AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Journal of Tsinghua University (Science and Technology) Article
PDF (13 MB)
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Publishing Language: Chinese

Full-scale experimental study on longitudinal smoke flow field characteristics in high-speed railway tunnels

Rongliang PAN1,2Yanan WANG3Shunyu YUE1,2Chenhao RAN1,2Huihang CHENG1,2Maohua ZHONG1,2( )
Institute of Public Safety Research, Department of Engineering Physics, Tsinghua University, Beijing 100084, China
School of Safety Science, Tsinghua University, Beijing 100084, China
China Railway Seventh Group Co. Ltd., Wuhan 430200, China
Show Author Information

Abstract

Objective

The design of Chinese high-speed railway tunnels, characterized by their high arched ceiling and large sections, presents unique challenges in terms of heat and mass transfer behaviors. These architectural features significantly influence the dynamics of smoke movement, resulting in distinctive patterns of longitudinal flow and temperature distribution of smoke during a fire, which differ markedly from those observed in conventional highway tunnels.

Methods

To investigate the specifics of smoke flow dynamics, this study embarked on full-scale fire experiments conducted within the Baijiashan tunnel of the Yuxiang high-speed railway between Chongqing and Qianjiang. These experiments were instrumental in capturing critical data on flame height and longitudinal distribution of smoke temperature under various fire scenarios. Building on this empirical foundation, the study analyzed the combustion stages and calculated the longitudinal smoke velocity for each fire scenario examined.

Results

Previous literature has highlighted that the heat release rates in full-scale experiments were calculated based on the equivalent diameter of fire sources, with values of 0.38, 1.01, and 2.52 MW, respectively. It was observed that as the heat release rate increased, there was a corresponding significant uptick in the longitudinal velocity of the smoke. Within the confines of a high-speed railway tunnel, the vertical temperature distribution of fire smoke exhibits a distinct top-hat pattern. This characteristic distribution remains consistent farther from the fire source. Furthermore, this study delineates the boundary between one-dimensional shooting flow (Region Ⅱ) and critical flow (Region Ⅲ) within the context of a Chinese high-speed railway tunnel, identified as x/H ≈3.85 based on experimental data. The study also probes into the suitability of existing models for predicting the longitudinal flow and temperature distribution of fire smoke in long, narrow spaces such as high-speed railway tunnels. It was found that owing to the extended length of one-dimensional shooting flow (Region Ⅱ), models that assume constant smoke thickness fall short in accuracy within this region.

Conclusions

This study revealed that despite the larger net height and cross-sectional area of high-speed railway tunnels compared to those of conventional railway tunnels, the heat release rate of the fire source critically influences the speed at which smoke spreads longitudinally. Moreover, the evolution of vertical temperature distribution is determined by the convective heat transfer coefficient beneath the ceiling and the ceiling jet thickness. As the smoke spreads, the smoke velocity evolution, along with the convective heat transfer coefficient and ceiling jet thickness, gradually stabilizes. This stabilization contributes to the stable top-hat temperature profile observed vertically. Leveraging Froude scaling, a new model for the longitudinal attenuation of smoke temperature rise in Region Ⅲ of a Chinese high-speed railway tunnel has been developed and validated for x/H ≥3.85. The insights gained from this work enrich the experimental research on the characteristics of longitudinal smoke flow in Chinese high-speed railway tunnels. Moreover, the field data obtained on the longitudinal flow and temperature distribution of fire smoke offers theoretical support for evaluating how the longitudinal spread of fire smoke affects personnel evacuation strategies in Chinese high-speed railway tunnels.

Keywords

full-scale experimentfire smokehigh-speed railway tunnelsmoke movement in longitudinal directionlongitudinal temperature distribution
CLC number: U231.96U Document code: A Article ID: 1000-0054(2024)09-1575-12

References

[1]

ZHOU Y L, BI H Q, WANG H L. Influence of the primary components of the high-speed train on fire heat release rate[J]. Archives of Thermodynamics, 2023, 44(1): 37-61.
Google Scholar
[2]
National Bureau of Statistics. Further implementation of the new development concept transportation and communication to achieve leapfrog development: The sixth of the series of reports on economic and social development achievements since the 18th national congress of the communist party of China[R/OL]. Bejing: National Bureau of Statistics, (2022-09-21)[2023-01-01]. https://www.stats.gov.cn/xxgk/jd/sjjd2020/202209/t20220921_1888529.html. (in Chinese)
[3]

GONG J F, WANG W, LI X, et al. Statistics of railway tunnels in China by the end of 2022 and overview of key tunnels of projects newly put into operation in 2022[J]. Tunnel Construction, 2023, 43 (4): 721-738. (in Chinese)
Google Scholar
[4]

BI H Q, ZHOU Y L, WANG H L, et al. Characteristics of fire in high-speed train carriages[J]. Journal of Fire Sciences, 2020, 38 (1): 75-95.
Crossref Google Scholar
[5]

ZHOU Y L, WANG H L, BI H Q, et al. Heat release rate of high-speed train fire in railway tunnels[J]. Tunnelling and Underground Space Technology, 2020, 105: 103563.
Crossref Google Scholar
[6]

TAO L L, YAN X N, ZHANG Y M, et al. Experimental and numerical study on the smoke and velocity distribution in an extra-long railway tunnel fire[J]. Tunnelling and Underground Space Technology, 2021, 117: 104134.
Crossref Google Scholar
[7]
National Railway Administration of the People's Republic of China. Code for design of high speed railway: TB10621-2014[S]. Beijing: China Railway Publishing House, 2014. (in Chinese)
[8]

KARLSSON B, QUINTIERE J G. Enclosure fire dynamics[M]. Boca Raton: CRC Press, 2000.
Crossref
[9]

ZHANG X L, HU L H, ZHANG X C. Flame lengths in two directions underneath a ceiling induced by line-source fire: An experimental study and global model[J]. Proceedings of the Combustion Institute, 2021, 38(3): 4561-4568.
Crossref Google Scholar
[10]

YE K, TANG X, ZHENG Y, et al. Estimating the two-dimensional thermal environment generated by strong fire plumes in an urban utility tunnel[J]. Process Safety and Environmental Protection, 2021, 148: 737-750.
Crossref Google Scholar
[11]

YE K, ZHOU X D, ZHENG Y, et al. Estimating the longitudinal maximum gas temperature attenuation of ceiling jet flows generated by strong fire plumes in an urban utility tunnel[J]. International Journal of Thermal Sciences, 2019, 142: 434-448.
Crossref Google Scholar
[12]
PAN R L. Study on ceiling jet and induced heat feedback mechanism of representative fire scenarios in shield utility tunnel[D]. Xuzhou: China University of Mining and Technology, 2022. (in Chinese)
[13]

HU L H, HUO R, LI Y Z, et al. Full-scale burning tests on studying smoke temperature and velocity along a corridor[J]. Tunnelling and Underground Space Technology, 2005, 20(3): 223-229.
Crossref Google Scholar
[14]

TIAN X L, ZHONG M H, SHI C L, et al. Full-scale tunnel fire experimental study of fire-induced smoke temperature profiles with methanol-gasoline blends[J]. Applied Thermal Engineering, 2017, 116: 233-243.
Crossref Google Scholar
[15]

LIU C, ZHONG M H, SHI C L, et al. Temperature profile of fire-induced smoke in node area of a full-scale mine shaft tunnel under natural ventilation[J]. Applied Thermal Engineering, 2017, 110: 382-389.
Crossref Google Scholar
[16]

LIU C, ZHONG M H, TIAN X L, et al. Experimental and numerical study on fire-induced smoke temperature in connected area of metro tunnel under natural ventilation[J]. International Journal of Thermal Sciences, 2019, 138: 84-97.
Crossref Google Scholar
[17]
INGASON H, LI Y Z, LÖNNERMARK A. Tunnel fire dynamics[M]. New York: Springer, 2015.
Crossref
[18]

SHI C L, LI J, XU X. Full-scale tests on smoke temperature distribution in long-large subway tunnels with longitudinal mechanical ventilation[J]. Tunnelling and Underground Space Technology, 2021, 109: 103784.
Crossref Google Scholar
[19]

ZHONG M H, LIU C. Progress of full-scale experimental study for fire prevention and control in metro tunnel[J]. Bulletin of National Natural Science Foundation of China, 2021, 35 (6): 878-884. (in Chinese)
Google Scholar
[20]

ZHONG M H, CHENG H H, CHEN J F, et al. Full-scale experimental design and engineering practice of metro station fire[J] Experimental Technology and Management, 2022, 39(9): 1-8. (in Chinese)
Google Scholar
[21]

CHENG H H, LIU C, CHEN J F, et al. Full-scale experimental study on fire under natural ventilation in the T-shaped and curved tunnel groups[J]. Tunnelling and Underground Space Technology, 2022, 123: 104442.
Crossref Google Scholar
[22]

OKA Y, IMAZEKI O. Temperature and velocity distributions of a ceiling jet along an inclined ceiling-Part 1: Approximation with exponential function[J]. Fire Safety Journal, 2014, 65: 41-52.
Crossref Google Scholar
[23]
HURLEY M J, GOTTUK D T, HALL J R, et al. SFPE handbook of fire protection engineering[M]. 5th ed. New York: Springer, 2016.
Crossref
[24]

BABRAUSKAS V. Estimating large pool fire burning rates[J]. Fire Technology, 1983, 19(4): 251-261.
Crossref Google Scholar
[25]

OKA Y, OKA H. Velocity and temperature attenuation of a ceiling-jet along a horizontal tunnel with a flat ceiling and natural ventilation[J]. Tunnelling and Underground Space Technology, 2016, 56: 79-89.
Crossref Google Scholar
[26]

GUO Q H, LI Y Z, INGASON H, et al. Theoretical studies on buoyancy-driven ceiling jets of tunnel fires with natural ventilation[J]. Fire Safety Journal, 2020: 103228.
Crossref Google Scholar
[27]

OKA Y, OKA H, IMAZEKI O. Ceiling-jet thickness and vertical distribution along flat-ceilinged horizontal tunnel with natural ventilation[J]. Tunnelling and Underground Space Technology, 2016, 53: 68-77.
Crossref Google Scholar
[28]
ALPERT R L. Ceiling jet flows[M]// HURLEY M J, GOTTUK D T, HALL J R, et al. SFPE handbook of fire protection engineering. 5th ed. New York: Springer, 2016: 429-454.
Crossref
[29]

TANNO A, OKA H, KAMIYA K, et al. Determination of smoke layer thickness using vertical temperature distribution in tunnel fires under natural ventilation[J]. Tunnelling and Underground Space Technology, 2022, 119: 104257.
Crossref Google Scholar
[30]

PAN R L, ZHU G Q, XU G, et al. Experimental analysis on burning rate and temperature profile produced by pool fire in a curved tunnel as a function of fire location[J]. Process Safety and Environmental Protection, 2021, 152: 549-567.
Crossref Google Scholar
[31]

HU L H, HUO R, CHOW W K. Studies on buoyancy-driven back-layering flow in tunnel fires[J]. Experimental Thermal and Fluid Science, 2008, 32(8): 1468-1483.
Crossref Google Scholar
[32]
INGASON H, LI Y Z, LÖNNERMARK A. Gas temperatures[M]// INGASON H, LI Y Z, LÖNNERMARK A. Tunnel fire dynamics. New York: Springer, 2015: 207-231.
Crossref
[33]

LI Y Z, INGASON H. Model scale tunnel fire tests with automatic sprinkler[J]. Fire Safety Journal, 2013, 61: 298-313.
Crossref Google Scholar
[34]

HU L H, HUO R, PENG W, et al. On the maximum smoke temperature under the ceiling in tunnel fires[J]. Tunnelling and Underground Space Technology, 2006, 21(6): 650-655.
Crossref Google Scholar
Journal of Tsinghua University (Science and Technology)
Volume 64 Issue 9,
September 2024
Pages 1575-1586
DOI: 10.16511/j.cnki.qhdxxb.2024.21.015
Cite this article:
PAN R, WANG Y, YUE S, et al. Full-scale experimental study on longitudinal smoke flow field characteristics in high-speed railway tunnels. Journal of Tsinghua University (Science and Technology), 2024, 64(9): 1575-1586. https://doi.org/10.16511/j.cnki.qhdxxb.2024.21.015

41

Views

4

Downloads

0

Crossref

0

Scopus

0

CSCD

Altmetrics
Received: 16 January 2024
Published: 15 September 2024
© Journal of Tsinghua University (Science and Technology). All rights reserved.
Return