Next Article in Journal
Upgrading Carthamus by HTC: Improvement of Combustion Properties
Previous Article in Journal
Fire Detection in Urban Areas Using Multimodal Data and Federated Learning
Previous Article in Special Issue
Experimental Estimation of Turbulent Flame Velocity in Gasoline Vapor Explosion in Multi-Branch Pipes
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Fire
Volume 7
Issue 4
10.3390/fire7040105
fire-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Investigating the Influence of Flue Gas Induced by Coal Spontaneous Combustion on Methane Explosion Risk

by
Sijia Hu
1,2,3,
Yanjun Li
1,2,3,*,
Chuanjie Zhu
2,3,
Baiquan Lin
2,3,
Qingzhao Li
2,3,
Baolin Li
1,2,3 and
Zichao Huang
4,*
1
School of Environment and Safety Engineering, North University of China, Taiyuan 030051, China
2
Key Laboratory of Gas and Fire Control for Coal Mines, Ministry of Education, China University of Mining and Technology, Xuzhou 221116, China
3
School of Safety Engineering, China University of Mining and Technology, Xuzhou 221116, China
4
Industrial Safety Research Branch, China Coal Technology and Engineering Group Chongqing Research Institute, Chongqing 400037, China
*
Authors to whom correspondence should be addressed.
Fire 2024, 7(4), 105; https://0-doi-org.brum.beds.ac.uk/10.3390/fire7040105
Submission received: 12 February 2024 / Revised: 15 March 2024 / Accepted: 21 March 2024 / Published: 22 March 2024
(This article belongs to the Special Issue Fire/Explosion Risk Assessment and Loss Prevention of Hazardous Materials, Mines and Natural Gas)
Browse Figures
Versions Notes

Abstract

:
During the process of coal spontaneous combustion (CSC), a plethora of combustible gases alongside inert gases, such as CO2, are copiously generated. However, prior investigations have regrettably overlooked the pivotal influence of inert gas production on the propensity for methane explosions during CSC. To investigate the impact of the flue gas environment generated by CSC, containing both combustible and inert gases, on the risk of methane explosion, a high-temperature programmed heating test system for CSC was employed to analyze the generation pattern of flue gas. It was found that CO, CO2, and CH4 were continuously generated in large quantities during the process of CSC, which are the main components of CSC flue gas. The effect of the concentration and component ratio (CCO2/CCO) of the flue gas on the methane explosion limit was tested. It was found that the CSC flue gas led to a decrease in the methane explosion limit, and that the explosion limit range was facilitated at 0 < CCO2/CCO < 0.543 and suppressed at CCO2/CCO > 0.543. As the temperature of CSC increases, the risk of methane explosion is initially suppressed. When the coal temperature exceeds 330~410 °C, the explosion risk rapidly expands.

1. Introduction

Energy stands as the bedrock of human advancement, with coal wielding a significant sway in global energy consumption [1,2,3]. Throughout the coal mining process, various disaster risks are encountered, among which methane explosions pose the gravest threat, resulting in profound human casualties and extensive property devastation [4,5,6,7]. The residual coal left within mining sites, owing to the inherent limitations in extraction techniques, lays the groundwork for the emergence of coal spontaneous combustion (CSC) [8,9]. When the CSC develops to a high temperature sufficient to detonate methane, it is possible to form a serious methane explosion accident [10]. In the genesis of this high-temperature source, copious volumes of mixed flue gas, comprising combustible and inert constituents, are incessantly generated, exerting a tangible influence on methane explosion risks [11,12,13]. Delving into the generation law of flue gas during coal spontaneous combustion and its consequential impact on methane explosion limits not only enriches our comprehension of the perils posed by methane explosion disasters stemming from coal spontaneous combustion in goaf but also fortifies our arsenal of preventive and mitigation measures against such calamitous events [14,15]. Hence, a plethora of scholarly endeavors have been dedicated to scrutinizing the methane explosion risk under the aegis of CSC conditions [16].
The genesis of combustible gases poses a palpable escalation in the risk profile of methane explosions [17,18,19]. In a study by Zhang et al., the impact of CO on methane explosion limits was examined across varying temperature regimes, employing a 20 L explosive sphere apparatus. Their findings elucidated a conspicuous augmentation in gas explosion risk concomitant with heightened initial temperatures and CO concentrations [20]. Hao et al. conducted investigations into the influence of H2 on methane explosion risks, uncovering a notable expansion in the explosion limit range of methane due to the presence of H2 [19]. Further delving into this intricate nexus, Ma et al. probed the effects of CO-H2 mixtures on methane explosion limits. Their comprehensive analysis unveiled a discernible decrease in the lower explosion limit (LEL) and a noteworthy expansion in methane explosion limits, thereby substantially amplifying methane explosion risks, with CO-H2 mixtures demonstrating a more pronounced effect compared to pure CO [14]. Wang et al. undertook experiments centered on the spontaneous combustion gas emissions of long-flame coal to scrutinize the impact of CO-C2H4-C2H6 mixtures on methane explosion limits. Their discernments highlighted a heightened explosion hazard attributed to the addition of these combustible gases, with C2H4 and C2H6 exerting more significant effects than CO [21]. Building upon the foundations laid by Wang et al., Luo et al. expanded the purview of inquiry by incorporating the influence of H2, revealing a parabolic increase in methane explosion hazards within CSC mixtures [22].
While significant strides have been made in scrutinizing the impact of gases engendered during coal spontaneous combustion (CSC) on methane explosion risks, these endeavors are not devoid of certain lacunae. Primarily, extant investigations predominantly center on gas analyses at temperatures below 500 °C [23,24], whereas the temperature required for CSC to ignite methane often needs to exceed 650 °C [25]. Moreover, prevailing studies tend to concentrate on the effects of individual combustible gases or their mixtures generated during CSC on methane risk, neglecting the distinctive characteristic of yielding copious volumes of mixed gas comprising both combustible and inert constituents during coal spontaneous combustion. This oversight inevitably engenders inaccuracies in analysis outcomes [13]. Therefore, in this study, the variation law of the concentration and composition of gases generated during the process of CSC temperature rising to 730 °C was analyzed. The impact of flue gas, characterized by varying concentrations and composition ratios, on methane explosion limits was systematically evaluated, thereby elucidating the dynamics of methane explosion risk under the influence of flue gas in relation to coal temperature.

2. Flue Gas Generation Characteristics during CSC

2.1. The Flue Gas Generation Characteristic Test Experiment of CSC

2.1.1. Experimental System

The temperature-programmed experiment serves as a cornerstone method for elucidating the gas generation law of CSC [26]. Given that CSC-induced methane explosions necessitate attaining temperatures exceeding 600 °C, a high-temperature programmed experimental system was built, as illustrated in Figure 1 The system was composed of a gas supply system, programmed temperature control system, temperature acquisition system, and gas analysis system. The gas supply system consisted of gas cylinders, flow controllers, gas mixing tanks, check valves, and gas purifiers. In order to simulate the air conditions in the goaf of coal mine, O2 and N2 were used as the gas source. The input gas flow was meticulously regulated by high-precision gas flow controllers, maintaining an N2/O2 ratio of 4. The programmed temperature control system was composed of an SG-GL1400 vacuum tube furnace (heating range 0~1400 °C, maximum heating rate 10 °C/min) and a coal sample container of 316 stainless steel. The coal samples were broken and screened to obtain particles with a size range of 40–80 mesh. Subsequently, these particles were placed into coal sample containers, sealed, and then placed horizontally in a vacuum tube furnace to ensure uniform heating of the coal sample container. The temperature acquisition system was composed of thermocouples and a temperature acquisition instrument. The measurement accuracy of the thermocouple was 0.1 °C. The temperature changes inside the container were collected in real-time. The gases generated during the coal heating process were collected in gas sampling bags and analyzed using a GC-4000A gas chromatograph.

2.1.2. Experimental Process

(1)
Coal samples screening: The fresh coal samples taken from the site were removed by sandpaper, and then the coal samples were broken into different sizes by a crusher. Then, the coal samples were screened by a sieve with a screening range of 0.18–0.38 mm to obtain a coal sample with a particle size range of 40~80 mesh. Finally, 300 g coal samples were selected and placed in a vacuum-drying oven at 50 °C for 24 h to remove external moisture.
(2)
Heating pretreatment: After the dry coal samples were loaded into the coal sample container, N2 was first introduced into the furnace at a flow rate of 120 mL/min for about 10 min to drain the air in the tank. Subsequently, the furnace temperature was set at 30 °C and maintained for 30 min to make the initial temperature conditions of the experiment consistent.
(3)
Temperature programming: The flow controller was adjusted to supply gas to the coal sample tank at 300 mL/min, and the proportion of O2 in the supplied gas was 21%. At the same time, the flow and composition of the outlet gas were monitored. After the outlet gas was stable, the programmed temperature control system was turned on, and the heating rate was set to 2 °C/min, and the heating range was 30~710 °C.
(4)
Data collecting: After the temperature started to rise, the temperature acquisition instrument was opened, and the acquisition frequency was set to 1 time/s. At the same time, for every 20 °C increase in coal temperature, flue gas generated from coal spontaneous combustion was collected and stored separately in gas bags with a volume of 10 mL each. Subsequently, the flue gas in each gas bag was tested using the chromatograph.

2.1.3. Experimental Samples

Three types of coal samples with different degrees of metamorphism were selected for testing to analyze the generation law of combustible and inert gases during the CSC process. These coal samples were obtained from the Shengli Coal Mine in the Inner Mongolia Autonomous Region (lignite), Baikuang Coal Mine in Pingdingshan, Henan Province (bituminous coal), and the Linhua Coal Mine in Guizhou Province (anthracite). The industrial analysis and vitrinite reflectance test results of the coal samples are shown in Table 1.

2.2. Flue Gas Generation Law of CSC

Figure 2 portrays the dynamic interplay between gas concentrations and coal temperature throughout the heating process. Across the spectrum of temperatures spanning from 30 to 710 °C, the gases emanating from the heating of three distinct coal types predominantly encompass CO, CO2, CH4, C2H4, C2H6, and C3H8. The initial concentrations of CO and CO2 for lignite, bituminous coal, and anthracite were 0.0029% and 0.27%, 0.0022% and 0.22%, and 0.0017% and 0.16%, respectively. Notably, the emergence of CO and CO2 pervaded the entirety of the coal’s thermal evolution, steadfastly constituting the principal constituents of the generated gases. The advent of CH4 burgeoned notably once the coal temperature surpassed the threshold of 290 °C, exhibiting a sustained propensity for generation even amidst the heightened temperatures. This phenomenon underscores the potential for localized explosion hazards in regions with diminished methane content in the goaf, where evaluation in coal temperature can instigate methane release. In contrast, the generation of C2H4, C2H6, and C3H8 predominates within the temperature band of 350 to 550 °C, yielding relatively diminutive quantities, each remaining below 0.5. Consequently, the influence of these gases on methane explosions remains circumscribed. Thus, in instances of (CSC) within the goaf, the gases prone to amass in the combustion zone primarily comprise CO, CO2, and CH4. Among them, CH4 is the inherent gas in the goaf, while CO and CO2, as gases generated in large quantities during the coal heating process, may affect methane explosions. Accordingly, this investigation delves into the ramifications of CSC flue gas, predominantly constituted by CO and CO2, on the risk of methane explosions.

3. Influence of CSC Flue Gas on Methane Explosion Limit

The determination of the explosion limits of combustible gases was achievable through both experimental and theoretical calculation methodologies [27,28]. Despite the array of theoretical approaches available for calculating these limits, experimental validation remains the gold standard [22,29,30]. Consequently, this study endeavored to employ experimental testing as the cornerstone for investigating the explosion limits of methane in the presence of flue gas.

3.1. Explosion Limit Test Experiment of Multi-Component Mixed Gas

3.1.1. Experimental System

In order to investigate the effect of CSC flue gas on the explosion limits of methane, a multi-component gas explosion limit testing experimental system was constructed as shown in Figure 3, mainly composed of an explosion room, gas supply system, ignition system, and data acquisition system. The explosion room was a cylindrical chamber made of 304 stainless steel, with a volume of 16 L and was capable of withstanding an explosion pressure of 10 MPa. The gas supply system mainly consisted of gas cylinders, control valves, driers, vacuum pumps, and high-precision vacuum gauges. The gas was supplied using Dalton’s law of partial pressures. During the supply process, precise control of gas concentration as achieved through a high-precision vacuum gauge, with an accuracy of up to 0.01%. The ignition system consisted of ignition electrodes and an ignition controller, with a gap of 2 mm between the positive and negative electrodes. The ignition controller was a KTD-W adjustable igniter capable of releasing ignition energy ranging from 50 to 500 mJ. The data acquisition system consisted of a high-frequency pressure sensor and a TST6300 dynamic signal acquisition instrument. The highest sampling frequency for explosion overpressure was 1 MHz, with a maximum sampling width of 2 M and a sampling accuracy of up to ±0.001 FS. According to the European Union standard BSEN 1839:2012, the criterion for an explosion is whether the maximum explosion pressure exceeds 5% of the initial pressure [31].

3.1.2. Experimental Process

(1)
Experimental preparation: Before the experiment, the line connections and the air tightness of the device were checked separately. The ignition system and explosion overpressure acquisition system were debugged under unpressurized conditions to ensure the normal operation of the testing apparatus.
(2)
Vacuuming: The intake valve was closed, the vacuum pump was turned on, the high-precision vacuum pressure gauge was observed, and once the pressure decreased to a stable level, the vacuuming valve was closed.
(3)
Gas supply: The partial pressure of each gas according to Dalton’s law was calculated, then sequentially the gas valve was opened and the concentration of each gas was controlled using the vacuum pressure gauge. After completion, the gases were allowed to stand for 10 min to ensure thorough mixing.
(4)
Ignition: The explosion overpressure signal acquisition was turned on, then the mixed gas was ignited using the igniter controller.
(5)
Exhaust the waste gas: After the explosion ended, the exhaust valve was opened and dry air was introduced into the explosion room via the intake pipe for 30 s to purge any remaining explosive gases inside the chamber.

3.1.3. Experimental Design

In accordance with the generation law of CSC flue gas, CO and CO2 emerged as prominent constituents capable of sustained and copious generation, each bearing distinct implications for methane explosion limits [32,33,34]. Therefore, this study took the concentration of flue gas (Cflue) and the concentration ratio of CO2 to CO in flue gas (α) as influencing factors to analyze the influence of CSC flue gas on the methane explosion limit. To analyze the variation trends of Cflue and α with coal temperature, corresponding values of Cflue and α were calculated based on the CO and CO2 concentrations obtained at each temperature adjustment as depicted in the experimental results of Figure 2. The results are presented in Figure 4. From Figure 4a, it is discernible that during the initial phases of coal temperature elevation, the concentration of flue gas remains relatively modest, with none of the three coal samples surpassing 1%. Subsequently, upon attaining 150 °C, the rate of flue gas generation escalates swiftly, albeit not exceeding 30% at its zenith. Figure 4b delineates the rapid initial decline followed by a gradual stabilization of α as coal temperature escalates. Prior to reaching 150 °C, the flue gas concentration remains relatively subdued, exerting limited impact on methane explosion limits. Consequently, this study directs its focus towards scrutinizing the effect of CSC flue gas on methane explosion limits subsequent to coal temperature surpassing 150 °C. During this phase, the α value of the flue gas predominantly oscillates within the range of 0 to 5.
Based on the preceding analysis, the concentration of flue gas generated by CSC predominantly fluctuates between 1% and 30%, while the α value primarily ranges from 0 to 5. In light of this, to scrutinize the impact of flue gas on methane explosion limits, six distinct concentration conditions of flue gas were devised, namely 5%, 10%, 15%, 20%, 25%, and 30%. Additionally, 5 α value conditions were delineated, encompassing 0.2, 0.5, 1, 3, and 5.

3.2. Experiments

Figure 5 delineates the repercussions of CSC flue gas, characterized by varying concentrations (Cflue) and α values, on methane explosion limits. Notably, the presence of CSC flue gas precipitates a decline in both the lower explosion limit (LEL) and upper explosion limit (UEL) of methane. This trend is similar to the experimental findings in reference [35], but the values are slightly higher than the test values in reference [35]. This may be due to different explosion limit standards and experimental conditions. The reduction in UEL is ascribed to the competitive influences of CO and CO2 on O2 molecules, coupled with the dilution, insulation, and cooling effects of CO2 on reactants, alongside the inhibitory impact of CO2 on the reaction process. Furthermore, as the proportion of CO2 in the flue gas mixture escalates, the role of CO2 becomes more conspicuous, yielding a more pronounced decrease in the UEL. However, the reasons for the decline of LEL are different from those of UEL. CO tends to diminish the LEL of methane, whereas CO2 tends to elevate it. The reason for the decrease in LEL of methane is that the effect of CO in the flue gas (α = 0~5) is stronger than that of CO2. Consequently, while the decrease in LEL may engender fresh explosion hazards in regions where methane concentrations were initially sub-threshold, the continuous escalation of Cflue, particularly in scenarios such as α = 0.2, can drive the LEL of methane to 0%, rendering the flue gas itself explosively susceptible, thereby heightening the likelihood of ignition or explosion.
The effects of different flue gases with varying Cflue or α on the methane explosion limits are different. When α remains constant, both the LEL and UEL of methane decrease linearly with the increase in Cflue. However, when Cflue remains constant, the impact of flue gases with different α on the UEL and LEL of methane varies. Specifically, the UEL decreases with increasing α, while the LEL increases with increasing α.

4. Influence of CSC Flue Gas on the Risk of Methane Explosion

4.1. Influence of Flue Gas on Methane Explosion Limit Range

The explosion limit range stands as a pivotal parameter for assessing explosion risks [36,37]. In the context of this study, the measured methane explosion limit spans from 5.22% to 15.51%, yielding a range of 10.29%. Figure 6 elucidates the impact of flue gas characterized by diverse Cflue and α values on the range of methane explosion limits. It is discernible that flue gas with varying α values exerts disparate effects on the explosion limit range of methane. Specifically, when α assumes values of 0.2 or 0.5, the flue gas augments the explosion limit range of methane. Notably, when Cflue ≥ 25%, there appears to be a decline in the explosion limit range of methane. However, this decline does not signify a mitigation of methane explosion risks. Rather, it signals that flue gas at elevated concentrations possesses explosive characteristics, thereby posing a heightened risk of direct ignition. Conversely, when α is 1, 3, or 5, the flue gas manifests an inhibitory effect on the explosion limit range of methane. Moreover, this inhibitory influence amplifies with escalating Cflue.
The fluctuations in the range of methane explosion limits are intricately influenced by both LEL and UEL. Specifically, when the LEL of methane exhibits a slower decline with increasing Cflue compared to the UEL, the range of the gas explosion limit contracts. When the decrease rate of the methane LEL with increasing Cflue is faster than that of UEL, the explosion limit range of methane expands. Conversely, if the rate of decrease in the methane LEL with increasing Cflue surpasses that of the UEL, the explosion limit range of methane expands.
This rate of decrease can be quantified by the absolute value of the slope (|k|) of the linear reduction in the methane explosion limit. In essence, when |k|LEL > |k|UEL, flue gas augments the explosion limit range of methane. Conversely, when |k|LEL < |k|UEL, flue gas constrains the explosion limit range of methane.
As illustrated in Figure 7, the variation of |k| with α is delineated. It can be observed that |k|LEL decreases as α increases, while |k|UEL increases with α. Notably, at α = 0.543, |k|LEL = |k|UEL, signifying a point where the impact of flue gas on both the UEL and LEL of methane is equivalent. Consequently, the methane explosion limit range is consistent with the condition without flue gas. In other words, the value of 0.543 denotes the critical threshold at which flue gas transitions from promoting to inhibiting the methane explosion limit range.
In summation, flue gas characterized by low α values tends to enhance the explosion limit range of methane, whereas flue gas with high α values tends to curtail it. Considering the actual conditions in coal mine goafs, Cflue remains relatively subdued during the initial stages of temperature elevation, thereby exerting minimal influence on the explosion limit range of methane. However, as the coal temperature continues to rise, Cflue steadily escalates while α gradually diminishes, signaling a trajectory of heightened methane explosion risk. Particularly during the high-temperature phases, when the α of flue gas plummets below 0.5, the flue gas itself acquires explosive properties, precipitating a sudden upsurge in the risk of explosion within the goaf area.

4.2. Variation Law of Methane Explosion Risk during the Temperature Increasing Process of CSC

4.2.1. Fitting of Methane Explosion Limits under the Influence of Flue Gas

The elevated temperatures generated by CSC in the goaf serve as crucial ignition sources for initiating methane combustion [38,39]. Concurrently, flue gas undergoes continuous generation throughout the coal temperature escalation process within the goaf, culminating in the formation of a dynamic flue gas environment characterized by fluctuating Cflue and α values. This, in turn, exerts a notable influence on the explosion limits of methane.
To assess the risk of methane explosion amidst coal temperature elevation, the methane explosion limit within the flue gas milieu was modeled. as shown in Figure 8. The specific outcomes of this fitting process are as follows:
LEL = 5.22 − 0.3CflueEXP(−α/1.42) − 0.03Cflue
UEL = 15.52 − 0.22Cflue − 0.03αCflue
where LEL is the lower explosion limit of methane, %; UEL is the upper explosion limit of methane, %; Cflue is the flue gas concentration, %; and α is the ratio of CO2 and CO concentrations in the flue gas.

4.2.2. Variation Law of Methane Explosion Limits during the Temperature Increasing Process of CSC

To assess the explosion risk of methane during the process of coal temperature elevation, it is necessary to calculate the methane explosion limits at various temperatures. By substituting the experimental results of the temperature-programmed experiment into the aforementioned fitted formula for explosion limits calculation, the variation pattern of methane explosion limits with coal temperature was obtained, as depicted in Figure 9. Notably, from the pattern of LEL variation illustrated in Figure 9a, it becomes apparent that under the influence of flue gas, the LEL of methane undergoes a continuous decline with increasing coal temperature. In the oxidation zone of the goaf, the methane concentration typically remains at a low level owing to air dilution, thereby mitigating methane explosion risks [40,41]. However, the presence of flue gas serves to diminish the LEL of methane, thereby introducing new explosion hazards in areas that were initially non-explosive. Something that is particularly noteworthy is the scenario wherein the temperature of bituminous and anthracite coal reaches 550 °C and 650 °C, respectively, resulting in the LEL of methane plummeting to 0%. At this juncture, the risk of methane explosion escalates significantly due to the combustibility of the flue gas itself.
Similarly, Figure 9b shows that the UEL of methane experiences a decrease under the influence of flue gas. However, unlike the pattern observed in LEL variation, fluctuations in UEL emerge after the temperatures of lignite, bituminous coal, and anthracite reach 350 °C, 350 °C, and 390 °C, respectively. In the event of a CSC disaster in the goaf, the reduction in LEL can potentially mitigate the risk of methane explosion. However, this inhibitory effect is constrained by the low methane concentration prevalent in the oxidation zone. Furthermore, it is noteworthy that the impact of flue gas generated by different coal types on the methane explosion limits varies. Lignite exerts the greatest influence, followed by bituminous coal, with anthracite exerting the least impact. This observation implies that the CSC flue gas generated by low metamorphic grade coal is more likely to escalate the risk of methane explosion.

4.2.3. Variation Law of Methane Explosion Limits Range during the Temperature Increasing Process of CSC

In order to further analyze the impact of flue gas on methane explosion risk during the coal temperature elevation process, it is necessary to analyze the variation of methane explosion limit range with coal temperature. This value can be calculated based on the difference between the LEL and the UEL in Figure 9. The results are illustrated in Figure 10. Notably, it becomes evident that as coal temperature rises, the range of methane explosion limits initially diminishes before rebounding. Relative to conditions devoid of flue gas, the presence of flue gas engenders a reduction in the range of methane explosion limits, reaching a nadir when the temperatures of lignite, bituminous coal, and anthracite reach 330 °C, 350 °C, and 410 °C, respectively. At this juncture, although the decrease in methane LEL remains relatively modest, the inhibitory effect on the explosion limit range peaks, thereby yielding the lowest risk of methane explosion. Subsequently, with the swift expansion of the methane explosion limit range and the continual decline in LEL, the risk of methane explosion progressively escalates.

5. Conclusions

(1)
Throughout the CSC temperature elevation process, CO, CO2, and CH4 are consistently generated in substantial quantities, constituting the primary components of CSC flue gas. They represent the predominant gases that influence the risk of methane explosions. Conversely, C2H4, C2H6, and C3H8 are produced only in minor quantities within the temperature range of 350~550 °C, and their impact on the risk of methane explosions remains limited.
(2)
Both the LEL and UEL of methane demonstrate a linear decline with increasing Cflue. The UEL of explosion diminishes with escalating α, whereas the LEL increases with α.
(3)
Flue gas characterized by lower α values facilitates an expansion of the range of methane explosion limits, whereas flue gas with higher α values constrains the range of methane explosion limits. α = 0.543 marks the critical threshold at which flue gas transitions from promoting to inhibiting the explosion limit range of methane.
(4)
At lower coal temperatures, the influence of flue gas on methane LEL is minimal, while the explosion range is inhibited, culminating in a reduced risk of methane explosion. However, once the coal temperature surpasses 330~410 °C, the risk of methane explosion continues to escalate under the dual effects of a rapid decline in LEL and a continuous increase in the explosion limit range.

Author Contributions

Conceptualization, C.Z. and Y.L.; methodology, B.L. (Baiquan Lin); formal analysis, S.H.; investigation, Z.H.; resources, Q.L.; data curation, Y.L.; writing—original draft preparation, S.H.; writing—review and editing, Y.L.; visualization, C.Z.; supervision, Q.L.; project administration, B.L. (Baolin Li); funding acquisition, Y.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Science and Technology Major Project grant number 2020YFA0711803, the National Natural Science Foundation of China grant number 52174214, 52304260, and Shanxi Province Basic Research Program grant number 202203021222031. And The APC was funded by 202203021222031.

Data Availability Statement

The data in this article is presented in the text and no additional database is required.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Alshehry, A.; Belloumi, M. The Symmetric and Asymmetric Impacts of Energy Consumption and Economic Growth on Environmental Sustainability. Sustainability 2024, 16, 205. [Google Scholar] [CrossRef]
  2. Fouquet, R. The Digitalisation, Dematerialisation and Decarbonisation of the Global Economy in Historical Perspective: The Relationship Between Energy and Information Since 1850. Environ. Res. Lett. 2024, 19, 014043. [Google Scholar] [CrossRef]
  3. Wang, X.; Lu, Y.; Chen, C.; Yi, X.; Cui, H. Total-factor Energy Efficiency of Ten Major Global Energy-consuming Countries. J. Environ. Sci. 2024, 137, 41–52. [Google Scholar] [CrossRef]
  4. Zhang, X.; Jian, S.; Lin, B.; Zhu, C. Study on the Influence of Different-voltage Plasma Breakdowns on Functional Group Structures in Coal. Energy 2023, 284, 128768. [Google Scholar] [CrossRef]
  5. Liu, T.; Li, M.; Zou, Q.; Li, J.; Lin, M.; Lin, B. Crack Instability in Deep Coal Seam Induced By the Coupling of Mining Unloading and Gas Driving and Transformation of Failure Mode. Int. J. Rock Mech. Min. Sci. 2023, 170, 105526. [Google Scholar] [CrossRef]
  6. Li, B.; Wang, E.; Li, Z.; Cao, X.; Liu, X.; Zhang, M. Automatic Recognition of Effective and Interference Signals Based on Machine Learning: A Case Study of Acoustic Emission and Electromagnetic Radiation. Int. J. Rock Mech. Min. Sci. 2023, 170, 105505. [Google Scholar] [CrossRef]
  7. Zheng, Y.; Li, S.; Xue, S.; Jiang, B.; Ren, B.; Zhao, Y. Study on the Evolution Characteristics of Coal Spontaneous Combustion and Gas Coupling Disaster Region in Goaf. Fuel 2023, 349, 128505. [Google Scholar] [CrossRef]
  8. Duan, H.; Zhao, L.; Yang, H.; Zhang, Y.; Xia, H. Development of 3D Top Coal Caving Angle Model for Fully Mechanized Extra-thick Coal Seam Mining. Int. J. Min. Sci. Technol. 2022, 32, 1145–1152. [Google Scholar] [CrossRef]
  9. Liu, Q.; Lin, B.; Zhou, Y.; Li, Y. Permeability and Inertial Resistance Coefficient Correction Model of Broken Rocks in Coal Mine Goaf. Powder Technol. 2021, 384, 247–257. [Google Scholar] [CrossRef]
  10. Zheng, Y.; Li, Q.; Zhu, P.; Li, X.; Zhang, G.; Ma, X.; Zhao, Y. Study on Multi-field Evolution and Influencing Factors of Coal Spontaneous Combustion in Goaf. Combust. Sci. Technol. 2023, 195, 247–264. [Google Scholar] [CrossRef]
  11. Ma, D.; Qin, B.; Li, L.; Gao, A.; Gao, Y. Study on the Methane Explosion Regions Induced By Spontaneous Combustion of Coal in Longwall Gobs Using a Scaled-down Experiment Set-up. Fuel 2019, 254, 115547. [Google Scholar] [CrossRef]
  12. Gao, A.; Qin, B.; Zhang, L.; Ma, D.; Li, L. Experimental Study on Gas Migration Laws at Return Air Side of Goaf Under High-temperature Conditions. Combust. Sci. Technol. 2023, 195, 1930–1944. [Google Scholar] [CrossRef]
  13. Bai, G.; Li, X.; Zhou, X.; Wang, J.; Linghu, J. Evaluation of Lignite Combustion Characteristics and Gas Explosion Risks Under Different Air Volumes. Energy Sources Part A Recovery Util. Environ. Eff. 2020, 1–15, 1770375. [Google Scholar] [CrossRef]
  14. Ma, D.; Qin, B.; Zhong, X.; Sheng, P.; Yin, C. Effect of Flammable Gases Produced From Spontaneous Smoldering Combustion of Coal on Methane Explosion in Coal Mines. Energy 2023, 279, 128125. [Google Scholar] [CrossRef]
  15. Zhuo, H.; Qin, B.; Qin, Q. The Impact of Surface Air Leakage on Coal Spontaneous Combustion Hazardous Zone in Gob of Shallow Coal Seams: A Case Study of Bulianta Mine, China. Fuel 2021, 295, 120636. [Google Scholar] [CrossRef]
  16. Li, J.; Li, X.; Liu, C.; Zhang, N. Study on the Air Leakage Characteristics of a Goaf in a Shallow Coal Seam and Spontaneous Combustion Prevention and Control Strategies for Residual Coal. PLoS ONE 2022, 17, e0269822. [Google Scholar]
  17. Yang, Y.; Fei, J.; Luo, Z.; Wen, H.; Wang, H. Experimental Study on Characteristic Temperature of Coal Spontaneous Combustion. J. Therm. Anal. Calorim. 2023, 148, 10011–10019. [Google Scholar] [CrossRef]
  18. Wang, Y.; Sun, Y.; Dai, L.; Wang, K.; Cheng, G. Mechanisms of CO and CO2 Production During the Low-temperature Oxidation of Coal: Molecular Simulations and Experimental Research. Fire 2023, 6, 475. [Google Scholar] [CrossRef]
  19. Hao, Q.; Luo, Z.; Wang, T.; Xie, C.; Zhang, S.; Bi, M.; Deng, J. The Flammability Limits and Explosion Behaviours of Hydrogen-enriched Methane-air Mixtures. Exp. Therm. Fluid Sci. 2021, 126, 110395. [Google Scholar] [CrossRef]
  20. Zhang, X.; Zhou, X.; Bai, G.; Li, C. Influence of CO on Explosion Limits and Characteristics of the CH4/air Mixture. ACS Omega 2022, 7, 24766–24776. [Google Scholar] [CrossRef]
  21. Wang, H.; Liu, Y.; Shan, Q. Influence of Gas From Long-flame Coal Spontaneous Combustion on Gas Explosion Limit. Int. J. Chem. Eng. 2023, 2023, 5096109. [Google Scholar] [CrossRef]
  22. Luo, Z.; Liang, H.; Wang, T.; Cheng, F.; Su, B.; Liu, L.; Liu, B. Evaluating the Effect of Multiple Flammable Gases on the Flammability Limit of CH4: Experimental Study and Theoretical Calculation. Process Saf. Environ. Prot. 2021, 146, 369–376. [Google Scholar] [CrossRef]
  23. Li, H.; Chen, X.; Shu, C.M.; Wang, Q.; Ma, T.; Bin, L. Effects of Oxygen Concentration on the Macroscopic Characteristic Indexes of High-temperature Oxidation of Coal. J. Energy Inst. 2019, 92, 554–566. [Google Scholar] [CrossRef]
  24. Zhao, J.; Wang, T.; Deng, J.; Shu, C.M.; Zeng, Q.; Guo, T.; Zhang, Y. Microcharacteristic Analysis of CH4 Emissions Under Different Conditions During Coal Spontaneous Combustion with High-temperature Oxidation and in Situ Ftir. Energy 2020, 209, 118494. [Google Scholar] [CrossRef]
  25. Robinson, C.; Smith, D.B. The Auto-ignition Temperature of Methane. J. Hazard. Mater. 1984, 8, 199–203. [Google Scholar] [CrossRef]
  26. Wang, K. An Approach for Evaluation of Grading Forecasting Index of Coal Spontaneous Combustion By Temperature-programmed Analysis. Environ. Sci. Pollut. Res. 2023, 30, 3970–3979. [Google Scholar] [CrossRef] [PubMed]
  27. Ji, W.; Wang, Y.; Yang, J.; He, J.; Wen, X. Methods to Predict Variations of Lower Explosion Limit Associated with Hybrid Mixtures of Flammable Gas and Dust. Fuel 2022, 310, 122138. [Google Scholar] [CrossRef]
  28. Wang, G.; Shi, G.; Yang, Y.; Liu, S. Experimental Study on the Exogenous Fire Evolution and Flue Gas Migration During the Fire Zone Sealing Period of the Coal Mining Face. Fuel 2022, 320, 123879. [Google Scholar] [CrossRef]
  29. Nie, B.; Peng, C.; Gong, J.; Yin, F.; Wang, K. Explosion Characteristics and Energy Utilisation of Coal Mine Ultra-lean Methane. Combust. Theory Model. 2021, 25, 73–95. [Google Scholar] [CrossRef]
  30. Jiao, F.; Zhang, H.; Li, W.; Zhao, Y.; Guo, J.; Zhang, X.; Zhang, Y. Experimental and Numerical Study of the Influence of Initial Temperature on Explosion Limits and Explosion Process of Syngas-air Mixtures. Int. J. Hydrogen Energy 2022, 47, 22261–22272. [Google Scholar] [CrossRef]
  31. European Committee for Standardisation. Determination of Explosion Limits of Gases and Vapours: BS EN 1839:2012 [S]; BIS Standards Publication: Brussels, Belgium, 2012; p. 7. [Google Scholar]
  32. Zhu, X.; Zhou, J.; Guo, Z.; Zhang, X. CO2 Suppression of Methane/air Explosion Flame and Pressure Coupling Analysis. Fresenius Environ. Bull. 2022, 31, 4995–5003. [Google Scholar]
  33. Luo, Z.; Su, Y.; Li, R.; Chen, X.; Wang, T. Effect of Inert Gas CO2 on Deflagration Pressure of CH4/CO. ACS Omega 2020, 5, 23002–23008. [Google Scholar] [CrossRef] [PubMed]
  34. Deng, J.; Cheng, F.; Song, Y.; Luo, Z.; Zhang, Y. Experimental and Simulation Studies on the Influence of Carbon Monoxide on Explosion Characteristics of Methane. J. Loss Prev. Process Ind. 2015, 36, 45–53. [Google Scholar] [CrossRef]
  35. Cheng, F.; Deng, J. Experimental study on the influence of carbon monoxide on carbon dioxide-inerted methane explosion. Xian Univ. Sci. Technol. 2016, 36, 315–319. [Google Scholar]
  36. Wang, T.; Zhou, Y.; Luo, Z.; Wen, H.; Zhao, J.; Su, B.; Deng, J. Flammability Limit Behavior of Methane with the Addition of Gaseous Fuel at Various Relative Humidities. Process Saf. Environ. Prot. 2020, 140, 178–189. [Google Scholar] [CrossRef]
  37. Sun, Y.; Qian, X.; Yuan, M.; Zhang, Q.; Li, Z. Investigation on the Explosion Limits and Flame Propagation Characteristics of Premixed Methanol-gasoline Blends. Case Stud. Therm. Eng. 2021, 26, 101000. [Google Scholar] [CrossRef]
  38. Zhang, L.; Wang, H.; Chen, C.; Wang, P.; Xu, L. Experimental Study to Assess the Explosion Hazard of CH4/coal Dust Mixtures Induced by High-temperature Source Surface. Process Saf. Environ. Prot. 2021, 154, 60–71. [Google Scholar] [CrossRef]
  39. Li, L.; Liu, T.; Li, Z.; Chen, X.; Wang, L.; Feng, S. Different Prevention Effects of Ventilation Dilution on Methane Accumulation at High Temperature Zone in Coal Mine Goafs. Energies 2023, 16, 3168. [Google Scholar] [CrossRef]
  40. Deng, L.; Lei, C.; Xiao, Y.; Cao, K.; Ma, L.; Wang, W.; Bin, L. Determination and Prediction on “three Zones” of Coal Spontaneous Combustion in a Gob of Fully Mechanized Caving Face. Fuel 2018, 211, 458–470. [Google Scholar] [CrossRef]
  41. Ma, D.; Qin, B.; Gao, Y.; Jiang, J.; Feng, B. An Experimental Study on the Methane Migration Induced By Spontaneous Combustion of Coal in Longwall Gobs. Process Saf. Environ. Prot. 2021, 147, 292–299. [Google Scholar] [CrossRef]
Fire 07 00105 g001
Figure 1. Schematic diagram of high-temperature programmed experiment system.
Figure 1. Schematic diagram of high-temperature programmed experiment system.
Fire 07 00105 g001
Fire 07 00105 g002aFire 07 00105 g002b
Figure 2. Generation law of CSC flue gas.
Figure 2. Generation law of CSC flue gas.
Fire 07 00105 g002aFire 07 00105 g002b
Fire 07 00105 g003
Figure 3. Experimental system for testing the explosion characteristics of multi-component gases.
Figure 3. Experimental system for testing the explosion characteristics of multi-component gases.
Fire 07 00105 g003
Fire 07 00105 g004
Figure 4. Variations of Cflue and α with the increase in coal temperature.
Figure 4. Variations of Cflue and α with the increase in coal temperature.
Fire 07 00105 g004
Fire 07 00105 g005aFire 07 00105 g005b
Figure 5. Influence of flue gases of different Cflue and α on the methane explosion limit [35].
Figure 5. Influence of flue gases of different Cflue and α on the methane explosion limit [35].
Fire 07 00105 g005aFire 07 00105 g005b
Fire 07 00105 g006
Figure 6. Influence of flue gas on the explosion range of methane.
Figure 6. Influence of flue gas on the explosion range of methane.
Fire 07 00105 g006
Fire 07 00105 g007
Figure 7. The variation law of |k| with α.
Figure 7. The variation law of |k| with α.
Fire 07 00105 g007
Fire 07 00105 g008
Figure 8. Methane explosion limit fitting.
Figure 8. Methane explosion limit fitting.
Fire 07 00105 g008
Fire 07 00105 g009
Figure 9. Variation law of methane explosion limit during the temperature rising process of coal.
Figure 9. Variation law of methane explosion limit during the temperature rising process of coal.
Fire 07 00105 g009
Fire 07 00105 g010
Figure 10. The variation law of methane explosion range during the temperature rising process of coal.
Figure 10. The variation law of methane explosion range during the temperature rising process of coal.
Fire 07 00105 g010
Table 1. Reflectance and industrial analysis of coal sample maceral groups.
Table 1. Reflectance and industrial analysis of coal sample maceral groups.
Coal SamplesProximate Analysis (w/w %)Vitrinite Reflectance
R0, max (%)
MadAadVdafFCad
Lignite11.3714.6353.4120.590.32
Bituminous1.169.3724.6064.871.22
Anthracite2.1815.456.6475.733.33
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Hu, S.; Li, Y.; Zhu, C.; Lin, B.; Li, Q.; Li, B.; Huang, Z. Investigating the Influence of Flue Gas Induced by Coal Spontaneous Combustion on Methane Explosion Risk. Fire 2024, 7, 105. https://0-doi-org.brum.beds.ac.uk/10.3390/fire7040105

AMA Style

Hu S, Li Y, Zhu C, Lin B, Li Q, Li B, Huang Z. Investigating the Influence of Flue Gas Induced by Coal Spontaneous Combustion on Methane Explosion Risk. Fire. 2024; 7(4):105. https://0-doi-org.brum.beds.ac.uk/10.3390/fire7040105

Chicago/Turabian Style

Hu, Sijia, Yanjun Li, Chuanjie Zhu, Baiquan Lin, Qingzhao Li, Baolin Li, and Zichao Huang. 2024. "Investigating the Influence of Flue Gas Induced by Coal Spontaneous Combustion on Methane Explosion Risk" Fire 7, no. 4: 105. https://0-doi-org.brum.beds.ac.uk/10.3390/fire7040105

Article Metrics

Back to TopTop