Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology
Abstract
:1. Introduction
2. Experiment and Theoretical Analysis
2.1. Experiments of Extraction
2.2. Extraction of Residual Coal Group Content Test
2.3. Determination of the Macroscopic Characteristic Parameters of Coal Oxidation
2.3.1. Temperature-Programmed Experiment Test
2.3.2. Isothermal Temperature Difference Leading Test
2.3.3. Thermal Analysis Combined Test (TG-DSC)
2.4. The Principle of Gray Correlation Analysis
- Determine the reference sequence (1) and the comparison sequence (2):
- 2.
- The initial value method is used to make the data dimensionless.
- 3.
- Calculate the correlation coefficient; the calculation formula is as follows (3):
- 4.
- Calculate the correlation degree, that is, calculate the average value of the obtained correlation coefficient to obtain the correlation degree, as shown in Equation (4):
2.5. Analysis Process of the Influence Mechanism of the Active Structure on Coal Spontaneous-Combustion Based on Macro–Micro Correlation
3. Results and Analysis
3.1. Change in Active Group Content of Extracted Residual Coal
3.2. Effect of Active Group Content on Coal Spontaneous Combustion
3.3. Effect of Active Group Content on Gas Products
Gray Correlation Analysis of Active Groups and Gas Products
- (1)
- The correlation between CO, CO2 and different active group structures
- (2)
- The correlation between CH4, C2H4, C2H6 and different active group structures
3.4. Gray Correlation Analysis of Active Groups and Thermal Properties of Coal
4. Discussion
- (1)
- Extraction of the coal molecular active group structure
- (2)
- Weakening the reactivity intensity of coal spontaneous-combustion
- (3)
- Weakening the characterization strength of coal thermophysical properties
5. Conclusions
- (1)
- The influence of the active structure on the process of coal spontaneous combustion is different. The oxygen-containing structure represented by -OH mainly affects the reactivity in the low-temperature oxidation process (30~90 °C). The aliphatic structure represented by -COOH mainly affects the reactivity in the middle stage of coal spontaneous combustion (90~130 °C). The aromatic ring structure determines the reactivity intensity of coal spontaneous combustion in the high-temperature stage (130~170 °C).
- (2)
- The gray correlation method was used to calculate the correlation degree between the active structure of coal molecules and gas products. It was found that the gas products produced in the process of coal spontaneous combustion had a large correlation degree with -OH, -COOH, -CH2, C = C and other structures. With the development of the coal spontaneous-combustion process, various active structures have participated in the reaction, thus generating oxygen-containing gases and alkanes and other iconic gases. The stripping extraction of the active structure leads to a decrease in the content of the groups involved in the reaction, resulting in a decrease in gas production, thereby weakening the spontaneous-combustion of coal.
- (3)
- Through gray correlation analysis, it is found that the main active groups affecting the thermal properties of coal are C=C in the molecular skeleton of coal, -COOH of aliphatic hydrocarbons and oxygen-containing functional groups represented by -OH. In the process of coal spontaneous combustion, the active structure reacts with oxygen to generate heat. The stripping of the active structure leads to a decrease in the intensity of the coal–oxygen composite reaction and a decrease in the amount of heat released, resulting in a delay in the ignition-point temperature and a decrease in the quality of the coal involved in the combustion. Finally, the coal spontaneous-combustion is weakened.
- (4)
- The influence mechanism of the key active structure of coal molecules based on extraction technology on spontaneous combustion characteristics is divided into three parts. (1) Extraction destroys the connection bond between coal molecules or the dominant group structure of the coal spontaneous-combustion reaction. (2) Stripping the dominant group structure of the coal spontaneous-combustion reaction weakens the reaction activity intensity in each process stage of coal spontaneous combustion, prolongs the temperature range of the heat storage reaction or increases the lower limit of the rapid reaction temperature threshold. (3) As a result, the thermal physical property characterization strength of coal spontaneous combustion is weakened, which is manifested as delaying the ignition-point temperature of coal or reducing the quality of coal involved in combustion.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Group | Active Structure Category | YM | THF | MT | CYC | CYH | C + A + A | AE | AOT | EG | TP | EG + TP |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Aromatic hydrocarbon | C-H | 108 | 77 | 91 | 56 | 42 | 46 | 54 | 51 | 73 | 45 | 40 |
C=C | 185 | 199 | 157 | 190 | 204 | 201 | 166 | 211 | 173 | 179 | 172 | |
Aliphatic hydrocarbon | -CH3 | 52 | 43 | 15 | 49 | 29 | 40 | 54 | 130 | 58 | 65 | 45 |
-CH2 | 117 | 73 | 101 | 44 | 28 | 63 | 96 | 145 | 103 | 78 | 111 | |
Oxygen-containing functional groups | -COOH | 187 | 161 | 154 | 176 | 176 | 181 | 184 | 174 | 185 | 183 | 168 |
-OH | 435 | 388 | 310 | 389 | 463 | 428 | 357 | 480 | 357 | 367 | 425 | |
C-O | 177 | 137 | 147 | 144 | 134 | 150 | 145 | 153 | 146 | 154 | 160 | |
C=O | 66 | 59 | 89 | 75 | 93 | 75 | 63 | 56 | 50 | 50 | 50 |
Group | CH4 | CO | CO2 | C2H6 | C2H4 |
---|---|---|---|---|---|
YM | 0.48549 | 38.33111 | 177.61669 | 0.62251 | 0.34461 |
THF | 0.43321 | 35.06035 | 178.00860 | 0.2425 | 0.17216 |
MT | 0.37073 | 40.99266 | 178.00860 | 0.28744 | 0.18847 |
CYC | 0.27937 | 37.15417 | 158.69036 | 0.16944 | 0.14322 |
CYH | 0.37136 | 36.34579 | 174.96191 | 0.1641 | 0.25814 |
CYC + AOT + AE | 0.24421 | 28.80616 | 127.02185 | 0.23388 | 0.12843 |
AE | 0.48858 | 36.17914 | 145.47469 | 0.9406 | 0.36273 |
AOT | 0.43511 | 43.82697 | 201.89459 | 0.23651 | 0.15241 |
EG | 0.26614 | 32.19166 | 173.87919 | 0.10831 | 0.11619 |
TP | 0.26061 | 39.30838 | 200.26572 | 0.12891 | 0.13512 |
EG + TP | 0.18521 | 32.19166 | 169.43187 | 0.09223 | 0.10690 |
Group | Ignition Temperature/°C | Ignition-Point Quality/% | Peak Temperature of Heat Release/°C | Peak Temperature Quality/% | Burning Temperature/°C | Burnout Temperature Quality/% | Spontaneous-Combustion Index Value |
---|---|---|---|---|---|---|---|
YM | 402.68 | 93.76 | 459.33 | 68.44 | 543.16 | 23.63 | 628.01 |
THF | 415.09 | 82.86 | 464.42 | 61.76 | 542.79 | 24.13 | 773.34 |
MT | 411.51 | 84.76 | 458.10 | 64.63 | 546.38 | 22.88 | 704.32 |
CYC | 404.66 | 87.17 | 443.06 | 70.81 | 550.84 | 21.43 | 687.42 |
CYH | 406.93 | 87.31 | 452.94 | 69.26 | 552.29 | 21.95 | 698.24 |
C + A + A | 417.94 | 75.94 | 453.72 | 62.02 | 543.11 | 21.99 | 790.78 |
AE | 402.88 | 92.18 | 457.74 | 68.13 | 540.10 | 22.58 | 625.89 |
AOT | 410.32 | 85.30 | 452.58 | 68.91 | 540.76 | 23.40 | 692.23 |
EG | 403.72 | 90.14 | 448.07 | 73.16 | 555.70 | 23.90 | 698.63 |
TP | 400.65 | 89.73 | 454.21 | 72.42 | 545.80 | 23.48 | 712.48 |
EG + TP | 416.52 | 81.35 | 449.09 | 72.51 | 557.23 | 23.27 | 843.20 |
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Guo, J.; Wu, Y.; Liu, Y.; Cai, G.; Li, D.; Jin, Y. Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology. Fire 2024, 7, 283. https://doi.org/10.3390/fire7080283
Guo J, Wu Y, Liu Y, Cai G, Li D, Jin Y. Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology. Fire. 2024; 7(8):283. https://doi.org/10.3390/fire7080283
Chicago/Turabian StyleGuo, Jun, Yunfei Wu, Yin Liu, Guobin Cai, Dailin Li, and Yan Jin. 2024. "Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology" Fire 7, no. 8: 283. https://doi.org/10.3390/fire7080283
APA StyleGuo, J., Wu, Y., Liu, Y., Cai, G., Li, D., & Jin, Y. (2024). Study on the Influence Mechanism of the Key Active Structure of Coal Molecules on Spontaneous Combustion Characteristics Based on Extraction Technology. Fire, 7(8), 283. https://doi.org/10.3390/fire7080283