Effects of Abrupt Cross-Section Area Change on theMultiparameter Propagation Characteristics of Premixed Methane–Air Explosion in Pipes
Abstract
:1. Introduction
2. Experimental Research on Gas Explosion Shock Wave along Pipes with Abrupt Cross-Section Area Change
2.1. Experimental System
2.2. Experimental Scheme
2.3. Experimental Results and Analysis
3. Numerical Simulations of Gas Explosion along Pipelines with Abrupt Cross-Section Area Changes
3.1. Numerical Calculation Methods
3.2. Analysis of Pressure Wave Transmission Process in the Pipes
3.3. Change Laws of Explosion Temperature in the Pipe
3.4. Change Laws of Vorticity and Kinetic Energy
4. Conclusions
- (1)
- When the cross-section area of the pipe changes abruptly from small to large, the shock wave overpressure decreases. In contrast, the shock wave overpressure increases when the cross-section of the pipe changes abruptly from large to small. When the diameter of the larger section of pipe is less than 0.24 m, the peak overpressure decreases, then sharply increases, and finally decreases. However, when the diameter is greater than 0.24 m, the peak overpressure exhibits a more complex sequence of decreasing, increasing, decreasing, increasing, and finally decreasing;
- (2)
- The overpressure changes in pipes along abrupt cross-section changes can be characterized by the attenuation coefficient, increase coefficient, and reflection coefficient. For a fixed ratio of cross-section areas, the attenuation coefficient increases with an increase in initial peak overpressure before the abrupt cross-section change, whereas the increasing coefficient and reflection coefficient both exhibit a decreasing trend. The coupling relationships between attenuation coefficients, increasing coefficients, reflection coefficients, and initial peak pressure and the ratio of cross-section areas were obtained;
- (3)
- The peak temperature decreases as the cross-section area changes. Moreover, a larger fuel volume creates a greater decrease in peak temperature. This demonstrates that the counter-current effect of the gas explosion pressure wave and reflected wave can inhibit the propagation of the explosion flame under the influence of an abrupt change in cross-section structure;
- (4)
- The vorticity in pipes with abrupt cross-section area changes presents a clear peak, which indicates that gas explosion propagation is affected by the action of turbulence induced by an abrupt cross-section change. Moreover, a larger fuel volume or ratio of cross-section areas has a more obvious effect on turbulence action. In the propagation process of a gas explosion, when the cross-section area changes abruptly, kinetic energy is converted to static pressure energy and vice versa. This indicates that the large eddy motion formed by strong restraint enhances kinetic energy.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Measurement Point | P1 | P2 | P3 | P4 | P5 | P6 | P7 | P8 | P9 | P10 |
---|---|---|---|---|---|---|---|---|---|---|
Distance | 10.25 | 11 | 11.75 | 12.25 | 13 | 13.75 | 14.25 | 15 | 16 | 17 |
Fuel Volume/m3 | Cross-Section Change from Small to Large | Cross-Section Change from Large to Small | |||||||
---|---|---|---|---|---|---|---|---|---|
k | Ω | Ψ | |||||||
0.18 | 1.23 | 0.7695 | 0.7155 | 1.075 | 0.6230 | 0.6422 | 0.6642 | 0.970 | 1.066 |
1.78 | 0.7695 | 0.7011 | 1.098 | 0.5663 | 0.6446 | 0.8735 | 0.879 | 1.542 | |
2.42 | 0.7701 | 0.4622 | 1.666 | 0.5239 | 0.6192 | 0.9297 | 0.846 | 1.775 | |
3.16 | 0.7685 | 0.4635 | 1.658 | 0.4815 | 0.5741 | 0.9145 | 0.839 | 1.899 | |
4.00 | 0.7638 | 0.4646 | 1.644 | 0.4475 | 0.5299 | 0.9020 | 0.844 | 2.016 | |
0.23 | 1.23 | 0.9915 | 0.9013 | 1.100 | 0.7452 | 0.8710 | 0.7542 | 0.856 | 1.012 |
1.78 | 0.9903 | 0.9263 | 1.069 | 0.7279 | 0.8734 | 1.1648 | 0.833 | 1.600 | |
2.42 | 0.9995 | 0.5995 | 1.667 | 0.6655 | 0.7745 | 1.1846 | 0.859 | 1.780 | |
3.16 | 0.9910 | 0.6014 | 1.648 | 0.6156 | 0.7451 | 1.1716 | 0.826 | 1.903 | |
4.00 | 0.9845 | 0.6078 | 1.620 | 0.5742 | 0.6978 | 1.1565 | 0.823 | 2.014 | |
0.28 | 1.23 | 1.2197 | 1.1328 | 1.077 | 0.9831 | 1.1473 | 0.9177 | 0.857 | 0.934 |
1.78 | 1.2196 | 1.0067 | 1.211 | 0.9022 | 1.1859 | 1.3102 | 0.761 | 1.452 | |
2.42 | 1.2194 | 0.7085 | 1.721 | 0.8361 | 1.1501 | 1.4748 | 0.727 | 1.764 | |
3.16 | 1.2166 | 0.7156 | 1.700 | 0.7755 | 1.1123 | 1.4566 | 0.697 | 1.878 | |
4.00 | 1.2140 | 0.7226 | 1.680 | 0.7197 | 1.0275 | 1.4125 | 0.700 | 1.963 |
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Qiu, J.; Jiang, B.; Tang, M.; Zhou, L.; Yang, Y. Effects of Abrupt Cross-Section Area Change on theMultiparameter Propagation Characteristics of Premixed Methane–Air Explosion in Pipes. Appl. Sci. 2023, 13, 6372. https://doi.org/10.3390/app13116372
Qiu J, Jiang B, Tang M, Zhou L, Yang Y. Effects of Abrupt Cross-Section Area Change on theMultiparameter Propagation Characteristics of Premixed Methane–Air Explosion in Pipes. Applied Sciences. 2023; 13(11):6372. https://doi.org/10.3390/app13116372
Chicago/Turabian StyleQiu, Jinwei, Bingyou Jiang, Mingyun Tang, Liang Zhou, and Yingdi Yang. 2023. "Effects of Abrupt Cross-Section Area Change on theMultiparameter Propagation Characteristics of Premixed Methane–Air Explosion in Pipes" Applied Sciences 13, no. 11: 6372. https://doi.org/10.3390/app13116372
APA StyleQiu, J., Jiang, B., Tang, M., Zhou, L., & Yang, Y. (2023). Effects of Abrupt Cross-Section Area Change on theMultiparameter Propagation Characteristics of Premixed Methane–Air Explosion in Pipes. Applied Sciences, 13(11), 6372. https://doi.org/10.3390/app13116372