradually with the depth of the stratum. However, in areas with complex geological structures and multiple coal seam occurrences, the gas storage situation in shallow coal seams is typically better than in deep coal seams. This research paper focuses on coal seams numbered 8, 9, and 10 within the Luling coal seam as the subject of study. The study combines the analysis of gas accumulation history, laboratory experiments, and field investigations to examine the differences in gas occurrence within the coal seam group. The findings suggest that the differences in gas occurrence state within each coal seam of the Luling coal mine is predominantly governed by tectonic processes. During the process of tectonic evolution, the thicker coal seams, such as Nos. 8 and 9, are more prone to fracturing, leading to the formation of widely distributed tectonic coal. These broken coal bodies exhibit a significant capacity to store gas, resulting in favorable gas storage conditions within these coal seams. On the other hand, the low permeability of the mudstone in the roof layer restricts the migration and seepage of gas in the No. 10 coal seam, leading to a comparatively lower sealing effect for gas. By providing a comprehensive understanding of the gas content differences in the coal seam group, this study highlights the significant influence of geological processes on the distribution and storage of gas. These findings contribute to understanding the characteristics of gas reservoirs under complex geological conditions and adopting corresponding measures to reduce the risk of coal and gas outbursts in coal seams. [ABSTRACT FROM AUTHOR]

Published

2024

12. Challenges and Opportunities of Carbon Capture and Utilization: Electrochemical Conversion of CO2 to Ethylene.

Author

Pappijn, Cato A. R., Ruitenbeek, Matthijs, Reyniers, Marie-Frangoise, Geem, Kevin M. Van, Adams, Thomas Alan, and Desideri, Umberto

Subjects

CARBON sequestration, CLEAN energy, COAL gas, ELECTROLYTIC reduction, CAPITAL investments

Abstract

The discovery and development of efficient technologies that enable the use of CO2 as a starting material for chemical synthesis (at scale) is probably one of the biggest scientific challenges of our time. But a key question is if the cure will not be worse than the disease? In this work, the economic feasibility of the electrochemical reduction of CO2 to ethylene is assessed and it is demonstrated that from a Capital expenditure and Operational expenditure point of view the electrochemical production of ethylene from CO2 is not feasible under the current market conditions. Even in the case that the renewable electricity price would be zero, the feasibility is hampered by the state-of-the-art catalyst performance (selectivity) and the cost of the electrochemical reactor. Turning the installation on and off, if this would be even practically possible, is not interesting because our study shows that because of the high Capital expenditure, the payback time of the process would become unacceptably high. Finally, because of the high electricity requirement, this Carbon Capture and Utilization process has a lower CO2 avoidance potential than the substitution of gray electricity by green electricity. This means that today the available green electricity would best be used to close coal and gas based power plants instead of powering the electrochemical conversion of CO2 to ethylene. [ABSTRACT FROM AUTHOR]

Published

2024

13. Analysis on typical characteristics and causes of coal mine gas explosion accidents in China.

Author

Lin, Zhijun, Li, Min, He, Shan, Wang, Deming, Shi, Shiliang, and Wang, Dan

Subjects

GAS explosions, ASSOCIATION rule mining, TEXT mining, APRIORI algorithm, COAL gas

Abstract

Large-scale coal mine gas explosion (CMGE) accidents have occurred occasionally and exerted a devastating effect on society. Therefore, it is essential to systematically identify the characteristics and association rules of causes of CMGE accidents through analysis on large-scale CMGE accident reports. In this study, 298 large-scale CMGE accidents in China from 2000 to 2021 were taken as the data sample, and mathematical statistical methods were adopted to analyze their general characteristics, coupling cross characteristics, and characteristics of gas accumulation and ignition sources. Moreover, the text mining technology and the Apriori algorithm were used for exploring the formation mechanism of CMGE accidents, during which 46 main causal factors were identified and 59 strong association rules were obtained. Furthermore, an accident causation network was constructed based on the co-occurrence matrix. The key causal items and sets of CMGE accidents were clarified through network centrality analysis. According to the research results, electrical equipment failure, cable short circuit, mine lamp misfire, hot-line work, and blasting spark are the key ignition sources of CMGE. Fan failure, airflow short circuit, and local ventilation fan damage are the main causes of gas accumulation. Besides, the confidence levels of two association rules of "static spark-fan failure" and "blasting spark-airflow short circuit" are higher than 70%, indicating that they are the two dominant risk-coupling paths of gas explosions. In addition, six causes appear frequently in the shortest risk paths of gas explosion and are closely related to other causes, i.e., fan failure, local ventilation fan damage, static sparks, electrical equipment failure, self-heating ignition, and friction impact sparks. This study provides a new perspective on identifying causes of accidents and their complex association mechanisms from accident report data for practical guidance in risk assessment and accident prevention. [ABSTRACT FROM AUTHOR]

Published

2024

14. Effect of liquid CO2 phase change on pores and fractures in coal: An experimental study.

Author

Jiang, Zebiao, Gao, Shikang, Liu, Hao, Chen, Siliang, Mo, Qiaoshun, and He, Feng

Subjects

*LIQUID carbon dioxide, *GAS bursts, *SCANNING electron microscopes, *GAS well drilling, *COAL gas

Abstract

The evolution characteristics of pores and fractures in coal after liquid carbon dioxide (CO2) phase change are important factors that determine the permeability increase effect. Therefore, it is critical to correctly understand the influences of liquid CO2 phase change on pores and fractures in coal. The changes of adsorption and desorption isotherm, pore size, pore volume, and specific surface area of fractured coal and fractured coal were compared by low temperature liquid nitrogen adsorption experiment. In addition, a scanning electron microscope was adopted to observe fracture characteristics of fractured and unfractured coal samples and analyze changes in the connectivity and fracture development. Experimental results show that the fractured coal samples exhibit better hysteresis loops and a larger proportion of gas desorption than the unfractured ones. Fractured coal samples contain more developed pores and fractures compared with unfractured ones, and their fragmentation degree, pore diameter, fracture width, and connectivity of pores and fractures are also better. Besides, the closer the samples from the fracturing boreholes are, the better the fracturing effect. This indicates that liquid CO2 phase change can effectively enhance the gas transport capacity in pores and fractures in coal. The research results provide a solid basis for the better application of liquid CO2 phase‐change fracturing to the prevention of coal and gas outburst disasters and the realization of efficient gas extraction in deep coal seams. [ABSTRACT FROM AUTHOR]

Published

2024

15. Interfacial contact characteristics and energy evolution of gas-bearing coal seams at different shear rates.

Author

Hu, Jiaying, Guo, Yangyang, Chen, Xuexi, Chen, Xingyu, and Yang, Tao

Subjects

*SHEAR (Mechanics), *COAL mining, *STABILITY (Mechanics), *COAL gas, *SHEAR strength

Abstract

Coal mine geological tectonic belts have a high incidence of coal mine gas disasters. The deformation and displacement of tectonic belts under geological action are the typical characteristics of a "tectonic interface." It is of great significance to study the shear mechanics and stability of the tectonic interface of gas-bearing coal seams to clarify the mechanisms of geologic structure control outburst. In this paper, the interfacial shear seepage coupling tests of coal seams under different shear rates are carried out, and the displacement and mechanical properties of interfacial contact points under different shear rates are studied on a mesoscale basis. The main conclusions are as follows: with the increase in shear rate, the interfacial shear strength and stick-slip stress decrease, but the number of stick-slip events increases correspondingly. The interfacial friction coefficient is negatively correlated with the shear rate, and the sensitivity of the interfacial friction coefficient decreases with the increase in the shear rate. With the increase in shear rate, the meshing degree of shear convex decreases and the meso-contact stress decreases. As the shear rate increases, less energy is released and fewer cracks are generated by dissipated energy. Finally, the evolution law of macroscopic mechanics-meso-contact-energy transformation of the interface during shearing is expounded. [ABSTRACT FROM AUTHOR]

Published

2024

16. Research on outburst gas pressure dynamics and water-injected coal damage.

Author

Wei, Chengmin, Li, Chengwu, Lu, Shuhao, Li, Zhenfei, Li, Mingjie, and Hao, Min

Subjects

*GAS bursts, *GAS dynamics, *DAMAGE models, *COAL gas, *PARTICLE size distribution

Abstract

Coal and gas outbursts are complex dynamic disasters closely associated with gas pressure dynamics and coal damage. An experimental system was established to investigate the effects of water injection on coal particles. The experiments utilized helium (He) and carbon dioxide (CO2) gases, at initial pressures ranging from 0.25 to 1.0 MPa and water injection periods ranging from 0 to 12 days, to measure gas pressure variation, particle size distribution, equivalent diameter, and newly generated surface area. The results indicated that outburst gas pressure follows a power-law decay, with He decaying more rapidly than CO2. Elevated gas pressure and adsorptivity intensified coal particle damage: each 0.25 MPa rise in pressure increased the new surface area by 1.02 times for He and 1.28 times for CO2, with the CO2's surface area being 5.03–5.20 times larger than that of He. Water injection mitigated the damage caused by adsorptive gases; as the injection time increased, the new surface area initially decreased and then increased, with the least damage at 6 days. For every 3 day increase in the water injection time, the average surface area of He-fractured coal increases by 0.69 times. A gas pressure decay model and a coal damage model considering pressure differential tension, gas adsorption expansion, and adsorption-induced strain were developed and validated against experimental results. These findings provide theoretical insights into coal and gas outbursts. [ABSTRACT FROM AUTHOR]

Published

2024

17. Experimental investigation on the gas pressure influence laws and mechanical mechanism of coal and gas outbursts.

Author

Meng, Han, Yang, Yuzhong, Guo, Haijun, Hou, Wei, Li, Xinwang, An, Fenghua, Zhang, Rui, Chen, Li, Rong, Tenglong, Yang, Daming, Cheng, Lichao, and Niu, Yufen

Subjects

*PULVERIZED coal, *GAS bursts, *COAL gas, *PRESSURE sensors, *GAS detectors

Abstract

With the increasing frequency and intensity of coal and gas outburst disasters under deep mining conditions, studying the outburst mechanism of occurrence has great significance for outbursts prevention and control. The evolution law of coal and gas outbursts under different gas pressure is proposed. The outbursts law is analyzed utilizing the self-developed simulation experiment system of coal and gas outbursts, and the simulation experiment is carried out under the gas pressure of 0.45, 0.8, and 1.5 MPa. In the experiment, the gas pressure drops curves, the relative intensity change, the interval distribution of coal powder, and the evolution of outburst hole and the migration rate of coal powder are analyzed. The results indicate that (1) the gas pressure detected by the No. 4 gas pressure sensor starts to drop first; (2) the gas pressure is positively proportional to the relative outburst intensity. When the gas pressure increases from 0.45 to 0.80 MPa and then to 1.5 MPa, the farthest outburst distance of coal powder increases from 10 to 15 m and then to 21 m, and the corresponding relative outburst intensity increases from 22.94% to 35.74% and then to 45.73%, respectively. (3) The average proportion of coal particles size less than 0.28 mm and larger than 1 mm under each corresponding outburst interval is 40.75% and 22.53%, respectively. Experimental results show that the gas pressure plays an essential role in the secondary crushing and pulverization of coal samples during the outburst process. (4) The throwing velocity of the pulverized coal is increased with the gas pressure near the outburst hole. When the gas pressure is 0.8 MPa, the throwing velocity of pulverized coal reaches the maximum value of 32.40 m/s. (5) The dimensional characteristics and the location initiation of the outburst hole are obtained. The results showed that the outburst process of coal is mainly in two failure forms: pulverization and spallation. The research results provide a theoretical basis and test data support for the prevention and control of coal and gas outburst disasters. [ABSTRACT FROM AUTHOR]

Published

2024

18. Impact of closed pores on gas transport and its implication for optimizing drainage borehole design.

Author

Xu, Hexiang, Liu, Ting, Zhai, Cheng, Xu, Jizhao, Zheng, Yangfeng, Zhu, Xinyu, Wang, Yu, and Huang, Ting

Subjects

*GAS migration, *RESPONSE surfaces (Statistics), *COMPOUND fractures, *COAL gas, *STATISTICAL correlation

Abstract

Mining disturbances can rupture the closed pores, releasing the gas and potentially triggering gas accidents. The pre-drainage of gas via boreholes is the primary measure for preventing coal and gas outbursts. Nevertheless, the influence of closed pores on gas migration remains unclear, leading to suboptimal borehole spacing and radius. Therefore, a gas–solid coupled model incorporating closed pores was developed to investigate the influence of closed pores on gas migration during gas drainage (GD). Subsequently, response surface methodology was employed to investigate the input parameters and their interactions on residual gas content (RGC) and pre-drainage time (PDT). Finally, an optimization methodology for borehole spacing/radius was presented. The results show that both RGC and PDT exhibit a positive correlation with the ratio of closed porosity to total porosity (λ) and the ratio of closed pore diffusion coefficient to that of the open pore (Do/Dc). Initially, the total gas production is primarily extracted from fractures and open pores, followed by closed pores in the later stages. Single-factor analysis demonstrates that λ, permeability, and Do/Dc have a more significant impact on RGC and PDT compared to borehole spacing and borehole radius. Borehole spacing interacts more strongly with λ, permeability and Do/Dc than borehole radius. An optimization method for borehole spacing and borehole radius, constrained by PDT, RGC, and the number of boreholes, is proposed using response surface optimization maps. This method provides guidance for borehole construction to optimize GD efficiency and minimize RGC. [ABSTRACT FROM AUTHOR]

Published

2024

19. Comparison of Gravimetric Determination of Methane Sorption Capacities of Coals for Using Their Results in Assessing Outbursts in Mines.

Author

Obracaj, Dariusz, Korzec, Marek, and Dreger, Marcin

Subjects

*MINE ventilation, *GAS bursts, *COAL gas, *COAL mining, *GRAVIMETRIC analysis

Abstract

The gravimetric method for determining coal gas sorption has many advantages and limitations. The article presents the influence of various factors on the results of methane sorption on coal. In mining practice, in addition to sorption properties of coal, knowledge of methane sorption capacity and effective diffusion coefficient determined when assuming a unipore sorption/desorption model are crucial for predicting sudden releases of methane from coal seams to a mine ventilation environment. In Poland, determining sorption capacities of coals for methane is mandatory when starting mining operations in new parts of coal deposits threatened by outbursts. Traditionally, gravimetric microbalances, such as intelligent gravimetric analysis (IGA), are used to determine adsorption capacity and desorption rate. Recently, newer microbalances XEMIS have been introduced to the market. Two gas laboratories, AGH in Krakow and CLP-B in Jastrzebie-Zdroj, respectively, compared experimental adsorption isotherms using XEMIS microbalances with mutually exchanged coal samples. Both sorption capacity at the pressure of 1 bar ( a 1 b a r ) and effective diffusion coefficient ( D e ) were independently determined for the coal samples tested. The results obtained are comparable despite the use of different microbalance XEMIS models. The conducted studies and comparative evaluation of the results allowed for assessing procedures for determining sorption properties using XEMIS microbalances. The exchange of laboratory experiences also allowed for the identification of methodology factors crucial for the development of a uniform procedure for conducting similar studies with XEMIS microbalance. The proposed factors for testing the sorption behavior of methane in coal structures may be helpful in mining practice. [ABSTRACT FROM AUTHOR]

Published

2024

20. 基于超前探测技术的煤矿瓦斯异常预警方法.

Author

刘占宇

Subjects

DISCRETE wavelet transforms, COAL mining, RAYLEIGH waves, COAL gas, GAS detectors

Abstract

Copyright of China Mining Magazine is the property of China Mining Magazine Co., Ltd. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

21. 含瓦斯煤岩构造界面剪切-渗流耦合 试验方法及教学设计实践.

Author

胡嘉英, 邹光华, 徐祚卉, 陈学习, 杨 涛, 师皓宇, and 周爱桃

Subjects

SHEAR (Mechanics), SHEAR strength, COAL mining, SHEARING force, COAL gas, GAS bursts

Abstract

Copyright of Experimental Technology & Management is the property of Experimental Technology & Management Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

22. Combustion and Fragmentation Characteristics of Single Wet Coal Slime Particle.

Author

Mei, Weiguang, Jia, Tongying, Zhang, Yongsheng, Wang, Tao, Wang, Jiawei, and Pan, Wei-Ping

Subjects

COAL combustion, COAL gas, MASS spectrometers, COAL, HIGH temperatures, PULVERIZED coal

Abstract

The combustion and fragmentation characteristics of wet coal slime particle are different from that of dried coal particle. In this paper, an understanding of the combustion process of wet coal slime particle through the combined results of the morphology characteristics, mass changes, and gas release pattern is provided. A tube furnace and high-speed camera were used to observe morphological changes of the combustion process of wet coal slime. For comparison, the mass change and gas release pattern of wet coal slime was monitored by a thermogravimetric analyzer and mass spectrometer (TG/MS). The four combustion stages of coal slime were observed for the first time: (1) drying and evaporation, (2) devolatilization and fragmentation, (3) volatile homogeneous combustion, and (4) char heterogeneous combustion. The water content in wet coal slime greatly affected the fragmentation of coal slime, it could build up a great internal pressure when evaporated, which caused the primary fragmentation to occur earlier and be more severe than traditional coals. The temperature and diameter of the slime were considered as factors for the occurrence of fragmentation and the level of it. A larger diameter with a higher furnace temperature resulted in a more severe fragmentation of the wet coal slime. The smaller coal slime at the lower temperatures did not experience the fragmentation stage. Here, the fragmentation and non-fragmentation zones of wet coal slime at different temperatures and different paticle diameters are given, which could be a guide for the combustion of coal slime in CFB(Circulating Fluidized Bed). Also, for larger diameters and lower setting temperatures, the ignition delay time and burnout time of wet coal slime became longer. The gas release pattern of wet coal slime during the combustion process was analyzed, and it was determined that it could be affected greatly by fragmentation. A model of the drying and evaporation stage of wet coal slime was established for the first time by using COMSOL Multiphysics. The results of the theoretical calculations show that there were two evaporation rate peaks of water when fragmentation occurred, which theoretically explained the early stage of the combustion process of wet coal slime, and the results were in agreement with the experiments. [ABSTRACT FROM AUTHOR]

Published

2024

23. Research on Hotspots and Evolutionary Trends in Coal Mine Gas Prevention.

Author

Zhao, Chunguang, Gao, Peng, Ruan, Jinlin, Pu, Yang, Sun, Yuan, Cheng, Xiaoyang, and Sun, Yu

Subjects

COAL gas, MINE safety, GREENHOUSE gases, RESEARCH personnel, DATABASES

Abstract

Mine gas accidents have received widespread attention at home and abroad, because mine gas accidents often cause casualties and property losses once they occur. This study was conducted in order to have a more comprehensive understanding of the research status of and research hotspots in coal mine gas management at home and abroad, and to provide references for relevant researchers' studies and literature searches. Using the Web of Science (WOS) core database as the data source, this paper analyzed the data from the period of 2000–2023 under the headings of "gas governance", "Gas Control Technology", "Pre-mining gas methods in coal mines", "Methods of Gas Mining in Coal Mines", "Post-mining gas", and "Post-mining gas methods in coal mines". "Methods in Coal Mines", "Methods of Gas Mining in Coal Mines", and "Post-mining Gas Methods in Coal Mines" were searched, and the CiteSpace tool was utilized to provide a multi-dimensional visual presentation of the literature, including authors, the number of journals issued, countries of issue, keywords, etc., in order to explore the research hotspots in this field. The analysis results show the following: the development process in the field of gas prevention and control is mainly divided into the three stages of initial exploration, steady development, and explosive surge; China, Australia, and the United States are the top three countries in terms of the number of articles published, and they have a greater influence in the field, but there is a closer connection between the regions in Europe; a certain group size has been formed by the researchers and research institutes in this field, the China University of Mining and Technology is more active in this field, ranking as the first in terms of the number of articles issued, and it has a cooperative relationship with many universities; Kai Wang and Enyuan Wang are the core authors in this field, while C. Ozgen Karacan also has a large body of research in the field, and his research results are widely recognized; the main journals issued in this field are Fuel and Energy Policy, while other journals have been frequently cited, and these journals have an important role in the field. In these journals, "Coal mine methane: A review of capture and utilization practices with benefits to mining safety and to greenhouse gas reduction" is one of the most important articles in the field. Thin coal seams, coal mining workings, and coal and gas protrusion are current research hotspots. [ABSTRACT FROM AUTHOR]

Published

2024

24. Study on Safety Tunneling Technology of Secondary Outburst Elimination by CO 2 Gas Fracturing in High-Outburst Coal Seam.

Author

Xu, Zongwei, Zhang, Junsheng, Cao, Yunxing, Wang, Zhenzhi, and Zhang, Xinsheng

Subjects

TECHNOLOGICAL innovations, COAL mining, COAL gas, MINE safety, CARBON dioxide

Abstract

The No. 3 coal seam in the Yuxi Coal Mine has a measured maximum gas content of 25.59 m3/t, along with a maximum gas pressure of 2.9 MPa, indicating its high risk to gas and outbursts. To mitigate outburst risks of the coal seam, the 1301 working face has been implemented with gas pre-drainage measures by grid boreholes from underlying roadways. After one year of extraction, it was confirmed that the gas content at all 33 test sites was below 8 m3/t, meeting the outburst prevention standards. However, during subsequent coal tunnel excavation, the gas desorption index K1 value frequently exceeded the standard, resulting in numerous occurrences of abnormal gas emission or small-scale outbursts. To tackle the challenges associated with safe excavation following the first-round regional outburst prevention measures, a research and industrial trial of CO2 gas fracturing (CO2-Frac) technology for secondary outburst prevention and rapid excavation was completed. The results show that the dual-hole and high-pressure (185 MPa) CO2-Frac considerably contributes to outburst prevention. K1 exceedances per hundred meters of tunnel excavations were from an average of 2.54 without CO2-Frac to an average of 0.28 after the new technology was implemented, leading to an eight-fold reduction. Additionally, the monthly excavation footage increased from an average of 81.64 m without CO2-Frac to an average of 162.42 m with CO2-Frac, resulting in a two-fold improvement. The dual-hole and high-pressure CO2-Frac is an advanced technology for safe and efficient excavation for secondary outburst elimination in highly outburst-prone coal seams in the Yuxi Coal Mine, with potential for widespread application in similar coal seam conditions. [ABSTRACT FROM AUTHOR]

Published

2024

25. 平顶山矿区多煤层卸压立体抽采模式与工程示范.

Author

李延河, 倪小明, and 贾晋生

Subjects

COAL mining, GAS-lubricated bearings, COAL gas, MINES & mineral resources, MINE closures, HORIZONTAL wells

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

26. 煤系氦气富集机理与资源潜力.

Author

刘祥柏, 陶士振, 杨秀春, 赵群, 陈燕燕, 刘自扬, 裴向兵, 王龙飞, 伊伟2，, 冯建秋, 张谭, 高建荣, 陶小晚, 柳庄小雪, 李超正, 杨怡青, and 陈悦

Subjects

FAULT location (Engineering), CAP rock, COALBED methane, GAS wells, COAL gas

Abstract

Copyright of Coal Geology & Exploration is the property of Xian Research Institute of China Coal Research Institute and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

27. Preparation and stability of zinc‐based mesoporous sorbent modified with aluminium for high temperature coal gas desulphurization.

Author

Li, Yang, Du, Yi‐en, Wu, Haipeng, Mi, Jie, and Feng, Yu

Subjects

DESULFURIZATION of coal, COAL gas, POROSITY, MASS transfer, DESULFURIZATION

Abstract

Zinc‐based sorbents with ordered mesoporous structure were modified with aluminium and the key factors in the preparation were optimized based on the results of desulphurization tests performed in a fixed‐bed reactor with simulated coal gas. It was shown that the sorbents for hydrogen sulphide removal reached an optimum sulphur capacity of 9.14% when prepared under conditions of 10.0 crystalline pH, 30:1 Si:Al molar ratio, 0.32:1 Zn:Si molar ratio, and 1:3 Zn:TAA molar ratio. The sorbent without aluminium was synthesized synchronously as a comparison sample to investigate the effect of aluminium addition on the desulphurization properties. The surface acidity of the sorbents is enhanced by the addition of aluminium, and the sulphur capacity of the aluminium‐doped sorbent is consequently lower compared to that of aluminium‐free sorbent. Nevertheless, the aluminium‐doped sorbent shows a significant advantage in stability of performance over multiple desulphurization–regeneration cycles and reaches an 81% retention rate of sulphur capacity after five desulphurization, while the aluminium‐free sorbent is only 51% in contrast. The characterization results manifest that aluminium enters the carrier skeleton and increases the wall thickness, which alleviates the collapse of the carrier pore channels and the agglomeration of the active components during the desulphurization process. Stable pore structures and highly dispersed active components facilitate the mass transfer in the reaction process after multiple desulphurization. As a result, the aluminium‐doped sorbent exhibits better performance stability in high temperature coal gas desulphurization. [ABSTRACT FROM AUTHOR]

Published

2024

28. 鄂尔多斯盆地西缘奥陶系乌拉力克组页岩气 地球化学特征与成因.

Author

李福奇, 王晓锋, 刘文汇, 黄正良, 张东东, 李孝甫, 李风娇, and 陈晓艳

Subjects

GAS reservoirs, NATURAL gas, OIL shales, NATURAL gas prospecting, COAL gas, SHALE gas, COALBED methane

Abstract

Copyright of Natural Gas Geoscience is the property of Natural Gas Geoscience and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

29. 鄂尔多斯盆地南部古生界天然气地球化学 特征与成因.

Author

张 涛, 王晓锋, 金晓辉, 孟庆强, 王怡然, 陈晓艳, 张 雯, and 张 隽

Subjects

CARBON isotopes, COAL gas, PALEOZOIC Era, ORGANIC compounds, ETHANES, NATURAL gas

Abstract

Copyright of Natural Gas Geoscience is the property of Natural Gas Geoscience and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

30. Study on the Coupling Characteristics of Infrasound–Temperature–Gas in the Process of Coal Spontaneous Combustion and a New Early Warning Method.

Author

Liang, Yuntao, Song, Shuanglin, Guo, Baolong, Gao, Liyang, Liu, Jifan, Lu, Wei, Wang, Wei, and Kong, Biao

Subjects

SPONTANEOUS combustion, COAL combustion, DEBYE temperatures, TEMPERATURE inversions, COAL gas

Abstract

The phenomenon of coal spontaneous combustion poses a serious threat to mine safety, and monitoring and warning of coal spontaneous combustion has become an important issue that needs to be urgently addressed in coal mines. The current monitoring and early warning methods for coal spontaneous combustion have their limitations, and a single indicator cannot accurately mark the degree of coal spontaneous combustion danger inside the goaf. Therefore, this article proposes a new method for monitoring coal spontaneous combustion through infrasound waves. Infrasound waves have advantages such as low attenuation and long transmission distance. However, current research on monitoring and warning coal spontaneous combustion in goaf through infrasound waves is not yet complete, and there is a lack of research on the characteristics of infrasound signal changes during coal spontaneous combustion. Based on this, the article first tested the characteristic temperature and release changes of indicator gases (CO, C2H4) through thermogravimetric experiments and coal oxidation and heating experiments. Then, the generation and variation of infrasonic signals during coal spontaneous combustion (CSC) was studied and analyzed using a self-designed CSC infrasonic testing system. The results showed that obvious infrasound signals could be generated during the CSC process, there is a good mapping relationship between signals and temperature. Furthermore, the analysis revealed the inherent relationship between the infrasonic signal, temperature, and indicator gas of coal at different oxidation stages. The research in this article has promoted the use of infrasound waves for temperature inversion and promoted the development of multi-parameter analysis and early warning of CSC, which is of great significance for the field of CSC monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

31. Temperature Reduction Characteristics of Coal with Different Moisture Contents During Cryogenic Treatment.

Author

Zhang, Siqi, Wang, Zhaofeng, Ma, Xingying, Qi, Lingling, Li, Shijie, and Chen, Yanqi

Subjects

COAL reserves, FROST heaving, POROSITY, COAL gas, COAL

Abstract

To investigate the effect of moisture content on coal in cryogenic treatment, based on a gas-containing coal cryogenic treatment simulation testing system and an automated mercury intrusion porosimeter, temperature changes, strains, and characteristic parameters of the pore structure of coal after cryogenic treatment were determined. In addition, a thermal–water–mechanical coupling theoretical model was established using COMSOL software to simulate the changes in temperature and volume of coal. It was observed that moisture content was correlated negatively with the rate of temperature drop of coal and correlated positively with the frost heave strain. After cryogenic treatment, the final volume of coal decreased and the pores increased. The experiment revealed that frost heave heat extended the temperature stabilization time by an average of 27%, while methane adsorption heat had almost no effect. It is recommended to control the moisture content of coal at around 5% when using cryogenic treatment for anti-outburst, while for frozen coring, the moisture content should be controlled below 3%. The research results provide significant understanding of changes caused by cryogenic treatment on coal and supply practical information for optimizing the industrial production application of cryogenic treatment on coal. [ABSTRACT FROM AUTHOR]

Published

2024

32. Statistical Study of the Characteristics of Coal Spontaneous Combustion Gases and Temperature.

Author

Zhongyu, Liu, Qing, Guo, and Wanxing, Ren

Subjects

SPONTANEOUS combustion, COAL combustion, COMBUSTION gases, DEBYE temperatures, COAL gas

Abstract

The occurrence of coal spontaneous combustion has a significant impact on both the safety of personnel and mine recovery. In order to establish an early warning system for combustion, it is crucial to develop a mathematical model that characterizes indicator gases and coal temperature. In this study, we investigated the O2, CO, and CO2 characteristics of data collected from a goaf beam pipe in the Mengcun mine. Our findings demonstrate a linear decrease in O2 concentration with goaf depth and a strong negative correlation between CO and O2. We observed that CO/∆O2 and CO/CO2 increased to a maximum and then decreased as the goaf depth increased. Furthermore, we found that the peaks of these parameters at the same sampling point corresponded to the same goaf depth, and both occurred at the junction between the air-leakage and oxidation zones. By using a logistic model to fit the CO and C2H4 data, we developed a model that characterizes the relationships among CO, C2H4, and coal temperature based on statistical laws. The model provides direct information about the inflection point temperatures of C2H4 and CO, with the former being slightly lower within the same coal sample. The overall difference between the inflection point temperatures is relatively small, about 10°C. The initial temperature ratio of C2H4 and CO remains essentially constant at 3.8. C2H2 concentrations are low and irregular, and the presence of this gas can be used to assess when coal enters the accelerated oxidation stage. This research result provides a new research view for elucidating the distribution characteristics of coal spontaneous combustion index gas. [ABSTRACT FROM AUTHOR]

Published

2024

33. What determines the boundaries of H2O maser emission in an X-ray illuminated gas disc?

Author

Kuo, C Y, Gao, F, Braatz, J A, Pesce, D W, Humphreys, E M L, Reid, M J, Impellizzeri, C M V, Henkel, C, Wagner, J, and Wu, C E

Subjects

*COAL gas, *MASERS, *GAS distribution, *HUBBLE constant, *ACTIVE galaxies

Abstract

High precision mapping of H |$_{2}$| O megamaser emission from active galaxies has revealed more than a dozen Keplerian H |$_{2}$| O maser discs, which enable a |$\sim$| 4 per cent uncertainty estimate of the Hubble constant as well as providing accurate masses for the central black holes. These discs often have well-defined inner and outer boundaries of maser emission on sub-parsec scales. In order to better understand the physical conditions that determine the inner and outer radii of a maser disc, we examine the distributions of gas density and X-ray heating rate in a warped molecular disc described by a power-law surface density profile. For a suitable choice of the disc mass, we find that the outer radius |$R_{\rm out}$| of the maser disc predicted from our model can match the observed value, with |$R_{\rm out}$| mainly determined by the maximum heating rate or the minimum density for efficient maser action, depending on the combination of the Eddington ratio, black hole mass, and disc mass. Our analysis also indicates that the inner radius for maser action is comparable to the dust sublimation radius, suggesting that dust may play a role in determining the inner radius of a maser disc. Finally, our model predicts that H |$_{2}$| O gigamaser discs could exist at the centres of high-z quasars, with disc sizes of |$\gtrsim 10-30$| pc. [ABSTRACT FROM AUTHOR]

Published

2024

34. The Establishment of the Great Central Gas Consumers’ Company in Mid-Nineteenth-Century London.

Author

Sun, Chaojing and Liu, Cheng

Subjects

*INDUSTRIALISM, *GAS companies, *MIDDLE class, *COAL gas, *SOCIAL problems, *MONOPOLIES

Abstract

The Great Central Gas Consumers’ Company (GCGCC) was established by the metropolitan middle class to address the detrimental effects of gas industry monopoly through the promotion of market competition. It revealed that the middle class staunchly advocated for the use of liberalism to safeguard their own rights and interests, coinciding with Britain’s wider acceptance of liberalism and echoing the clarion call of the era of liberalism. Government engagement and interference in the formation of the GCGCC, as well as the ensuing disputation around it, could be seen as a manifestation of the principle of liberalism rather than a violation thereof. It reflected that liberalism was neither the absence of government nor total laissez-faire. The fact that the old gas companies adjusted their positions and compromised in favour of liberal principles demonstrated the more flexible response mechanisms of the modern industrial system to industrial and social problems, as well as the significant influence of liberalism on the development of the British industrial sector and society as a whole. [ABSTRACT FROM AUTHOR]

Published

2024

35. Research on Optimization Model of Coal Mine Gas and Coal Dust Monitoring and Control Based on Data Acquisition.

Author

Zhou, Qiang and Zeng, Jiaxing

Subjects

FLAMMABLE limits, DUST explosions, COAL mining accidents, COAL mining safety, COAL gas, COAL dust

Abstract

The situation of coal mine safety production is still quite severe. Most coal mine accidents are caused by gas or coal dust explosion. Therefore, the monitoring and control of underground gas and coal dust is the key link to realize coal mine safety production. In this paper, through the data acquisition, processing and calculation of the monitored values, the corresponding optimization model and the optimization calculation formula of absolute gas emission and relative gas emission are obtained. Through the given data, the absolute gas emission and relative gas emission of each monitoring point in the coal mine are calculated every day. The absolute gas emission and relative gas emission of the total return air roadway are used to identify whether the mine belongs to "low" or "high" gas mine. Considering the possibility of gas explosion and coal dust explosion, the deviation degree between coal dust and the lower explosion limit of coal dust under the influence of gas concentration is cited to measure. The table shows the unsafe degree corresponding to different gas concentration and coal dust concentration. Through the diversion of air volume in each shaft and roadway, it is determined that the best total ventilation volume is the sum of the air volume of inlet roadway I and II and the roadway where the local fan is located (including the air volume of the local fan).Under the simplified assumption, the model is evaluated, popularized and improved through error analysis. [ABSTRACT FROM AUTHOR]

Published

2024

36. Disaster-causing mechanisms of gas migration under loading and unloading conditions.

Author

Peng, Kang, Shi, Shaowei, Liu, Hao, Ma, Chunde, Tian, Shixiang, and Wang, Yunqiang

Subjects

COALBED methane, GAS migration, GAS bursts, COAL mining, COAL gas

Abstract

The aim of studying the mechanisms of coal and gas outbursts is to master the occurrence and development process of outbursts and to determine the reasons and conditions for outburst occurrence. Gas permeability is an important parameter for characterizing the difficulty of gas migration in a coal seam and an important factor in studying coal and gas outbursts. By utilizing a THM-2 type thermo-fluid-solid coupling test system of gas-bearing coal developed at Chongqing University, China, gas-bearing coal was experimentally investigated under loading and unloading paths. The results demonstrate that permeability is significantly affected by stress paths and gradually decreases with an increase in stress. The permeability of coal samples under unloading increased with the number of loading and unloading cycles and the irreversible strain was negatively correlated with permeability. In situ stress mainly affects the difficulty of migration and the flow direction of gas in the coal seam by controlling the pore and fracture systems of the coal mass. The point of maximum bearing pressure is the boundary point of the gas migration direction. In the coal mining process, mining activities break the in-situ stress state and induce stress concentration. As the mining face advances, the abutment pressure curve shifts to the deep part of the coal seam as does the permeability. Gas is prone to accumulate in the area between the maximum abutment pressure and the in situ stress zone, which increases the gas concentration, thus forming a zone with increased outburst risks. Highlights: The direction of gas transportation in the coal seam was determined, and a model was established. The gas migration in the coal seam is divided into different areas. It was found that the maximum supporting pressure point is the boundary point of the direction of gas migration, which is the main factor that makes gas migration difficult. [ABSTRACT FROM AUTHOR]

Published

2024

37. High-efficiency and precision gas extraction in intelligent mining faces: Application of a comprehensive three-dimensional extraction system.

Author

Lu, Zhuang, Wang, Liang, Fu, Shenguang, Chu, Peng, Zhu, Zibin, Wang, Hao, Zhao, Changxin, Wu, Songwei, and Cheng, Yuanping

Subjects

*GAS well drilling, *GAS extraction, *COAL mining, *COAL gas, *EXTRACTION techniques, *GAS bursts

Abstract

As intelligent mining operations evolve, stringent standards for gas management and extraction are imperative. To mitigate the risks associated with coal and gas outburst and to prevent gas concentration from exceeding safe limits, a comprehensive three-dimensional gas extraction system is introduced. This method, exemplified by the 1075 intelligent working face at the Yangliu coal mine, integrates temporal and spatial considerations for comprehensive extraction. Utilizing COMSOL and UDEC simulations, the extraction parameters for both pre-extraction and mid-mining extraction have been meticulously optimized. The optimal strategy involves boreholes with a diameter of 113 mm, spaced 3 m apart, and an initial negative pressure of 31 kPa, which is subsequently reduced to 13 kPa as gas levels decrease. The positioning of directional high-level boreholes is determined by the fracture zone distribution in the goaf's overlying strata, placed 19–25 m above the roof and 0–65 m from the return airway. Directional interception boreholes are optimally located 54–73 m above the roof. Surface wells are strategically positioned 15 m above the roof, with a horizontal distance of 30–65 m from the return airway. After extraction of the system, the maximum gas concentrations recorded in the return airway and the upper corner are 0.26% and 0.27%, respectively. The average daily production reached 5258 t, nearly doubling the overall efficiency. This gas extraction technique not only enhances the efficiency of intelligent mining operations but also serves as a valuable reference for future research in the field. [ABSTRACT FROM AUTHOR]

Published

2024

38. Coal-rock gas: Concept, connotation and classification criteria.

Author

LI, Guoxin, ZHANG, Shuichang, HE, Haiqing, HE, Xinxing, ZHAO, Zhe, NIU, Xiaobing, XIONG, Xianyue, ZHAO, Qun, GUO, Xujie, HOU, Yuting, ZHANG, Lei, LIANG, Kun, DUAN, Xiaowen, and ZHAO, Zhenyu

Subjects

NATURAL gas prospecting, COAL gas, SHALE gas, PETROLEUM reservoirs, GAS reservoirs, COALBED methane, NATURAL gas production

Abstract

In recent years, great breakthroughs have been made in the exploration and development of natural gas in deep coal-rock reservoirs in Junggar, Ordos and other basins in China. In view of the inconsistency between the industrial and academic circles on this new type of unconventional natural gas, this paper defines the concept of "coal-rock gas" on the basis of previous studies, and systematically analyzes its characteristics of occurrence state, transport and storage form, differential accumulation, and development law. Coal-rock gas, geologically unlike coalbed methane in the traditional sense, occurs in both free and adsorbed states, with free state in abundance. It is generated and stored in the same set of rocks through short distance migration, occasionally with the accumulation from other sources. Moreover, coal rock develops cleat fractures, and the free gas accumulates differentially. The coal-rock gas reservoirs deeper than 2 000 m are high in pressure, temperature, gas content, gas saturation, and free-gas content. In terms of development, similar to shale gas and tight gas, coal-rock gas can be exploited by natural formation energy after the reservoirs connectivity is improved artificially, that is, the adsorbed gas is desorbed due to pressure drop after the high-potential free gas is recovered, so that the free gas and adsorbed gas are produced in succession for a long term without water drainage for pressure drop. According to buried depth, coal rank, pressure coefficient, reserves scale, reserves abundance and gas well production, the classification criteria and reserves/resources estimation method of coal-rock gas are presented. It is preliminarily estimated that the coal-rock gas in place deeper than 2 000 m in China exceeds 30x1012 m3, indicating an important strategic resource for the country. The Ordos, Sichuan, Junggar and Bohai Bay basins are favorable areas for large-scale enrichment of coal-rock gas. The paper summarizes the technical and management challenges and points out the research directions, laying a foundation for the management, exploration, and development of coal-rock gas in China. [ABSTRACT FROM AUTHOR]

Published

2024

39. Effect of gas pressure and particle size on dynamic diffusion-adsorption characteristics of CO2 in coal.

Author

ZHANG Zunguo, LI Dandan, CHEN Yi, and TANG Chao

Subjects

GAS dynamics, DIFFUSION coefficients, ATTENUATION coefficients, DYNAMIC pressure, COAL gas

Abstract

This study investigates the influence mechanism of particle size and gas pressure on the dynamic diffusion law of CO2 in coal. We used a self-developed high pressure adsorption and desorption experimental system for coal seam to analyze the dynamic adsorption-diffusion characteristics before the adsorption equilibrium of gas in coal based on the volumetric adsorption experiment,which was combined with the classical single hole diffusion model to calculate the CO2 diffusion coefficient at different times. The results show that the adsorption equilibrium time is positively correlated with the coal particle size,and decreases with the increase of adsorption equilibrium pressure. Larger coal particle size would result in more obvious decreasing trend. The effective diffusion coefficient is found to be more effective than the diffusion coefficient in explaining the relationship between particle size and equilibrium time. Smaller particle size would result in higher effective diffusion coefficient and shorter adsorption equilibrium time. The effective diffusion coefficient shows a power function with time. The initial effective diffusion coefficient (De0) and effective diffusion attenuation coefficient (β) both decrease with the increase of particle size. De0 first increases and then decreases with the increase of equilibrium pressure, and the β exhibits varying relationships with the increase of equilibrium pressure depending on different particle sizes of the coal. Smaller particle size would result in better connectivity between the pores of coal,leading to shorter diffusion paths of gas molecules and lower diffusion resistance,thus more facilitated to adsorption. Gas pressure poses a driving effect on CO2 adsorption and diffusion,but with the continuous adsorption of coal samples,the coal matrix expands and blocks the pores,leading to a narrowing of the diffusion channel and diminished driving effects. [ABSTRACT FROM AUTHOR]

Published

2024

40. 药剂协同强化不连沟煤泥浮选试验研究.

Author

韩　伟, 牛　耀, 程　上, 李　斌, 王　磊, 刘文礼, 卓启明, 刘国杰, and 何静谊

Subjects

CONTACT angle, HYDROPHILIC surfaces, DRUG dosage, COAL gas, PARTICULATE matter

Abstract

Copyright of China Mining Magazine is the property of China Mining Magazine Co., Ltd. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

41. The Pore Structure Multifractal Evolution of Vibration-Affected Tectonic Coal and the Gas Diffusion Response Characteristics.

Author

Shen, Maoliang, Huo, Zhonggang, Shu, Longyong, Li, Qixian, Zhang, Pengxin, and Wang, Weihua

Subjects

PORE size distribution, POROSITY, GAS bursts, FREQUENCIES of oscillating systems, COAL gas

Abstract

Vibrations caused by downhole operations often induce coal and gas outburst accidents in tectonic zone coal seams. To clarify how vibration affects the pore structure, gas desorption, and diffusion capacity of tectonic coal, isothermal adsorption-desorption experiments under different vibration frequencies were carried out. In this study, high-pressure mercury intrusion experiments and low-pressure liquid nitrogen adsorption experiments were conducted to determine the pore structures of tectonic coal before and after vibration. The pore distribution of vibration-affected tectonic coal, including local concentration, heterogeneity, and connectivity, was analyzed using multifractal theory. Further, a correlation analysis was performed between the desorption diffusion characteristic parameters and the pore fractal characteristic parameters to derive the intrinsic relationship between the pore fractal evolution characteristics and the desorption diffusion characteristics. The results showed that the vibration increased the pore volume of the tectonic coal, and the pore volume increased as the vibration frequency increased in the 50 Hz range. The pore structure of the vibration-affected tectonic coal showed multifractal characteristics, and the multifractal parameters affected the gas desorption and diffusion capacity by reflecting the density, uniformity, and connectivity of the pore distribution in the coal. The increases in the desorption amount (Q), initial desorption velocity (V0), initial diffusion coefficient (D0), and initial effective diffusion coefficient (De) of the tectonic coal due to vibration indicated that the gas desorption and diffusion capacity of the tectonic coal were improved at the initial desorption stage. Q, V0, D0, and De had significant positive correlations with pore volume and the Hurst index, and V0, D0, and De had negative correlations with the Hausdorff dimension. To a certain extent, vibration reduced the local density regarding the pore distribution in the coal. As a result, the pore size distribution was more uniform, and the pore connectivity was improved, thereby enhancing the gas desorption and diffusion capacity of the coal. [ABSTRACT FROM AUTHOR]

Published

2024

42. Research on Intelligent Design and Visualization of Gas Extraction Drilling Based on PSO–LSTM.

Author

Yin, Yongming, Wang, Dacang, Zhu, Quanjie, Yang, Guangyu, Chen, Xuexi, Liu, Xiaohui, and Liu, Yongfeng

Subjects

GAS well drilling, GAS extraction, COAL mining, COAL gas, INTELLIGENCE levels

Abstract

Under the background of intelligent construction of coal mines, gas extraction design is still based on manual design, which is complex, time–consuming, and error–prone, and its automation degree needs to be improved. In order to solve this problem, taking the 1302 working face of a mine in Shanxi Province as the research object, this paper carried out relevant research. Firstly, the influencing factors of gas extraction were determined, and the influence rules of different parameters on the extraction effect were studied by numerical simulation. Secondly, an intelligent optimization method of gas extraction drilling parameters based on deep mining called the PSO–LSTM model, is proposed. This model uses the PSO algorithm to optimize the parameters of the LSTM model, so as to improve the accuracy of the LSTM model results. Finally, a quantitative expression algorithm of 3D spatial information of gas extraction drilling holes based on Python is proposed, which can automatically generate 3D spatial models of bedding or through gas extraction drilling holes using optimized drilling parameters and known 3D information of coal seams. This study shows that the results obtained using the PSO–LSTM model are the same as the drilling parameters obtained using numerical simulation, which verifies the accuracy of the PSO–LSTM model. According to the optimized drilling parameters, a 3D model of gas extraction drilling is quickly generated, which greatly reduces the tedious work of drawing construction drawings for coal mine enterprises and improves the intelligence level of coal gas extraction drilling. [ABSTRACT FROM AUTHOR]

Published

2024

43. Experimental Study on the Effect of Unloading Paths on Coal Damage and Permeability Evolution.

Author

Hao, Congmeng, Wang, Youpai, and Liu, Guangyi

Subjects

GAS well drilling, INTERNAL friction, COAL gas, GAS extraction, TEST systems, CAVITATION erosion, COAL gasification

Abstract

Coal seam cavitation is one of the most effective techniques for gas disaster control in low-permeability coal. Due to the difference in cavitation method and process, the damage degree and fracture development range of the coal body around the cavern are greatly different, and the effect of increasing the permeability of the coal body is further changed. In order to further understand the permeability enhancement mechanism of cavitation technology on low-permeability coal and effectively guide engineering applications, this paper conducted experimental research on the unloading damage and permeability evolution characteristics of coal under different cavitation paths using a coal-rock "adsorption-percolation-mechanics" coupling test system. Through the analysis of coal strength and deformation characteristics, coal damage characteristics, and the evolution law of coal permeability combined with the macroscopic damage characteristics of coal, the strength degradation mechanism of unloaded coal and the mechanism of increased permeability and flow were revealed. The results show that unloading can significantly reduce the strength of coal, and the greater the unloading rate, the more obvious the reduction. The essence of this is that unloading reduces the cohesion and internal friction angle of coal—damage and breakage are the most effective ways to improve the permeability of the coal body. Unloading damaged coal bodies not only significantly improves the permeability of the coal body but also improves the diffusion ability of gas, and finally, shows a remarkable strengthening effect of gas extraction. [ABSTRACT FROM AUTHOR]

Published

2024

44. A Study on the Effect of Different Charge Structures on the Permeability Enhancement of Coal Seam Blasting.

Author

Zuo, Yunfei, Zhang, Jianyu, Yang, Lidong, Wang, Feiran, and Wang, Zhengang

Subjects

BLAST effect, GAS well drilling, GAS extraction, COAL gas, BLASTING

Abstract

With the increasing depth of coal mining, the ground stress of coal seams rises, the gas content rises, and the permeability decreases, which is unfavorable to gas extraction and increases the possibility of gas accidents in coal mines. Blasting technology is often used to improve the permeability of coal seams and increase the effect of gas extraction, but it is difficult to control the blasting effect of ordinary flux coils, and the direction of the fissure and the degree of development of randomness, so it is important to study the effect of different flux coil structures on the blasting of coal seams to increase the permeability of the coal seam, in this paper, first of all, through the numerical simulation to analyze the effect of the blasting of the ordinary structure flux coils and the fissure change in the polygonal structure flux coils, and then make the experimental module. Then, we make the test module, build the test platform, and analyze the effect of blasting penetration of different drug coil structures by comparing the strain after blasting and the change in resistivity before and after blasting of two kinds of drug coil structures, and the results show that the polymerized drug coil can play the role of directional fracturing, and compared with the ordinary structure of the drug coil, the polymerized drug shows a better effect of fracturing and penetration increase. [ABSTRACT FROM AUTHOR]

Published

2024

45. Research on Gas Drainage Pipeline Leakage Detection and Localization Based on the Pressure Gradient Method.

Author

Zhang, Huijie, Shen, Maoliang, Huo, Zhonggang, Zhang, Yibin, Shu, Longyong, and Li, Yang

Subjects

GAS leakage, MINE drainage, LEAK detection, COAL gas, COAL mining

Abstract

Pipeline leakage seriously threatens the efficient and safe gas drainage in coal mines. To achieve the accurate detection and localization of gas drainage pipeline leakages, this study proposes a gas drainage pipeline leakage detection and localization approach based on the pressure gradient method. Firstly, the basic law of gas flow in the drainage pipeline was analyzed, and a pipeline network resistance correction formula was deduced based on the pressure gradient method. Then, a drainage pipeline model was established based on the realizable k - ε turbulence model, and the pressure and flow velocity distribution during pipeline leakage under different leakage degrees, leakage locations, and pipeline negative pressures were simulated and analyzed, thus verifying the feasibility of the pipeline leakage detection and localization method. It is concluded that the positioning errors of pipeline leakage points under different leakage degrees, different leakage positions, and different pipeline negative pressures were 0.88~1.08%, 0.88~1.49%, and 0.68~0.88%, respectively. Finally, field tests were conducted in the highly located drainage roadway 8421 of the Fifth Mine of Yangquan Coal Industry Group to verify the accuracy of the proposed pipeline leakage detection and localization method, and the relative error was about 8.2%. The results show that with increased pipeline leakage hole diameters, elevated pipeline negative pressures, and closer leakage positions to the pipeline center, the relative localization error was smaller, the localization accuracy was higher, and the stability was greater. The research results could lay the foundation for the fault diagnosis and localization of coal mine gas drainage pipeline networks and provide technical support for safe and efficient coal mine gas drainage. [ABSTRACT FROM AUTHOR]

Published

2024

46. Research on Wave Velocity Disparity Characteristics between Impact and Outburst Coal Seams and Tomography of Hazardous Zones.

Author

Fang, Zhixin, Liu, Qiang, Qiu, Liming, Yang, Zhanbiao, Cao, Zhaohui, Wang, Guifeng, Niu, Zehua, and Zhao, Yingjie

Subjects

ROCK bursts, GAS bursts, COAL gas, STRESS concentration, COAL

Abstract

To investigate the variations in wave velocity fields between impact and outburst coal seams, we analyzed the fluctuations in wave velocity under loading conditions for both coal types. A comprehensive methodology was developed to correct coal wave velocities in response to stress and gas presence, which was then applied to field assessments of hazardous regions. Our findings reveal significant differences in wave velocity alterations between impact and outburst coal seams during loading-induced failure. Gas pressure exhibits a negative correlation with wave velocity in outburst coal (correlation coefficient R2 = 0.86), whereas wave velocity in impact coal demonstrates a positive correlation with stress (R2 = 0.63). A robust methodology for correcting coal wave velocities in response to stress and gas presence was established to enable more accurate measurement of wave velocity changes. In field applications, seismic wave computed tomography identified stress anomalies that closelycorresponded with geological structures and mining operations, effectively pinpointing hazardous zones. The abnormal wave velocity coefficient ranges for outburst coal seams and impact coal seams are −0.6 to 0.25 and −0.35 to 0.16, respectively, which correspond well with the field stress distribution. [ABSTRACT FROM AUTHOR]

Published

2024

47. 基于程序升温试验的煤自燃特性及微观机理研究.

Author

刘垚, 王福生, 董轩萌, and 高东

Subjects

SPONTANEOUS combustion, OXYGEN detectors, REACTIVE oxygen species, MOLECULAR dynamics, COAL gas, LIGNITE

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

48. 基于小波散射变换的煤矿瓦斯和煤尘爆炸声音识别方法.

Author

余星辰 and 李小伟

Subjects

DUST explosions, MINES & mineral resources, COAL mining, SOUND wave scattering, COAL gas, COAL dust

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

49. 造穴−CO2 气相压裂复合技术造缝卸压增渗机理研究.

Author

闫志铭, 张新生, 张军胜, 杨百舸, 曹运兴, 李淑敏, and 董润平

Subjects

STRESS waves, GAS bursts, COAL mining, STRESS concentration, COAL gas

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

50. 构造煤质量占比对 CH4 吸附热力学特征参数演化规律的影响研究.

Author

赵鹏翔, 易春艳, 李树刚, 刘妍群, and 贾永勇

Subjects

GAS absorption & adsorption, COAL mining, THERMODYNAMIC laws, ADSORPTION capacity, COAL gas, GIBBS' free energy

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024