Your search keyword '"SPONTANEOUS combustion"' showing total 6,252 results

1. Effect of Initial Pyrolysis on Radical Reaction During Coal Spontaneous Combustion.

Author

Jiang, Xiaoyuan, Yang, Shengqiang, Zhou, Buzhuang, Lan, Lin, and Chu, Tingxiang

Subjects

SPONTANEOUS combustion, COAL combustion, COAL pyrolysis, COAL mining, IGNEOUS intrusions

Abstract

Coal in high-temperature deep mines or igneous intrusion mines is prone to complicated spontaneous combustion in the mining process, because it has occurred in a pyrolysis state for a long time. In order to investigate the effect of initial pyrolysis on coal oxidation, in this study, the coal samples were first pyrolyzed to different temperatures in the nitrogen atmosphere and then oxidized in the dry air atmosphere. Meanwhile, the changes in radical parameters (linewidth of ESR spectra, g factor and radical concentration), CO release and O2 content in the process of changing the states of coal samples from pyrolysis to oxidation at 70°C, 110°C, 150°C and 190°C were determined through experiments. The following conclusions were drawn: When the coal samples change from the pyrolysis state to the oxidation state, their linewidths of ESR spectra increase suddenly, and such an increase is more obvious when the change is made at a lower temperature. The linewidth increases by more than 0.066 mT after the change at a temperature lower than 110°C. Initial pyrolysis promotes the turning point temperature of g factor, and the turning point temperatures of g factor of coal after the gas atmosphere is changed from nitrogen to dry air at 70°C, 110°C, 150°C and 190°C are 160°C, 180°C, 190°C and 200°C, respectively. The growth rate of radical concentration surges after the change from the pyrolysis state to the oxidation state, and the radical concentrations of the coal samples whose states are changed after 150°C grow faster than that of the coal sample oxidized in dry air. When the temperature is lower than 110°C, the CO release under the pyrolysis and oxidation conditions is low, the maximum value being only 105 ppm. At the final temperature of 230°C, when the gas atmosphere is changed from nitrogen to dry air at 70°C, 110°C, 150°C and 190°C, the CO produced by coal is 14,386 ppm, 13220 ppm, 11836 ppm and 10,287 ppm, respectively. The mode of the effect of initial pyrolysis on coal spontaneous combustion was discussed in the end, and the conclusions are of guiding significance for coal spontaneous combustion control. [ABSTRACT FROM AUTHOR]

Published

2024

2. Spontaneous Combustion Characteristic Stages of Active FeS and Its Inhibition Effect by Gas-Phase Passivation.

Author

Xu, Qin, Gao, Jiancun, Yang, Shengqiang, Wu, Siyuan, Jia, Shaokang, Sui, Hongbin, and Hao, Ruixuan

Subjects

SPONTANEOUS combustion, CHEMICAL kinetics, OXIDE coating, ACTIVATION energy, WEIGHT gain

Abstract

To explore the spontaneous combustion characteristic stages of active ferrous sulfide (FeS) and its inhibition effect by gas-phase passivation. Active FeS samples were prepared and then the spontaneous combustion characteristics of active FeS and commercial FeS samples were compared. The active FeS spontaneous combustion process was divided into several characteristic stages from the perspective of spontaneous combustion kinetics. Furthermore, the inhibition effect of gas-phase passivation on the characteristic stages and the kinetics and thermal effects of active FeS spontaneous combustion process were investigated to further reveal the inhibition mechanism. The results indicate that spontaneous combustion process of active FeS is divided into the room temperature (RT) spontaneous combustion, oxygen-adsorption-induced weight gain, high-temperature combustion and burnout stages, while the spontaneous combustion process of commercial FeS excludes the RT spontaneous combustion stage. Active FeS presents greatly advanced characteristic stages, stronger spontaneous combustion reactivity and more intense reaction in the RT spontaneous combustion and high-temperature combustion stages, which agrees more with the sulfur corrosion products under actual on-site working conditions. The spontaneous combustion tendency of passivated FeS weakens gradually with the increase of passivation time until it loses its RT spontaneous combustion reactivity after 6 h passivation. After the oxide film formed on the surface of passivated FeS is destroyed, its high-temperature combustion reaction becomes relatively intense. The activation energy of passivated FeS in the spontaneous combustion reaction is much higher than that of active FeS, and their activation energies both soar with the deepening of passivation, indicating that the gas-phase passivation technology can effectively inhibit the FeS spontaneous combustion process. The gas-phase passivation time must be maintained for over 6 h despite the weakening inhibitory effect of passivation treatment on the FeS spontaneous combustion process. [ABSTRACT FROM AUTHOR]

Published

2024

3. Inhibiting Effect of Ionic Liquids on Long-Flame Coal Spontaneous Combustion Through Thermokinetic and Microstructure.

Author

Gao, Hong

Subjects

SPONTANEOUS combustion, COAL combustion, IGNITION temperature, PEARSON correlation (Statistics), AROMATIC compounds

Abstract

To explore the inhibiting effect of ionic liquids (ILs) on coal spontaneous combustion (CSC), the long-flame coal was treated by [BMIM][BF4], [BMIM][NO3], [BMIM][I], [EMIM][BF4], and [BMIM][AcO], the thermogravimetric analyzer and FTIR spectrometer were adopted, and they were used to analyze functional groups and mass loss properties of each sample. The combustion and thermokinetic characteristics were obtained at four heating rates, and the relation between each functional group and apparent activation energy was received. The results indicated that, the content of -OH, -CO-O-, -COO-, and aromatic hydrocarbon -CH in ILs-treated coals reduced conspicuously, and the content of C-O and aromatic ring C=C enhanced. Meanwhile, the mass maximum temperature and ignition temperature for ILs-treated coals was delayed, their reaction capacity was weakened markedly. In addition, their apparent activation energy enhanced, in which [BMIM][BF4] showed a higher apparent activation energy. The active group for -COO-, aromatic hydrocarbon -CH, and hydroxyls were main parameters affecting the CSC characteristics by Pearson correlation coefficient method. Those findings guidance for the efficient application of ILs on field of CSC. [ABSTRACT FROM AUTHOR]

Published

2024

4. Influence of Water Immersion Time on Re-Ignition Characteristics of High Temperature Oxidized Coal.

Author

Bu, Yun-Chuan, Niu, Hui-Yong, Wang, Hai-Yan, Fu, Qi, Qiu, Tian, and Yang, Yan-Xiao

Subjects

SPONTANEOUS combustion, WATER immersion, ELECTRON paramagnetic resonance, POROSITY, OXIDATION of water, COAL combustion, CHEMICAL bonds

Abstract

After a coal seam is mined, the oxidized coal left in its goaf is prone to water immersion, and spontaneous combustion accidents involving water-immersed coal may easily occur when mining the underlying coal seam. Using scanning electron microscopy and nitrogen adsorption experimental methods, the physical structure of high-temperature pre-oxidized water-immersed coal samples was characterized. By means of infrared spectroscopy, electron spin resonance (ESR) and simultaneous thermal analysis, the microscopic characteristics of the coal samples and the endothermic and exothermic characteristics of the oxidative combustion process were studied. The results showed that a specific pre-oxidation soaking time generated more oxidation pores in the coal sample, causing more water to become trapped in the pores and increasing the secondary oxidation heat absorption. High-temperature oxidation promoted the conversion of coal sample functional groups (FG) and free radical active sites, Water immersion led to the formation and loss of FG, and the longer the water immersion time was, the greater the loss. The larger average pore size of the pre-oxidized water-immersed coal sample provided more coal-oxygen contact sites, and the breaking of chemical bonds in the FG during the secondary oxidation process accelerated the heat release and promoted the oxidative re-ignition of the coal sample. The spontaneous combustion of water-immersed coal in the goaf can be prevented by controlling the high oxidation temperature and water immersion time. [ABSTRACT FROM AUTHOR]

Published

2024

5. 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

6. Air Leakage Law and Prevention Technology of Coal Spontaneous Combustion in the Goaf of "Isolated Island" Fully Mechanized Caving Face.

Author

Ma, Li, Du, Su, He, Cheng-Mao, Guo, Rui-Zhi, and Tao, Wei-Guo

Subjects

SPONTANEOUS combustion, COAL combustion, AIRWAYS (Aeronautics), TECHNOLOGICAL innovations, GAS leakage

Abstract

The coal pillar along the goaf of the completely mechanized caving face of "Isolated Island" is severely damaged, with complex air leakage and a high risk of coal spontaneous combustion. In order to research the law of goaf air leakage in "Isolated Island" working face and effectively control the hidden threat of coal spontaneous combustion in goaf, it is necessary to investigate the goaf air leakage law. In this work, the 3302 "Isolated Island" entirely mechanized caving face of Jining No. 2 Coal Mine in Shandong province, China, served as an example. SF6 tracer gas air leakage measurement was utilized to identify the air leaking route in the goaf. In conjunction with the numerical modeling, the air leakage route surrounding the goaf was evaluated to establish the coal spontaneous combustion risk region, and the targeted prevention and controlled ways of coal spontaneous combustion were proposed. The results indicated that the primary source of air leakage was the seepage of air flow through the working face to the rear goaf and the diffusion to the adjacent goaf through the broken coal pillar. The risk area for coal spontaneous combustion was 40–80 m behind the rear goaf and 50 m within the coal pillar of the adjacent goaf. Regarding this region, the comprehensive prevention and control strategies of plugging and oxygen reduction, inerting and cooling, monitoring and forecasting were proposed. In addition, the fire prevention and extinguishing system combining slurry spraying, sodium silicate, and liquid CO2 injection was designed at both ends of the 3302 track and haulage roads. Using field measurements during the working face mining process, the corresponding methods for reducing the CO volume fraction in 3302 return air roadway and air return corner effectively prevented and controlled the hidden danger of coal spontaneous combustion in the goaf and ensured the safety of working face mining. This research developed a new technology for the prevention and management of coal spontaneous combustion in the goaf of the "Isolated Island" working face. [ABSTRACT FROM AUTHOR]

Published

2024

7. Evolutions of Oxidation Products and Free Radicals for Coal-Gangue Samples with Various Gangue Contents.

Author

Zhang, Yutao, Xia, Shangwen, Li, Yaqing, Ren, Mengru, Che, Bo, and Lu, Xu

Subjects

HEAT release rates, SPONTANEOUS combustion, FREE radicals, COAL combustion, OXYGEN consumption

Abstract

To investigate the influence of gangue left in goafs on the low-temperature oxidation characteristics of coal, the variations of gas products and free radical parameters of coal-gangue mixed samples with different gangue contents were tested. The results show the concentration of gas products is directly proportional to temperature and inversely proportional to gangue content (except the sample with 20% gangue content (G(20))). In addition, the oxygen consumption rate and heat release intensity follow a variation trend similar to that of gas product. Pure gangue corresponds to the highest apparent activation energy, 57.6 kJ/mol, and G(20) has the lowest value, 48.8 kJ/mol. With the rise of temperature, the free radical concentration of the mixed samples decreased slowly when it was lower than 90°C and higher than 210°C, and increased between 90°C and 210°C. Compared with the theoretical calculation results, the mixed samples all possess higher gas product, oxygen consumption rates, heat release intensities, free radical concentrations and lower apparent activation energy in the experiments, which indicates that gangue can remarkably promote the reaction of coal during low-temperature oxidation. As a result, the gangue left in goafs may promote the risk of coal spontaneous combustion. [ABSTRACT FROM AUTHOR]

Published

2024

8. Study on the Synergistic Antioxidant Effect of Coal Inhibitors and the DFT Calculation.

Author

Yin, Yichao, Zhang, Yinghua, Huang, Zhian, Ding, Hao, hu, Xiangming, gao, Yukun, and Yang, Yifu

Subjects

SPONTANEOUS combustion, QUANTUM chemistry, VITAMIN E, ALIPHATIC hydrocarbons, QUANTUM theory, HYDROPEROXIDES

Abstract

In order to improve efficiency when preventing and controlling spontaneous combustion of coal, a type of compound inhibitor with tea polyphenol and vitamin E as the chemical inhibitor, grafted on a copolymer hydrogel, was prepared. The oxidation resistance of the compound inhibitor to coal was analyzed by thermogravimetric test, Fourier infrared spectroscopy, and quantum chemistry theory. The experiment results showed that: The optimum ratio of tea polyphenols and vitamin E was 1:0.05; tea polyphenols and vitamin E inhibited the oxidation of coal by capturing the decomposition products of hydroperoxides and finally forming stable ether structures, and slowing down the hydrogen supply reaction between aliphatic hydrocarbons and carboxyl groups; the antioxidant properties of vitamin E (VE) and tea polyphenols (EGCG) were mainly due to the presence of active hydroxyl groups in the ring; H22 of VE and H38 of EGCG were able to inhibit the chain reaction of coal effectively. This study provides a new technical method for development of comprehensive fire prevention technology to address spontaneous combustion of coal, and provides a reference for the research into the inhibition mechanism of spontaneous combustion of coal. [ABSTRACT FROM AUTHOR]

Published

2024

9. Experimental Study on the Inhibitory Effect of Organic Phosphonic Acid Compound on Coal Spontaneous Combustion.

Author

Wang, Jiantao, Wang, Fusheng, Zhong, Xiaoxing, Sun, Meng, and Li, Lei

Subjects

SPONTANEOUS combustion, TRANSITION metal ions, COAL combustion, PHOSPHONIC acids, CHELATING agents

Abstract

The minerals in coal contain a certain amount of metal ions, among which transition metal ions have a catalytic effect on coal spontaneous combustion (CSC). Therefore, the addition of metal ion chelating agent to coal will weaken this catalytic effect, thereby inhibiting CSC. As a class of highly effective metal ion chelating agent, two kinds of organic phosphonic acid compounds (OPAC), 1-Hydroxy Ethylidene-1,1-Diphosphonic Acid (HEDP) and 2-Hydroxyphosphonoacetic Acid (HPAA), were investigated for their inhibitory effect on CSC. First, the low-temperature oxidation experiment was performed on coal samples before and after OPAC treatment. The experimental results show that HEDP and HPAA could reduce CO generation during spontaneous combustion of coal with different metamorphic degrees. Besides, the inhibiting efficiency of HEDP on CSC is higher than that of HPAA. Then, the effects of HEDP and HPAA on the thermal properties of CSC were investigated using synchronous thermal analysis experiment. The experimental results show that HEDP and HPAA could significantly weaken the oxygen adsorption, mass loss, and heat release during the high-temperature oxidation stage of CSC and exhibit the same result that HEDP is better than HPAA. Finally, the reasons for the difference in the inhibitory effects of HEDP and HPAA were analyzed and the inhibition mechanism of them on CSC was revealed via quantum chemical calculation. The results can provide new ideas for preventing CSC and developing new inhibitors. [ABSTRACT FROM AUTHOR]

Published

2024

10. Research on the Tracing and Fire Prevention Performance of New Mining Composite Gel.

Author

Cao, Huimin, Lu, Wei, Yin, Zhandong, Fu, Hainan, Mou, Xiaowei, Pan, Xingfeng, and Kong, Biao

Subjects

SODIUM carboxymethyl cellulose, SPONTANEOUS combustion, XANTHAN gum, COAL combustion, THERMAL coal

Abstract

A WG/C/XG (water glass/sodium carboxymethyl cellulose/xanthan gum) gel was created in this study by incorporating a tracer indicator into the fire protection material. The gel is both a tracer and flame retardant. First, scanning electron microscopy, UV spectrophotometer, and chromatography-mass spectrometer was used to characterize the samples. The microstructure of the WG/C/XG gel was investigated, as well as its impact on high-temperature response. The average rate of tracer gas release varies significantly before and after 55°C. Moreover, the release patterns of the two tracer gases are similar, indicating that the WG/C/XG gel is suitable for the solid loading of tracer gases. A thermal analyzer and programmed warming oxidation experiment analysis were used to investigate the inhibitory effect of WG/C/XG gel on the oxidation of spontaneous coal combustion. The experimental results demonstrated that the WG/C/XG gel improved the thermal stability of coal samples and inhibited spontaneous coal combustion. In mined areas, WG/C/XG gel is an excellent tracer material. [ABSTRACT FROM AUTHOR]

Published

2024

11. Study on the Performance of a Novel Highly Stable Nano-Hydroxyapatite Gel Foam to Inhibit Coal Spontaneous Combustion.

Author

Han, Chao, Nie, Shibin, Liu, Zegong, Yang, Jinian, Zhang, Hong, Li, Jiayi, and Zhang, Haoran

Subjects

SPONTANEOUS combustion, X-ray photoelectron spectroscopy, THERMAL coal, BLOCKCHAINS, METAL bonding, COAL combustion

Abstract

The preparation of gel foams with high stability for inhibiting coal spontaneous combustion remains a huge challenge. In this paper, a highly stable gel foam (SCTH) was developed by introducing nano-hydroxyapatite (HAP) into gel foam system (sodium alginate/calcium L-lactate/tannic acid/composite forming agent). The effects of HAP on the foam performances of SCTH were analyzed. The results showed that HAP could improve the stability of SCTH by forming hydrogen bonds, metal ion bonds with the system and interfacial barriers. After 100 days, SCTH without HAP had only 44.8% of the foam volume remaining. The SCTH with 1.2 wt% HAP had 80% of the volume remaining. In addition, the SCTH had better safety. Thermogravimetric analysis showed that the SCTH could improve the maximum weight loss rate temperature, and increase the residual weight of the coal after thermal decomposition. The coal temperature-programmed oxidation experiment showed that the SCTH could increase the temperature of coal entering the rapid oxidation stage from 120 to 190°C, and the CO inhibition rate was 85.3% at 200°C. Fire suppression experiment showed that the SCTH could reduce the temperature of burning coal by 81.9% within 10 min, thus achieving rapid fire suppression. X-ray photoelectron spectroscopy analysis showed that the SCTH could more effectively reduce the total content of C=O and -COO in coal and block the chain cycle reaction of coal. This work presents a new design idea for using multifunctional nanoparticles to prepare highly stable gel foams with excellent inhibition performance of coal spontaneous combustion. [ABSTRACT FROM AUTHOR]

Published

2024

12. Heat Release Characteristics of L-Malic Acid Inhibited-Coal Oxidation.

Author

Pan, Rongkun, Li, Yang, Chao, Jiangkun, Jia, Hailin, and Wang, Jian

Subjects

SPONTANEOUS combustion, FREE radical reactions, TRANSITION metal ions, HEAT radiation & absorption, CHELATING agents, COAL combustion

Abstract

Transition metal ions in coal can catalyze the oxidation of coal, reduce the activation energy of the coal-oxygen reaction, and promote spontaneous combustion. Adding a metal chelating agent to coal can form chelates with metal ions so that the metal ions lose their catalysis. A green metal chelating agent, L-malic acid (L-MA), was proposed in this study. A C600 microcalorimeter was used to study the inhibitory effect of L-MA on spontaneous coal combustion. The results show that under the same temperature-programmed conditions, the heat absorption capacity of coal treated with L-MA solution is higher than that of raw coal, but the heat release capacity of treated coal is lower. With increase in the concentration of the L-MA solution, the inhibitory effect first increased and then decreased. The maximum heat flow of raw coal is 292 mW, and the maximum heat flow of coal samples treated with malic acid is 246 mW, 237 mW, 232 mW, 240 mW and 255 mW, respectively. The maximum heat flow of 15 wt% coal sample is 20.55% lower than that of raw coal. Based on the thermal analysis, kinetic theory, and experimental data, the activation energy of each coal sample can be calculated. The activation energy of raw coal is the lowest, and the activation energy of each group first increases and then decreases with increasing L-MA concentration, which is in agreement with the law of heat flow data. Combined with the microscopic process of coal oxidation at different temperature stages, the mechanism of L-MA inhibiting spontaneous coal combustion was explored. In summary, L-MA can effectively reduce the concentration of related free radicals in the chain reaction of spontaneous coal combustion and inhibit spontaneous coal combustion. [ABSTRACT FROM AUTHOR]

Published

2024

13. Influence of Air Leakage on the Risk of Spontaneous Combustion in Close Coal Seam Groups.

Author

Li, Cong, Pan, Rongkun, Wang, Chenhui, Jia, Hailin, and Wang, Jian

Subjects

SPONTANEOUS combustion, CRITICAL temperature, STAGE adaptations, X-ray diffractometers, COAL sampling, COAL combustion

Abstract

To study the effect of air leakage on the risk of spontaneous combustion of close coal seam clusters, the heat release characteristics and microstructural evolution of coal samples during primary and secondary oxidation at different air volumes were compared with the help of a high precision calorimeter and an X-ray diffractometer. The Arrhenius formula was applied to calculate the effect of different air volumes on the activation energy. The results show that: The effect of air volume on coal spontaneous combustion is found to have stage adaptation, low airflow is more conducive to coal self-ignition in the pre-heat storage, and the effect of high air volume on coal spontaneous combustion becomes increasingly significant after the temperature rises to a certain degree. The effect of air volume on secondary oxidation and primary oxidation has high affinity. The risk of spontaneous combustion of secondary versus primary oxidation is not absolute, but there is a critical temperature, and secondary oxidation has a higher risk of spontaneous combustion only when the temperature is higher than the critical temperature. The effect of wind volume on the morphological characteristics of the aromatic layer structural unit is achieved mainly by changing the side chain structure. [ABSTRACT FROM AUTHOR]

Published

2024

14. Research on Underground CO Sources and Abnormal Exceedance in the Tailgate Corner of Low Metamorphic Coal Seam.

Author

Li, Lei, Ren, Ting, Zhong, Xiaoxing, and Wang, Jiantao

Subjects

SPONTANEOUS combustion, COAL mining, COAL combustion, COAL sampling, COAL

Abstract

To solve the problem of early warning of coal spontaneous combustion (CSC) caused by abnormal continuous CO overrun in the tailgate corner of low metamorphic coal seam, this paper takes 1306 working face of Dananhu No. 1 coal mine in Hami, Xinjiang as an example. Field measurement, experimental research and numerical simulation were used to study the sources of CO in the tailgate corner and its overrun mechanism, and a CO early warning limit calculation method suitable for CSC oxidation of low metamorphic coal seam is proposed. The results show that the ambient temperature oxidation is the most important source during non-production periods. When ambient O2 concentration is ≥7.7%, the coal sample can undergo ambient temperature oxidation to release CO, and the CO production rate has a good quadratic function fitting relationship with the ambient O2 concentration. The average CO production rate of the dissipation zone in the goaf is 3.3 times that of the oxidation zone, and the CO output proportion is 1.1. The CO early warning limit calculated can indicate the phenomenon of CSC oxidation well. The relevant research work is significant for the safety management of CSC in low metamorphic coal seam mining. [ABSTRACT FROM AUTHOR]

Published

2024

15. Study on Oxidation Dynamic Characteristics of Pressure Bearing Broken Coal with Different Water Content.

Author

Han, Xuefeng, Chao, Jiangkun, Chu, Tingxiang, and Yu, Minggao

Subjects

SPONTANEOUS combustion, HEAT release rates, AXIAL stresses, COAL combustion, COAL mining

Abstract

Gob is one of the most serious areas of coal spontaneous combustion. With the continuous increase of mining depth, the residual coal in gob bears increased axial stress, the rise of ground temperature, and the degree of fragmentation of mining coal and rock continues to increase, the external water in the mining process changes the water content of broken residual coal, under the influence of multiple factors, the prevention and control situation of coal spontaneous combustion in gob is becoming more serious. Based on the actual accumulation environment of residual coal in gob, this paper carried out the oxidation and temperature rise experiment of broken coal under the condition of water bearing and pressure. The variation laws of oxidation characteristic parameters such as outlet oxygen concentration, oxidation derived gas, oxygen consumption rate and heat release intensity were obtained. It is found that with the increase of water content of coal sample, the water content first promotes and then inhibits the oxidation process of coal. It is found that after water molecules form a relatively stable hydrogen bond with oxygen-containing functional groups, the total energy of the two-phase materials decreases, and the reason for the decrease of wetting heat release is analyzed. The influence mechanism of axial stress loading on coal spontaneous combustion oxidation process is studied. It is found that the increase of axial stress first promotes and then inhibits the process of coal spontaneous combustion. [ABSTRACT FROM AUTHOR]

Published

2024

16. Study on Regional Distribution of Spontaneous Combustion in Goaf of Deep Inclined Working Face and Effect of Low Temperature Inert Gas Injection.

Author

Zhao, Wenbin, Cao, Huaisheng, Shi, Xinyan, Wang, Jinfeng, Du, Wenzhou, and Li, Runzhi

Subjects

SPONTANEOUS combustion, NOBLE gases, EARTH temperature, GAS injection, OXYGEN consumption

Abstract

Affected by the occurrence conditions, the inclination angle of the goaf and the ground temperature change the caving structure and temperature rise environment of the goaf, which in turn affects the distribution range of the spontaneous combustion zone in the goaf. During the process of inert gas injection, the cooling and diffusion range of the inert gas determines the its inerting effect. In this paper, the temperature-programmed experiment was used to obtain the oxygen consumption rate of coal at different temperatures. Fluent simulation showed that when no inert gas was injected, the scope of the spontaneous combustion zone on the inlet side moved backward and expanded, while the gas in the gob on the return air side overflowed, and the spontaneous combustion zone The range becomes smaller; when inert gas is injected at low temperature, the influence of different inert gases (N2, CO2) on cooling and diffusion distribution is quite different, CO2 accumulates at the bottom of the goaf, and the influence range is larger; And the space inerting effect is better; the spontaneous combustion area is affected by the injection of inert gas, and there is a risk of secondary re-ignition when the inert gas injection ends. [ABSTRACT FROM AUTHOR]

Published

2024

17. Study on the Influence of the Mechanical Crushing Process on Low-Temperature Oxidation Characteristics of Coal Samples.

Author

Hao, Wanshu, Yuan, Shujie, Li, Jinhu, Xu, Xiaoxue, and Geng, Jingjuan

Subjects

SPONTANEOUS combustion, ELECTRON paramagnetic resonance, COAL combustion, COAL sampling, ACTIVATION energy, HEAT release rates

Abstract

In order to study the influence of the mechanical crushing process on the low-temperature oxidation characteristics of coal, the programmed heating experiments of coal samples with different particle sizes were carried out using a programmed heating device. By comparing and analyzing the changes in CO and CO2 emission, cross-point temperature, heat release intensity, and apparent activation energy of coal samples with different particle sizes during temperature heating, the influence of particle sizes on the spontaneous combustion characteristics of coal samples was obtained. On the basis of the infrared spectrum experiment and ESR (electron paramagnetic resonance) experiment of coal samples with different particle sizes, the changes of functional groups and free radicals were further compared, and the deep-seated reasons that the mechanical crushing process affected the spontaneous combustion characteristics of coal were explored. The results showed that with the decrease in particle size, more alkyl side chains are dehydrogenated to produce alkyl radicals during mechanical crushing, and the alkyl radicals are oxidized with oxygen to form more oxygen-containing functional groups. These oxygen-containing functional groups can accelerate the low-temperature oxidation process of coal in the subsequent secondary low-temperature oxidation process, release more heat, and increase the heat release intensity. In the process of mechanical crushing, the coal sample not only changes in physical structure but also changes in chemical structure. With the decrease in particle size of coal samples, more CO and CO2 are produced in the process of low-temperature oxidation of coal, and the time to reach the cross-point temperature is advanced. However, the cross-point temperature and the apparent activation energy decreases, and the spontaneous combustion characteristics of coal are enhanced. [ABSTRACT FROM AUTHOR]

Published

2024

18. Study on Diffusion Behavior of Inorganic Materials and Performance of Extinguishing Coal Fire.

Author

Cheng, Jianwei, Wu, Yuhang, Zhang, Jufeng, Li, Haijian, Wang, Yungang, Cai, Feng, Lu, Weidong, and Liu, Guozhong

Subjects

GROUTING, SPONTANEOUS combustion, POROUS materials, COAL mining, COAL combustion

Abstract

The majority of a coal mine's goaf is semi-closed complex porous medium space, which is a critical place for coal spontaneous combustion disasters. To investigate the flow diffusion pattern of inorganic compounds in fractured coal in the goaf, as well as the capacity to put out coal fires. It examine the viscosity properties of an inorganic material slurry as a function of water/material ratio and time. By building a three-dimensional grouting test platform in the lab, simulating the broken coal body with sand and gravel, designing orthogonal tests to run multiple groups of grouting tests, and analyzing the effects of factors besides grouting pressure, water/material ratio, and air space ratio on the slurry diffusion radius. The effect of grouting pressure on the pattern of slurry diffusion radius of inorganic material and the water/material ratio under the action of grouting pressure is studied. The test of inorganic materials to extinguish coal pile fire is done, and the fire extinguishing and cooling ability is assessed in comparison to mud of the same grade, based on a prior research of inorganic materials to suppress CO formation in coal oxidation warming. According on the findings, the three-dimensional grouting test platform can pass the grouting test of loose sand and gravel bodies at various grouting pressures. The effects of grouting pressure, water/material ratio, and air space ratio on slurry dispersion are discovered to be multivariate power function relationships rather than linear correlations. The related slurry diffusion radius equation is established, and the variables impacting the parameters of the slurry diffusion range are evaluated, with the grouting pressure and water/material ratio having a substantial impact on slurry diffusion. Inorganic materials, as opposed to mud, require less time to extinguish coal pile fires and are less prone to scatter. It can form an oxygen barrier through continually covering the surface of coal. The study's findings might give a solid foundation for the avoidance of slurry and fire suppression of inorganic materials in the goaf. [ABSTRACT FROM AUTHOR]

Published

2024

19. Inhibiting Effects of Inhibitors on Different Temperature Oxidation of Sulfide Ores.

Author

Huang, Yu-Jie, Guo, Yong, Yang, Fu-Qiang, Qiu, Dong-Yang, and Hong, Yi-du

Subjects

SPONTANEOUS combustion, RAW materials, CHEMICAL resistance, STRENGTH of materials, CETYLTRIMETHYLAMMONIUM bromide

Abstract

To control spontaneous combustion of sulfide ores, the compound inhibitor was prepared by selecting physical resistance raw materials(Na2CO3), chemical resistance raw materials(Melatonin), Cetyltrimethylammonium bromide(CTMAB) and hydroxyethyl cellulose(HEC). With the help of the simultaneous thermal analyzer, different concentrations of inhibitors were prepared and the thermal behavior of the ore samples with 10, 15, and 20 wt% inhibitor at four heating rates of 5, 10, 15, and 20 K/min was determined. The Flynn-Wall-Ozawa method was applied to calculate the activation energy of sulfide ores with different concentrations. The results showed that: Gradually increasing the heating rate will increase the reaction intensity of each ore sample in the first weight loss stage of thermal decomposition, and then reduce the mass of the ore samples involved in the second weight loss stage; The thermal stability of each resisted ore sample is better than that of the original ore sample; The increase in the concentration of inhibitor can inert the reaction process of ore samples in the thermal decomposition stage, weakening the exothermic effect of ore samples; The inhibitor with 15 wt% had a better effect on preventing spontaneous combustion of sulfide ores, and its property value is higher than other concentrations. [ABSTRACT FROM AUTHOR]

Published

2024

20. A Review on the Types, Performance and Environmental Protection of Filling & Plugging Materials for Prevention and Control of Coal Spontaneous Combustion in China.

Author

Lu, Wei, Cao, Huimin, Sun, Xiaolei, Hu, Xiangming, Li, Jinliang, Li, Jinhu, and Kong, Biao

Subjects

SPONTANEOUS combustion, COAL combustion, COAL mine waste, ENVIRONMENTAL protection, FILLER materials

Abstract

Coal spontaneous combustion (the term is hereafter abbreviated as CSC) is an important problem facing by China to achieve carbon peak and carbon neutrality. CSC affects the mining process of mining for a long time, not only causing a large amount of waste of coal resources, but also severely destroying the ecological environment. At present, filling & plugging materials (the term is hereafter abbreviated as F&P materials) is widely welcomed and developed rapidly because of its advantages of wide application, obvious performance and low price. Based on the research of the prevention and control of CSC and the materials applying for it, this paper creatively puts forward an application system of materials used for the prevention and control of CSC. The types of F&P materials are systematically summarized. According to the form of materials, the F&P materials are divided into slurry, colloid and foam. The performance and effect of three kinds of F&P materials are analyzed in detail. On this basis, the cost and environmental protection characteristics of F&P materials in China were compared and evaluated. Finally, this paper predicts the development of F&P materials. This paper provides an effective reference for Chinese coal mining enterprises to select suitable F&P materials, which is of great significance for the prevention and control of CSC and environmental protection. [ABSTRACT FROM AUTHOR]

Published

2024

21. 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

22. Alumina Fiber Membrane Prepared by Electrospinning Technology for Passive Daytime Radiative Cooling.

Author

Xin, Yingfei, Wang, Qingxue, Fu, Chongyang, Du, Shanmei, Hou, Limei, Wei, Xiangxia, Wang, Hanbin, and Wang, Xiaoxiong

Subjects

*SPONTANEOUS combustion, *THERMAL insulation, *THERMAL resistance, *CONSTRUCTION materials, *HOT weather conditions

Abstract

Passive daytime radiative cooling (PDRC) achieves cooling by simultaneously reflecting sunlight and radiating heat to outer space, without consuming any external energy. Traditional PDRC designs use organic materials that are prone to aging and secondary pollution under solar illumination. Here, a flexible alumina fiber membrane (FAFM) is prepared using electrospinning technology. The fiber‐membrane hierarchical structure ensures macroscopic flexibility, allowing this inorganic material to be assembled on complex surfaces just like organic materials. It can efficiently dissipate heat by emitting infrared radiation that matches the atmospheric window and scattering sunlight. Importantly, it is notable that no aging phenomenon occurs even under prolonged ultraviolet irradiation, which brings additional benefits to its green energy‐saving properties. As a result, its outstanding fire resistance and thermal insulation prevent the possibility of spontaneous combustion in extremely hot weather during the summer and may serve as a multifunctional insulation layer for buildings. This preparation method promotes surface design based on more inorganic structural materials in the future, enabling the design of more low‐cost, highly flexible inorganic PDRC materials. [ABSTRACT FROM AUTHOR]

Published

2024

23. Reaction mechanism of catalytic gasification by calcium-based catalysts and oxidized coal residues in coalfield fire zones.

Author

Chen, Liangzhou, Lu, Wei, and Qi, Xuyao

Subjects

*RESOURCE exploitation, *SPONTANEOUS combustion, *COKING coal, *COAL combustion, *COAL pyrolysis

Abstract

Fires originating from coal spontaneous combustion within coalfields result not only in substantial coal resource depletion but also producing residual low-activity pyrolysis coal chars exhibiting varying degrees of oxidation. These chars develop progressively through successive heat penetration at the fire front and post-fire extinguishment phases. This paper focuses on the alkaline earth metal-activated catalytic gasification of residual oxidized coal in fire zones, constructs a carbon-based model of oxidized coal in fire zones. The results show that the reaction active sites of the oxidized coal carbon matrix model are mainly concentrated on the carbon atoms at the end of the aromatic ring. During catalytic gasification, the calcium-based catalyst engages with these active sites, forming a preliminary catalyst. The transformation of oxidized coal into CO primarily occurs through two distinct routes. Calcium attaches to the surface of the oxidized coal's carbon-based structure, establishing active sites. Acting as a facilitator, it aids the movement of CO2 to the carbon-based surface, leading to its further breakdown into CO. The catalytic species containing calcium persistently amalgamates with active sites on coal coke surface, fostering the release of additional CO. Moreover, these catalytic species with calcium also bind CO2 and unite with active coal coke sites, generating carbon–oxygen complexes on the surface. These complexes are thermally unstable and decompose, yielding CO and initiating the formation of fresh active sites on the coal coke surface. Consequently, they interact further with calcium-based catalytic species, culminating in the creation of catalyst precursors, which drive a recurrent catalytic reaction process. [ABSTRACT FROM AUTHOR]

Published

2024

24. Thermodynamic Characteristics and Kinetic Mechanism of Bituminous Coal in Low-Oxygen Environments.

Author

Ren, LiFeng, Tao, Fan, Weng, TengFei, Li, QingWei, Yu, Xin, Zhai, XiaoWei, and Ma, Teng

Subjects

SPONTANEOUS combustion, BITUMINOUS coal, COAL combustion, HIGH temperatures, DISCONTINUOUS precipitation

Abstract

Coal is a crucial energy source globally, but it poses environmental challenges due to high temperatures and harmful missions during combustion. This study investigates bituminous coal's oxidation combustion in low-oxygen environments using thermogravimetry and differential thermogravimetry tests. We explore the thermal behavior and kinetic properties of three coal samples during combustion. Our findings reveal that, as oxygen concentration decreases, the combined combustion index of the coal samples also decreases during the oxygen-absorption stage. Additionally, the apparent activation energy of coal increases with its conversion rate (temperature). We observe a shift in the reaction mechanism from three-dimensional dissipation mode to two-dimensional as the oxygen concentration decreases. Notably, the activation energy initially rises and then decreases with increasing conversion (temperature) during the pyrolysis combustion stage, with a shortened phase of increased activation energy at lower oxygen concentrations. Furthermore, the kinetic mechanism transitions from stochastic nucleation and growth to one-dimensional phase-boundary mode with decreasing oxygen concentration. These insights enhance our understanding of coal oxidation combustion in low-oxygen environments, contributing to strategies for mitigating coal spontaneous combustion. [ABSTRACT FROM AUTHOR]

Published

2024

25. Quantitative characterisation of the influence of different environmental factors on coal spontaneous combustion.

Author

Zhao, Jingyu, Wang, Chen, Song, Jiajia, Lu, Shiping, Deng, Jun, Zhang, Yanni, and Shu, Chi-Min

Subjects

*SPONTANEOUS combustion, *EXOTHERMIC reactions, *DEBYE temperatures, *CRITICAL temperature, *COAL combustion

Abstract

Coal spontaneous combustion (CSC) events pose hazards to miners, infrastructure, and the environment. To mitigate some of the risk of CSC, this study explored the influence of airflow rate (AFR), oxygen concentration (OxyC), and heating rate (HR) on CSC. A temperature programmed experiment was used to examine a coal sample under different AFRs, OxyCs, and HRs. The characteristic temperature was determined using index gas growth rate analysis, and the characteristic parameters were shown. The apparent activation energy (Ea) of the sample was computed by the Arrhenius equation, and variance analysis was employed to quantitatively characterise the impact of different environmental factors on the characteristic parameters of the coal samples. The experimental results show that the critical temperature of the coal samples ranges between 65 and 75 °C, and the cracking temperature ranges between 115 and 130 °C, dividing the low-temperature oxidation process of coal into three stages: before the critical temperature, between the critical temperature and the cracking temperature, and after the cracking temperature. An AFR of 120 mL min−1 was identified as the optimal level; exceeding or falling below this value inhibits the coal-oxygen reaction. Increasing OxyC and reducing HR improves coal oxidation. Compared to the same samples under AFR and HR conditions, the Ea of coal under oxygen conditions is lower, ranging between 20 and 35 kJ mol−1, while under AFR and HR conditions, the Ea is not less than 30 kJ mol−1, indicating a stronger tendency for spontaneous combustion under oxygen conditions. AFR substantially affects the oxygen consumption rate, CH4, and exothermic intensity at all stages, with a partial η2 of 0.6. Before the critical temperature, OxyC has the greatest impact on CO2; between the critical temperature and the cracking temperature, OxyC has the greatest impact on CO; and after the cracking temperature, OxyC has the greatest impact on CO, CO2, C2H4, and C2H6, with partial η2 values of 0.51, 0.59, 0.278, and 0.45, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

26. Effect of oxygen concentration on the heat release behaviour of bituminous coal over the complete spontaneous combustion process.

Author

Zhao, Jingyu, Li, Rui, Song, Jiajia, Lu, Shiping, and Shu, Chi-Min

Subjects

*SPONTANEOUS combustion, *BITUMINOUS coal, *COAL combustion, *DIFFERENTIAL scanning calorimetry, *ACTIVATION energy, *HEAT release rates

Abstract

The effect of different oxygen concentration conditions on the heat release behaviour of bituminous coal during spontaneous combustion was investigated. Thermal analysis experiments were conducted using differential scanning calorimetry (DSC) and laws governing feature peak changes. Heat flow curves were utilised to identify thermal reaction stages, and the impact of oxygen concentration on heat flows during spontaneous coal combustion (SCC) was assessed. The determinants of heat release rates according to temperature and different oxygen concentration conditions were shown. The heat release process exhibited varying heat proportions at distinct stages. Using the feature point analysis method, the DSC curves could be used to show the apparent activation energy of the total SCC process for different oxygen concentrations. Findings showed a noteworthy influence of oxygen concentration on the overall SCC process. As oxygen concentration increased, the characteristic peak of the heat flow curve appeared earlier, the range of heat release and its heat release temperature rose, and the apparent activation energy also increased. A critical oxygen concentration range, between 7 and 12%, was identified, causing fluctuations in the development process of SCC. This article provided a theoretical basis for further investigation into the SCC process and mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

27. Impact of mixing low-reactivity gases on the mechanism of hydrogen spontaneous combustion: A ReaxFF MD study.

Author

Li, Hao, Cao, Xuewen, Xu, Zhongying, Cao, Hengguang, Teng, Lin, and Bian, Jiang

Subjects

*LEAN combustion, *SPONTANEOUS combustion, *HEAT of combustion, *CHEMICAL reactions, *ACTIVATION energy

Abstract

The phenomenon of spontaneous combustion during the release of high-pressure H 2 is critical to the safe storage and transportation. Besides physical methods to suppress self-ignition, the approach of mixing low-reactivity gases has gained increasing attention. Previous work has mainly focused on the flow, physical heating effects, and boundary conditions of self-ignition in mixed gases, while the intrinsic chemical reaction mechanisms of spontaneous combustion remain underexplored. To clear this issue, this work uses the ReaxFF MD simulation method to study the spontaneous combustion process of H 2 /CO and H 2 /CH 4 mixtures with various concentrations. The results indicate that: (1) in pure H 2 , H 2 /CO, and H 2 /CH 4 systems, the primary initial reaction mechanism is H 2 +O 2 HO 2 +H. Additionally, in some mixed systems, CO + O 2 CO 2 +O and CH 4 +O 2 CH 3 +HO 2 may also serve as initial reaction mechanisms. (2) Under fuel-lean combustion conditions, the RIDTs of the systems decrease, supporting the viewpoint that self-ignition typically occurs first in fuel-lean regions. The addition of CO and CH 4 increases the RIDTs, which helps inhibit the development of self-ignition. (3) In H 2 -rich environments, CO combusts to CO 2 through the formation of HOCO, while CH 4 undergoes dehydrogenation and oxidation processes through intermediates such as CH 3 , CH 3 O, and HCHO, leading to the formation of CO and CO 2. The combustion of H 2 is also influenced by these processes. (4) The addition of CO and CH 4 increases the activation energy of H 2 combustion, raising the reaction energy barrier that must be overcome for spontaneous combustion. This effectively helps to suppress the occurrence and development of self-ignition during the release of high-pressure gases. • Clear initial reaction mechanism of pure H 2 , H 2 /CO, and H 2 /CH 4 combustion systems. • RIDTs of H 2 , H 2 /CO, and H 2 /CH 4 systems are statistically analyzed and compared. • Reaction pathways of H 2 , CO, and CH 4 in mixed systems have been identified. • Combustion activation energies of H 2 in mixed systems are calculated. • Explained the inhibition of self-ignition from a molecular reaction perspective. [ABSTRACT FROM AUTHOR]

Published

2024

28. Study on the Thermal Effects and Characteristics of Free Radical Evolution in Coal Oxidation at Different Moisture Content.

Author

Zhang, Yanni, Zhai, Fangyan, Yao, Di, Deng, Jun, Shu, Pan, and Duan, Zhengxiao

Subjects

*ELECTRON paramagnetic resonance, *THERMAL coal, *SPONTANEOUS combustion, *FREE radicals, *COAL combustion

Abstract

To investigate the influence of moisture on the exothermic properties of coal oxidation, this study investigated the variation in thermal effect and radical parameters in the oxidation process of coal under different moisture content. This was achieved through thermogravimetric–differential thermal experiments and electron spin resonance experiments. Additionally, the study analyzed the impact of free radicals on the characteristics of the thermal effect of coal at different oxidation stages using the product–moment correlation method. The results indicate that the moisture content of 8% is a critical point for promoting or inhibiting the oxidation reaction of coal. Below this threshold, it promotes the oxidation reaction, while above it, it plays an inhibitory role. The most significant promotional effect was observed at 8% moisture content, which increased both the weight loss and heat release by 8.61% and 1567.04 J/g, respectively, while also significantly enhancing free radical species and complexity. Conversely, when the moisture content of coal reached 20%, there was a notable inhibition effect, with a reduced weight loss and exothermic capacity by 4.94% and 2705.03 J/g, respectively, along with decreased free radical species and complexity. The free radical species and heat effect parameters in coal showed a strong correlation at all stages of low-temperature oxidation, thus indicating that g-factor can characterize the coal oxidation process to some extent. [ABSTRACT FROM AUTHOR]

Published

2024

29. Study on the effect of imidazole ionic liquids on the whole process spontaneous combustion characteristics of long-flame coal based on TG–DSC technology.

Author

He, Yan-peng, Ma, Li, Yan, Zhen-guo, and Wang, Yan-ping

Subjects

*SPONTANEOUS combustion, *DEBYE temperatures, *DIFFERENTIAL scanning calorimetry, *THERMAL analysis, *ENTHALPY, *COAL combustion

Abstract

To investigate the influence of imidazole ionic liquids (IILs) on the whole process of coal spontaneous combustion (CSC). Three IILs, [EMIm][BF4], [BMIm][BF4], and [BMIm][NO3], were selected to carry out thermogravimetry and differential scanning calorimetry (TG–DSC) thermal analysis experiments on long-flame coal. The mass change curve (TG) and enthalpy change curve (DSC) of the coal oxidation process were determined. The characteristic temperatures and stages of the whole process of CSC were also divided by TG and DSC curves, respectively. The influence of IILs on the mass and enthalpy changes were analyzed. Then, the inhibition effect of different IILs on the whole process and each stage of CSC were calculated based on the thermal release, and the inhibition strength of anion and cation was discriminated. From the TG curve, the characteristic temperatures (except T2) and stages of the treated coal moved toward the high-temperature region of the CSC process compared with the raw coal, the whole mass loss behavior lags behind the raw coal significantly, and the mass loss in the combustion stage is smaller than that of the raw coal. From the DSC curve, the characteristic temperatures (except TD4) of the treated coal are higher than that of the raw coal, and the thermal release at each stage is lower. Although IILs have a slight facilitating on the accelerated oxidation stage of CSC. However, in general, IILs not only inhibit the occurrence and development of CSC mass loss behavior, but also cause the thermal behavior to end earlier and thermal release reduced. The inhibition effect of the three IILs on spontaneous combustion of long-flame coal is as follows: [EMIm][BF4] > [BMIm][NO3] > [BMIm][BF4], with inhibition effects of 26.5%, 19.4%, and 4.8%, respectively. The inhibition effect on CSC of cation [EMIm]+ is better than that of [BMIm]+, anion [NO3]– is better than that of [BF4]–, and the inhibition strength of cation was superior to the anion. [ABSTRACT FROM AUTHOR]

Published

2024

30. 改性固废基多孔颗粒吸附CO2 及其 解吸抑制煤自燃特性研究.

Author

付文刚, 关洪峰, 石　勇, and 李　娟

Subjects

SPONTANEOUS combustion, CARBON dioxide adsorption, COAL combustion, COAL mining, SOLID waste

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

31. A Study on the Influence of Air Humidity on the Characteristic Parameters and Thermal Effect of Coal Spontaneous Combustion.

Author

Wang, Chen, Zhang, Yulong, Wang, Junfeng, Fan, Yaoting, and Tang, Yibo

Subjects

SPONTANEOUS combustion, COAL combustion, THERMAL coal, THERMAL analysis, COAL sampling, OXYGEN consumption

Abstract

Air humidity has a significant effect on the characteristic parameters and heat changes of the coal spontaneous combustion process. In this study, a self-built precision humidity-generating device with adjustable humidity was used to investigate the effect of different humidity conditions on the spontaneous combustion process of coal. The release of indicator gases was determined by a humidity-generating unit in conjunction with a temperature-programmed device for coal oxidation, and the effect of air humidity on coal spontaneous combustion was studied from a macroscopic perspective. A quantitative study of the effect of air humidity on the heat released during the spontaneous combustion of coal was carried out by obtaining data for exothermic heat release intensity by conducting thermal analysis. Meanwhile, the numerical simulation method was used to study the influence of air humidity on the heat released during the coal spontaneous combustion process. The experimental results indicated that the introduction of moist air could significantly increase the oxygen consumption rate of the coal samples and promote the production of CO and CO2. In the slow oxidation stage, the air humidity has a greater effect on the heat release than that in the accelerated and fast oxidation stages. The simulated results of heat release in the slow oxidation phase are consistent with the experimental data, verifying that the moisture in the air can increase the amount of heat release and promote the coal-oxygen reaction. When the moisture in the air first came into contact with the coal, it released a large amount of adsorption heat in a short time, which increased the coal temperature. [ABSTRACT FROM AUTHOR]

Published

2024

32. Research on a Spontaneous Combustion Prevention System in Deep Mine: A Case Study of Dongtan Coal Mine.

Author

Kong, Biao, Li, Jiahui, Lu, Wei, Fu, Wei, Song, Haizhou, and Liu, Jifan

Subjects

SPONTANEOUS combustion, RADON isotopes, COAL combustion, EARTH temperature, COAL mining

Abstract

Due to the influence of high ground stress, high ground temperature, high water inflow and other problems in deep mines, coal spontaneous combustion (CSC) is seriously harmful. This paper studied the variation law of three kinds of indicator gases in the process of coal heating in deep mines, and established a multi-parameter gas indicator prediction system for CSC. Secondly, in view of the shortcomings of the negative pressure bundle tube. A positive pressure beam tube monitoring system for early warning of CSC was developed, the accuracy of sampling data was verified on site, and the high temperature area in the well was further identified by isotope radon measurement. Combined with the positive pressure beam tube monitoring system, to realize the joint detection of uphole and downhole. Finally, according to the detection results of the fire area, the fire prevention methods for small space fire area, multi-coal seam and multi-source air leakage complex fire area and large-area concealed fire area are determined. The above-mentioned CSC early warning and prevention system was applied in Dongtan (DT) Coal Mine, and a good fire prevention effect was achieved. In this paper, the CSC prevention and extinguishing system established has important significance in the prevention and control of mine fires. [ABSTRACT FROM AUTHOR]

Published

2024

33. Analysis of the Coal Spontaneous Combustion Risk Space Evolution in the Goaf Under Ventilation and Extraction Coupling.

Author

Pan, Rongkun, Wang, Xiaohuan, Chao, Jiangkun, Jia, Hailin, and Shen, Hedi

Subjects

SPONTANEOUS combustion, COAL combustion, GAS well drilling, AIR flow, FLOW velocity

Abstract

The risk of coal spontaneous combustion in goaf is one of the disasters in coal mining, ventilation and extraction often aggravate air leakage from the goaf. Due to the unclear rule of expansion law and air leakage, the risk space for coal spontaneous combustion continues to occur. To investigate the influence of ventilation and extraction on the evolution of the risk space of coal spontaneous combustion (CSC) in goaf, further reveal the characteristics of air leakage and extraction in goaf and obtain the expansion law of CSC risk space. A three-dimensional model of goaf under surface drilling and gas extraction was developed. Using FLUENT numerical simulation software, taking a coal mine in Anhui Province, this study analyzes the influence factors, evolution law, and influence characteristics of CSC through field observations and numerical simulation. The research indicates that ventilation keeps the risk space of CSC expanding. The extraction of single drilling showed a local space expansion, while the extraction of double drilling shows the overall space expansion of the goaf. The air leakage flow path in goaf, air flow velocity vector in working face, gas concentration loss, and gas extraction characteristic parameters are determined. The loss of air leakage along the working surface meets four-stage: "strong in – flow - mixed flow – steady inflow – sudden outflow." It can be determined that the extraction intensity of single drilling should be greater than 34.8 m3/min, and the double drilling should be greater than 18.7 m3/min. The relationship between the coupling influence of ventilation and extraction and the expansion law of CSC risk space is determined, and the maximum risk space width of CSC can be predicted. The research results are of guiding significance for CSC prevention and gas efficient extraction. [ABSTRACT FROM AUTHOR]

Published

2024

34. 20 WEIRDEST SCIENCE MYSTERIES.

Author

DUTFIELD, SCOTT

Subjects

WEAKLY interacting massive particles, MIGRATORY animals, SMALL magellanic cloud, LIFE cycles (Biology), SPONTANEOUS combustion

Abstract

This document provides concise summaries of various scientific phenomena and mysteries. It covers topics such as the signs of carcinisation, near-death experiences, autonomous sensory meridian response (ASMR), the Hessdalen lights, the placebo effect, the properties of glass, the dancing plague, the Mpemba effect, and animal rain. The document presents different theories and explanations for these mysteries, highlighting the gaps in scientific understanding. It aims to provide library patrons with a brief overview of these topics for further research. [Extracted from the article]

Published

2024

35. 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

36. Oxidation Characteristics and Corresponding Reaction Mechanism of Coal During the Spontaneous Combustion Latency.

Author

Zhao, Xingguo, Dai, Guanglong, Qin, Ruxiang, Zhou, Liang, Li, Jinhu, and Li, Jinliang

Subjects

SPONTANEOUS combustion, ONLINE monitoring systems, COAL combustion, COAL, OXIDATION

Abstract

The study of the formation of CO and CO2 is an important means of investigating the mechanism of low-temperature coal oxidation. However, the small changes in the gas produced by oxidation during the spontaneous combustion latency cannot be accurately measured by traditional flow reactors. A set of coal low-temperature closed oxidation multi-component gas online monitoring system was designed. Small changes in the volume fractions of O2, CO and CO2 can be automatically monitored in real time. Experiments on the isothermal oxidation of coal were conducted during the spontaneous combustion latency under different conditions (different temperatures, different initial oxygen volume fractions and different oxidation times). The oxidation experiment results were corrected by Henry model. According to the retardation time of gas production and the changes in Graham's ratio, CO and CO2 are produced from different reaction sequences during the spontaneous combustion latency. The active substances in coal react with O2 to produce unstable carbon-oxygen complexes, and CO2 is mainly derived from the decomposition of the intermediates. CO is derived from the H-capture reaction of stable solid oxygenated complexes. The research results will help to further understand the mechanism of spontaneous combustion of coal. [ABSTRACT FROM AUTHOR]

Published

2024

37. Effect of Soaking Time on the Spontaneous Combustion Characteristics of Lignite.

Author

Niu, Huiyong, Mao, Zihao, Bu, Yunchuan, Li, Shuopeng, Yang, Yanxiao, Sun, Qingqing, and Tao, Meng

Subjects

SPONTANEOUS combustion, FOURIER transform infrared spectroscopy, POROSITY, WATER immersion, LIGNITE combustion, LIGNITE

Abstract

When mining deep coal seams, the overlying mined-out area must be pumped and drained, and the remnant coal in the mining void area is vulnerable to spontaneous combustion via water immersion and air drying. To investigate the effect of soaking time on the spontaneous combustion characteristics of lignite, low-temperature N2 adsorption experiments and Fourier transform infrared spectroscopy (FTIR) experiments were used in this study to investigate the changes in pore structure and functional group content of coal samples by increasing the soaking time. Based on programmed warming experiments, macroscopic characteristic indicators of coal spontaneous combustion (CSC) oxidizability, such as the oxygen consumption rate and index gas, were derived. Results showed that the effect of soaking caused the total pore volume and specific surface area of lignite to increase to different degrees, which enhanced the adsorption capacity of coal to oxygen and improved the effective contact of oxygen with the active sites on the coal surface. However, there was no consistency in the effect of different soaking times on the content of reactive functional groups of the coal, with higher methyl and methine contents after 60 days of soaking (S60) and 120 days of soaking (S120) than in the raw coal (RC), and less in 90 days of soaking (S90). The propensity of coal to spontaneously combust is determined by both the pore structure and reactive functional groups, which shows the propensity of spontaneous combustion S60>S120>RC>S90. Results from this study are important in understanding the mechanism of CSC of water-soaked lignite in mined-out areas and can provide theoretical guidance to prevent CSC in mining areas. [ABSTRACT FROM AUTHOR]

Published

2024

38. N2 Inhibition Characteristics of Coal Spontaneous Combustion in Goaf: Experimental Study and Numerical Analysis.

Author

Li, Zhu, Wang, Liang, Xie, Xichao, Pan, Rongkun, and Wang, Xiaohuan

Subjects

SPONTANEOUS combustion, COAL combustion, NUMERICAL analysis, NITROGEN, BODY temperature, OXYGEN consumption

Abstract

To investigate the inhibition characteristics of coal spontaneous combustion in goaf under different nitrogen injection conditions, the oxidation and the heat release characteristics of coal bodies with easy spontaneous combustion were characterized by using adiabatic oxidation experiment. A comparative study on the evolution of the coal spontaneous combustion risk zone (CSCZ) in goaf was carried out by using numerical simulation. The results indicate that the oxygen consumption rate of coal bodies with the rise of temperature in a power function. The exothermic characteristics of coal decrease with the increase of N2 addition. The location and rate of N2 injection restrict the expansion process of CSCZ, which makes the maximum width of CSCZ shrink, the oxygen attenuation rate, N2 diffusion intensity and inerting area increase. When the N2 injection position is 40 m away from the working face and the N2 injection rate is 450 m3/min, the critical ideal value of inhibition coal spontaneous combustion can be achieved. [ABSTRACT FROM AUTHOR]

Published

2024

39. Analysis of CO Source and Prediction Model of Gushing Concentration at the Return Air Corner of Working Face in Shallow Coal Seam Mine.

Author

Wu, Fanghua, Shi, Shiliang, Lu, Yi, Shao, Shuzhen, Wu, Xiaoying, and Gu, Wangxin

Subjects

SPONTANEOUS combustion, COAL combustion, COAL mining, COMBUSTION gases, PREDICTION models

Abstract

The production practices in Shendong mining area show that the CO concentration at the return air corner of shallow coal seams often exceeds the limit, but the temperature of the residual coal in the goaf has not significantly increased, and no other indicative gas of spontaneous combustion in coal seams has been detected. In order to provide scientific basis for CO management at the return air corner of the fully mechanized mining face in Shendong mining area and the prevention and control of coal seam spontaneous combustion fires, based on the "three zones" distribution parameters of spontaneous combustion of coal in goaf and the characteristic parameters of spontaneous combustion of coal, and based on the mechanism of CO production in shallow buried mining area, the source and influencing factors of CO in working face were analyzed, and the calculation model of CO concentration at the return air corner in working face was established. The concentrations of CO at the return air corner in different working faces in Shendong mining areas were calculated by using the model. The results showed that the relative error between the observed and measured values remained between 0.32% and 6.92%. The quantitative analysis of the proportion of CO production from each source to the total production of CO in the return air corner is of great significance to the effective control of CO concentration in the air return corner of the working face. [ABSTRACT FROM AUTHOR]

Published

2024

40. Experimental study of microbial desulphurisation of sulphide ores combined with gel foam retardants to prevent spontaneous combustion.

Author

Pan, Wei, Liao, Zhigang, Yi, Ruge, and Yang, Lingrong

Subjects

SULFIDE ores, SPONTANEOUS combustion, FIREPROOFING agents, WEIGHT gain, ORES

Abstract

The purpose of this study was to reduce the propensity for spontaneous combustion of sulfide ores through the combined action of microorganisms and inhibitors and to assess the flame retardant effect. The sulfide ore samples were first pretreated with biodesulphurisation. The samples were then sprayed with a foam blocker to prevent re-oxidation of the ore and further reduce the spontaneous combustion tendency of the sulfide ore. The experimental results showed that the highest desulfurization rate of 24.26% was achieved for ore samples with a particle size between 140–160 mesh. A combination of 0.05% hexadecyltrimethylammonium bromide (CTAB), 0.11% lauramidopropyl betaine (LAB-35), 0.13% sodium alcohol ether sulfate (AES), 0.11% propanetriol foam stabilizer, 7% water glass and 3% sodium bicarbonate arresting agent was the most effective. The oxidation weight gain of the desulphurised ore sprayed with the resist was only 3.16%. The oxidation weight gain of the desulphurised ore without the addition of the resist was 3.98% and the oxidation weight gain of the undesulphurised ore was 6.01%. This method is effective in reducing the tendency of spontaneous combustion of sulfide ores. [ABSTRACT FROM AUTHOR]

Published

2024

41. Study on the Mechanical and Energy Evolution Characteristics of Oxidized Coal.

Author

Pan, Rongkun, Yu, Ruirui, Chao, Jiangkun, Jia, Hailin, Wang, Jian, and Li, Cong

Subjects

POISSON'S ratio, SPONTANEOUS combustion, ENERGY dissipation, SURFACE cracks, MECHANICAL energy, COAL combustion

Abstract

To study the variation laws of the mechanical properties of coal with different oxidation degrees, coal samples were subjected to constant temperature oxidation at 80°C, 120°C, 160°C and 200°C by using a coal oxidation spontaneous combustion test system. Through a uniaxial compression experiment, the variation laws of mechanical parameters, failure characteristics and energy dissipation law of coals with different oxidation degrees were analyzed and obtained. The study shows that the stress – strain curves of coal with different oxidation degrees vary in different stages. The peak stress, elastic modulus, secant modulus and Poisson's ratio appear to decrease to different degrees with the deepening of oxidation, and the peak strain increases. The cracks on the surface of the coal samples increase and become more with the deepening of oxidation, the exothermic characteristics of the coal samples decrease, and the failure characteristics of the coal samples change from single shear-type failure characteristic to conjugate shear-type characteristic and then to shatter-type failure characteristic. With an increasing degree of oxidation, the total energy required for coal destruction gradually decreases, the conversion rate of total energy into elastic energy decreases, the dissipation energy gradually increases, and the release rate of elastic energy and the increase rate of dissipation energy gradually slow down after the peak strain. [ABSTRACT FROM AUTHOR]

Published

2024

42. Experimental research on spontaneous oxidization combustion characteristics of coal after pre-adsorption CO2.

Author

Zhang, Yansong, Sun, Yingjun, Du, Wenzhou, Niu, Kuo, Dong, Hongtao, Xi, Ya, Wang, Bowen, and Wang, YangXu

Subjects

SPONTANEOUS combustion, FOURIER transform infrared spectroscopy, ALIPHATIC hydrocarbons, FUNCTIONAL groups, DEBYE temperatures, COAL combustion

Abstract

CO2 is injected into coal bodies in advance so that CO2 is fully adsorbed in the crack pores of the coal. It can inhibit the combination of coal and oxygen, so as to prevent and control the natural combustion of coal left in goaf. However, domestic and foreign scholars have little research on the low temperature oxidation characteristics and functional group changes of coal after CO2 pre-injection. In this article, a temperature programmed experimental device is used to analyze the formation of the macro-combustion index gas; a Fourier transform infrared spectroscopy experimental analyzer was determined the content of active functional groups of each component. The results showed that when the coal-sample pre-adsorbed CO2, the generation trend of CO2 formed an approximate "V" shape, the oxygen consumption decreased by about 4%. The initial generation temperature of CO and alkane gases is lagged, and the lag temperature is 20 ~ 30°C. CO2 occupied the surface of the coal surface, and inhibiting the oxidation response of oxygen-containing functional groups. The content of hydroxyl group increases, the oxidative decomposition rate of aliphatic hydrocarbon slows down, and the content of aromatic hydrocarbon increases, which can effectively slow down the course of coal oxidation and spontaneous combustion. [ABSTRACT FROM AUTHOR]

Published

2024

43. Dynamic correlation between surface carbon response and underlying emissions from spontaneous combustion goaf: field study of an abandoned coal mine

Author

Yongjun Wang, Qian Zheng, Hemeng Zhang, Xiaoming Zhang, Wei Dong, Yuichi Sugai, and Kyuro Sasaki

Subjects

CO2 flux, Goaf, Gas emission, Coal mine, Spontaneous combustion, Environmental pollution, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Abandoned coal mine goaf is affected by air leakages and prone to spontaneous combustion, resulting in environmental pollution and geological disasters. Haizhou Open-pit Mine adopts both underground and open-pit mining methods. During the long-term mining process, the original stable stratum structure is constantly destroyed, and the slope slides, increasing cracks and severe air leakage around the goaf and roadway. The spontaneous combustion of coal is particularly prominent after the mine shut down. At present, there is no suitable indirect monitoring method to effectively explore the spontaneous combustion area in goaf. The study developed an all-weather monitoring plan and conducted multi-point continuous long-term measurements of the spontaneous combustion state in one abandoned coal mine goaf located in the eastern part of the Haizhou Open-pit Mine. We evaluated the dynamic correlation between surface CO2 flux (SCF) and changes in the underground fire areas, determined the scope and evolution trend of the fire areas, and identified the distribution and change laws of SCF. The results show a significant positive correlation between SCF and soil temperature; moreover, the SCF value was found to reflect the CO2 emission intensity of the goaf. The high SCF in the test area showed month-wise expansion and increase, while the CO2 emission gradually increased monthly, and the calculated annual total emission was approximately 7017 t. Hence, the study can further provide guidance for the monitoring of spontaneous combustion in shallow coal seams, goaf and the assessment of CO2 emissions from underground coal fires through the on-site monitoring and analysis results.

Published

2024

44. Research on gel plugging and fire prevention technology for roadway excavation in residual coal re-mining area

Author

Shuo LIU, Yuanwei YANG, Haipeng MOU, Tingwen GUO, Baiyi LI, and Jialong LI

Subjects

residual coal re-mining, fire prevention and extinguishing, residual coal spontaneous combustion, spontaneous combustion, gel plugging, Mining engineering. Metallurgy, TN1-997

Abstract

The phenomenon of spontaneous combustion of coal left in the goaf directly affects the safe and efficient mining of coal mines, and the use of plugging materials to close the air leakage channel is an effective method to solve the problem of spontaneous combustion of coal in the goaf. Taking the F1301 re-mining face of Yunhe Coal Mine as the engineering background, aiming at the hidden danger of spontaneous combustion of loose coal left in the tunneling roadway in the goaf, the implementation scheme of gel plugging and fire extinguishing technology for loose coal was formulated. The COMSOL numerical simulation method was used to study the gel diffusion law under different injection time and pressures, and the engineering application was carried out. The results show that the injection time and pressure are proportional to the gel diffusion range. Considering the injection effect and cost, 10 MPa and 140-160 min are selected as the best injection pressure and time, and the distance between the injection holes is set to 5 m. After the implementation of the gel plugging fire prevention and extinguishing scheme, the monitoring data of the observation boreholes on both sides of the roadway show that the volume fraction of the iconic gas CO is stable below 24×10−6, and the gel plugging fire prevention and extinguishing effect is good, which effectively eliminates the hidden danger of spontaneous combustion of coal left in the goaf.

Published

2024

45. Research progress and trend analysis of comprehensive prevention and control of coal spontaneous combustion throughout all stages

Author

Yingbing YANG, Zhenqiang XING, Yunzeng ZHANG, Jiace GUO, Long LI, Wenyong LU, and Minghao CHEN

Subjects

spontaneous combustion, comprehensive prevention and control throughout all stages, machine learning, artificial intelligence, diverse innovation, informatization, monitoring and early warning, fire prevention and control, emergency rescue, Mining engineering. Metallurgy, TN1-997

Abstract

To gain a profound understanding of the current status and future trends in the comprehensive prevention and control of coal spontaneous combustion, this paper comprehensively reviews stages and research progress in the aspects of “monitoring and early warning, prevention technology, and emergency rescue”. The following future research aspects are proposed: utilizing advanced technologies such as comprehensive multivariate statistical analysis, the Internet of Things (IoT), machine learning, and artificial intelligence to enhance the accuracy of coal spontaneous combustion prediction and forecasting. This involves constructing an intelligent, proactive warning, and situational judgment mechanism to achieve intelligent prediction, forecasting, and proactive warning systems. Through the comprehensive application of interdisciplinary research methods, gaining in-depth insights into the spontaneous combustion mechanism, innovative fire-resistant materials, and the development of new microbial technologies, theses make the technology of spontaneous combustion prevention and control of coal present a trend of in-depth research and multiple innovation. Under the framework of an efficient, collaborative, and intelligent rescue mechanism, the emergency rescue for coal spontaneous combustion is advancing towards a more intelligent and information-oriented direction. The goal is to promote the intelligent advancement of the coal spontaneous combustion prevention and control level.

Published

2024

46. Study on oxidation characteristics of coal gangue with different moisture content under water immersion drying

Author

Chenhong ZHOU, Xuping LI, Jing ZHANG, Xiaopeng REN, Jianan YAO, Zhi LI, and Tianyu LI

Subjects

water immersion drying, coal gangue, oxidation, spontaneous combustion, program heats up, indicator gas, Mining engineering. Metallurgy, TN1-997

Abstract

Coal gangue, which accumulates in the open air, is modified by immersion in rain, and exhibits different tendencies to spontaneous combustion in different areas of precipitation. To study the role and influence of moisture on the oxidation and spontaneous combustion of coal gangue, we used high-sulfur coal gangue prone to spontaneous combustion in the Qipanjing area of Inner Mongolia. First, the coal gangue is soaked with different moisture content (moisture content: 0, 15%, 30%, 50%, 100%). After soaking for 45 days, the coal gangue is naturally air dried. The dried gangue samples were put into the self-made programmed temperature experiment furnace to conduct experiments on the pre-treated coal gangue samples (the temperature rise rate was set at 3℃/min, and the temperature rise range was set at 30−390 ℃). The gas the temperature points of the coal gangue in each stage was collected by air collecting bag (each rise of 15 ℃ was a stage). Finally, the collected gas was passed into the GC-4000A gas chromatograph. By comparing the O2 consumption、the volume fraction of CO, CH4, C2H4, C2H6 and other index gases produced by coal gangue treated with different moisture content, the results show that: The low temperature oxidation of coal gangue is the best when the moisture content is 15%, the initial formation temperature of CO, CH4, C2H4, C2H6 and other indicator gases is the lowest, and the concentration of various indicator gases is the highest when the temperature is 390℃. When the moisture content exceeds 50%, under the action of moisture dissolution, a large number of combustible substances in the coal gangue are carried and dispersed by moisture, resulting in a significant decrease in the concentration of various indicator gases generated when the moisture content of the coal gangue rises to 390 ℃, even lower than that of the control experimental group without moisture immersion and redrying treatment. When the coal gangue is immersed in water, the initial temperature points of the various index gases are reduced by about 15 ℃.

Published

2024

47. Study on the characteristics and predictive model of autoignition induced by shock wave from high-pressure hydrogen leakage.

Author

Cui, Gan, Li, Yixuan, Wu, Di, Li, Hongwei, Xing, Xiao, and Liu, Jianguo

Subjects

*SHOCK waves, *PREDICTION models, *SPONTANEOUS combustion, *GAS distribution, *BOUNDARY layer (Aerodynamics), *LASER peening

Abstract

Faced with climate change and increasing environmental pollution, countries around the world are actively exploring strategies for clean, renewable energy. However, under high-pressure conditions, hydrogen leaks can lead to spontaneous combustion, which significantly raises the safety risk of hydrogen applications. This study employs fluid dynamic simulation methods to investigate the development process of shock waves within tubes. It analyzes the effect of release conditions on the propagation speed and shock wave intensity, revealing the impact of shock wave intensity on the temperature distribution and gas composition variation within the hydrogen-air mixture boundary layer. The results show that the tube length and bends have relatively little impact on the shock waves, while discharge pressure and tube diameter significantly affect the propagation speed and intensity of shock waves. Combined with dimensional analysis and data fitting, a predictive model for autoignition of high-pressure hydrogen leakage is established: (P r / P a)((DXr x(H₂) r O₂)) /V s 2) = 1505(X / D)−1.329. • Studied the influence of the discharge conditions on the propagation process of the excitation wave in the tube. • Elucidated the microscopic influence of the leading shock wave on the gas properties at the boundary layer. • Propose a prediction model for spontaneous combustion of high-pressure hydrogen leakage. [ABSTRACT FROM AUTHOR]

Published

2024

48. Simulation and Catastrophe Detection of Spontaneous Combustion Processes in Sulfide Ores.

Author

Pan, Wei, Wang, Shuo, Yi, Ruge, and Kang, Youqing

Subjects

SPONTANEOUS combustion, MINES & mineral resources, SURFACE area, POINT processes, DATA mining

Abstract

Spontaneous combustion of sulfide ores during mining can lead to severe fires. To explore the transformation of state in the whole process of spontaneous combustion of sulfide ores, the simulation experiment of the whole unsteady process of spontaneous combustion of sulfide ore heap was carried out, and the most appropriate wavelet function was selected, combined with catastrophe detection and other methods for data mining and processing. The results indicate spatial differences in the response of the ore heap to environmental temperature changes during the whole unsteady process of spontaneous combustion of the sulfide ore heap. The reaction in the area near the surface of the heap is more prominent and faster, and the response in the area near the center of the heap is longer in duration. Moreover, there must be at least one catastrophe point in this process, and the catastrophe temperature must be between 108.2 °C and 113.9 °C. Finally, the whole unsteady process of the spontaneous combustion of the sulfide ore heap can be divided into four regions. Among them, region (II) is in a stage of obvious self-heating/near spontaneous combustion, and it is the catastrophe stage. [ABSTRACT FROM AUTHOR]

Published

2024

49. Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology.

Author

Guo, Jun, Wu, Yunfei, Liu, Yin, Cai, Guobin, Li, Dailin, and Jin, Yan

Subjects

*SPONTANEOUS combustion, *SOLVENT extraction, *MOLECULAR structure, *COAL, *STATISTICAL correlation, *COAL gasification

Abstract

The molecular structure of coal is complex, and the existing research methods are limited, so it is difficult to clarify its influence mechanism on the spontaneous-combustion characteristics of coal. In this paper, the previous extraction, FTIR, TPR, TG-DSC and other experimental results are combined to analyze the extraction weakening effect and the correlation analysis of the spontaneous-combustion characteristic parameters of raffinate coal. The results show that extraction can destroy the connection bond of coal molecules, change the content of dominant active groups in the coal spontaneous-combustion reaction, increase the lower limit of the key temperature nodes of coal spontaneous-combustion or extend the temperature range, resulting in an increase in the ignition-point temperature of coal and a decrease in coal quality. This paper will provide a theoretical basis for the study of the microscopic mechanism of coal spontaneous-combustion and then provide new ideas for the development of an active prevention and control technology for coal spontaneous-combustion. [ABSTRACT FROM AUTHOR]

Published

2024

50. The Influence of the Fire Point on the Thermal Dynamic Disaster in the Goaf.

Author

Chen, Xiaokun, Song, Chao, and Zhang, Zhipeng

Subjects

*SPONTANEOUS combustion, *COAL combustion, *COMBUSTION gases, *COAL mining, *AIR flow

Abstract

A thermal dynamic disaster in the goaf is one of the most serious coal mine disasters formed by coal spontaneous combustion and gas interweaving. However, the influence of the high-temperature hidden fire source formed in the goaf on the evolution law of thermal dynamic disasters is not clear, and effective prevention and control measures cannot be taken. Therefore, this paper uses the experimental platform of thermal dynamic disaster in the goaf to study the influence of different fire point positions on the development of thermal dynamic disaster in the goaf through a similar simulation experiment of thermal dynamic disaster evolution in the goaf and analyzes the corresponding relationship between temperature and CO concentration in the upper corner. The results show that under different locations of heat source, the high-temperature heat source of coal spontaneous combustion migrates to the air leakage side with sufficient oxygen supply, and an oxygen-poor circle is formed near the ignition point. Under the action of air leakage flow, CH4 accumulates in the deep part of the goaf on the return air side. Due to the increase in coal, part of CH4 is produced, which leads to the increase in concentration of CH4 at the ignition point. Under the action of different heat sources, the changing trend of concentration of CO and temperature in the return air corner is the same, but the temperature change in the return air corner shows a lag compared with the change in the concentration of CO, so concentration monitoring of CO can reflect the evolution process of the fire field in the goaf more quickly than temperature monitoring. [ABSTRACT FROM AUTHOR]

Published

2024