基于气-固两相流的深埋隧道烟尘运移特征

doi:10.16265/j.cnki.issn1003-3033.2024.11.1590

中国安全科学学报 ›› 2024, Vol. 34 ›› Issue (11): 213-219.doi: 10.16265/j.cnki.issn1003-3033.2024.11.1590

基于气-固两相流的深埋隧道烟尘运移特征

吴宗之¹^,²(), 周玉竹²^,³, 魏丁一⁴^,^**(), 曹伟杰⁴, 马文谨⁴, 余杰²

¹ 中国职业安全健康协会,北京 100029
² 北京科技大学土木与资源工程学院,北京 100083
³ 四川铸创安全科技有限公司,四川成都 610040
⁴ 河南工程学院资源与安全工程学院,河南郑州 451191

收稿日期:2024-06-11 修回日期:2024-09-12 出版日期:2024-11-28
通信作者:
** 魏丁一(1991—),男,河南禹州人,博士,讲师,主要从事职业健康安全方面的研究。E-mail:weidy103@126.com。
作者简介:
吴宗之 (1963—),男,安徽宿松人,博士,研究员,博士生导师,主要从事重大危险源监控、风险评价、应急管理、职业健康等方面的研究。E-mail:wuzongzhi@vip.sina.com。
周玉竹, 正高级工程师
基金资助:
国家卫生健康委粉尘危害工程防护重点实验室开放课题(KLECDH20230201); 河南省高等学校重点科研项目(23B440005); 河南工程学院博士培育基金(D2022021)

Characterization of smoke and dust transport in deep buried tunnel based on gas-solid two-phase flow

WU Zongzhi¹^,²(), ZHOU Yuzhu²^,³, WEI Dingyi⁴^,^**(), CAO Weijie⁴, MA Wenjin⁴, YU Jie²

¹ China Occupational Safety and Health Association, Beijing 100029, China
² School of Civil and Resource Engineering, University of Science and Technology Beijing, Beijing 100083, China
³ Sichuan Zhuchuang Safety Technology Co., Ltd., Chengdu Sichuan 610040, China
⁴ School of Resource and Safety Engineering, Henan University of Engineering, Zhengzhou Henan 451191, China

Received:2024-06-11 Revised:2024-09-12 Published:2024-11-28

摘要/Abstract

摘要：

为提高深埋隧道施工机械的耐用性及改善工人作业环境,基于气-固两相流理论,选取CO和粉尘作为主要研究对象,利用Fluent软件建立深埋隧道物理模型,通过模拟分析深埋隧道中不同围岩温度及风筒出口速度对烟尘运移过程的影响。结果表明:爆破后,CO在抛掷区内均匀分布,随通风时间的增加,CO的运移呈现为平移和扩散2种方式,CO以团状的形式向隧道外排出,且隧道壁处的CO运移速度大于隧道中心的运移速度;爆破瞬间,粉尘大量聚集在工作面附近,随通风时间的增加,粉尘不断向隧道外排出;其中,围岩温度对CO的运移有一定影响,且围岩温度越高,CO的运移速度越快,但围岩温度对粉尘运移的影响相对较小;风筒出口速度对CO及粉尘的运移均有较大影响,且风筒出口速度越大,CO及粉尘的运移速度越快,在现场应用中要结合实际条件和经济预算情况合理选择相关设备。

关键词: 气-固两相流, 深埋隧道, 烟尘运移, 风筒出口速度, 围岩温度

Abstract:

In order to improve the durability of the construction machine and the working environment in deep buried tunnels, based on the theory of gas-solid two-phase flow, CO and dust were selected as the main objects of study, and a physical model of deep buried tunnels was established by Fluent software. The effects of different surrounding rock temperatures and the outlet speed of the wind pipe on the transport process of soot in deep tunnels were investigated through simulation. The results show that after blasting, CO is uniformly distributed in the throwing area. With the increase of ventilation time, the CO transport shows two modes of translation and diffusion. CO is discharged out of the tunnel in the form of a mass, and the CO transport speed at the tunnel wall is larger than that at the center of the tunnel. At the moment of blasting, a large amount of dust gathers near the working face, and with the increase of ventilation time, the dust is continuously discharged out of the tunnel. Among them, the temperature of the surrounding rock has a certain effect on the transportation of CO. The higher the temperature of the surrounding rock, the faster the transportation of CO. However, the effect of the surrounding rock temperature on the transportation of dust is relatively small. The outlet speed of the wind pipe has a greater impact on the transportation of CO and dust. The greater the outlet speed of the wind pipe, the faster the transportation of CO and dust. The field application should be combined with the actual conditions and economic budget to select the relevant equipment.

Key words: gas-solid two-phase flow, deep buried tunnels, smoke and dust transport, outlet speed of wind pipe, surrounding rock temperature

中图分类号:

X964工业防尘

吴宗之, 周玉竹, 魏丁一, 曹伟杰, 马文谨, 余杰. 基于气-固两相流的深埋隧道烟尘运移特征[J]. 中国安全科学学报, 2024, 34(11): 213-219.

WU Zongzhi, ZHOU Yuzhu, WEI Dingyi, CAO Weijie, MA Wenjin, YU Jie. Characterization of smoke and dust transport in deep buried tunnel based on gas-solid two-phase flow[J]. China Safety Science Journal, 2024, 34(11): 213-219.

图/表 9

表1

图1

图2

图3

图4

图5

图6

图7

图8

参考文献 11

[1]	张汉中, 孟文俊, 王贝贝. 基于CFD-DEM耦合仿真的抓斗卸料气固两相流场研究[J]. 矿业研究与开发, 2022, 42(4): 166-172.
	ZHANG Hanzhong, MENG Wenjun, WANG Beibei. Research on gas-solid two-phase flow field in grab discharge based on CFD-DEM coupling simulation[J]. Mining Research and Development, 2022, 42(4): 166-172.
[2]	陆国琛, 秦丙林, 田天, 等. 气井井筒临界携垢流量计算与分析[J]. 石油机械, 2023, 51(10): 107-112.
	LU Guochen, QIN Binglin, TIAN Tian, et al. Calculation and analysis of critical scale carrying flow rate in gas wells[J]. China Petroleum Machinery, 2023, 51(10): 107-112.
[3]	张玥, 唐诗洋, 丁会敏, 等. 煤矸石CFB锅炉内气固两相流动特性模拟研究[J]. 自动化技术与应用, 2023, 42(12): 136-138, 142.
	ZHANG Yue, TANG Shiyang, DING Huimin, et al. Numerical simulation of gas-solid two-phase flow characteristics in coal gangue CFB boiler[J]. Techniques of Automation and Applications, 2023, 42(12): 136-138, 142.
[4]	刘杰, 周皓文, 王婉青, 等. 某高原螺旋施工隧道CO分布及扩散特征[J]. 中国安全科学学报, 2022, 32(12): 79-87. doi: 10.16265/j.cnki.issn1003-3033.2022.12.0110
	LIU Jie, ZHOU Haowen, WANG Wanqing, et al. Study on CO distribution and diffusion in spiral construction tunnel on plaleau[J]. China Safety Science Journal, 2022, 32(12): 79-87. doi: 10.16265/j.cnki.issn1003-3033.2022.12.0110
[5]	王冕. 掘进巷道流场结构及粉尘沉降规律相似模拟研究[J]. 矿业安全与环保, 2021, 48(3): 56-61.
	WANG Mian. Similar simulation study on the flow field structure and the law of dust settlement of heading roadway[J]. Mining Safety Environmental Protection, 2021, 48(3): 56-61.
[6]	SAGAR P, TED Z, GARY K, et al. New insights into the wind-dust relationship in sandblasting and direct aerodynamic entrainment from wind tunnel experiments[J]. Journal of Geophysical Research: Atmospheres, 2016, 121(4): 1 776-1 792.
[7]	WOUTER D, UDO H, DIETER F, et al. Wind tunnel and CFD study of dust dispersion from pesticide-treated maize seed[J]. Computers and Electronics in Agriculture, 2016, 128: 27-33.
[8]	BECK W, SEAMAN E, SHAHAN R, et al. Open-air sprays for capturing and controlling airborne float coal dust on longwall faces[J]. Mining Engineering, 2018, 70(1): 42-48. doi: 10.19150/me.7978 pmid: 29348700
[9]	乔力伟, 蒋葛夫. 双向掘进隧道游离SiO₂粉尘扩散规律模拟与分析[J]. 环境科学研究, 2019, 32(6): 1 043-1 051.
	QIAO Liwei, JIANG Gefu. Numerical analysis and simulation of SiO₂ dust diffusion in tunnel by inclined shaft[J]. Research of Environmental Sciences, 2019, 32(6): 1 043-1 051.
[10]	王将, 袁大军, 金大龙, 等. 基于非线型滑动面假设的盾构隧道松动土压力计算模型研究[J]. 铁道学报, 2021, 43(6):165-172.
	WANG Jiang, YUAN Dajun, JIN Dalong, et al. Research on calculation model for loosening earth pressure of shield tunnel based on assumption of non-liner sliding surface[J]. Journal of the China Railway Society, 2021, 43(6): 165-172.
[11]	DU Bo, LI Yanhe, CHEN Xingming, et al. Optimization of paste backfilling material ratios for long-distance transportation[J]. Engineering Letters, 2024, 32(3): 595-600.

参数	设定
求解器	压力基
湍流模型	k-ε双方程模型
能量方程	打开
离散相模型	打开
压力速度耦合	简单
梯度方案	基于最小二乘法
瞬态离散方案	一阶隐式
炮烟抛掷范围/(L·m^-1)	60
CO初始体积分数/%	0.125
与连续相的交互	打开
离散相模型迭代间隔	10
跟踪最大步数	9 000
非定常跟踪	打开
按流动时间步跟踪	打开
注射类型	打开
颗粒材料	大理岩
粒径分布	R-R分布
离散随机轨道模型	打开
使用曲线法方向注入	打开
总流速/(kg·s^-1)	3

基于气-固两相流的深埋隧道烟尘运移特征

Characterization of smoke and dust transport in deep buried tunnel based on gas-solid two-phase flow

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 9

参考文献 11

相关文章 4

编辑推荐

Metrics

本文评价

[1]	游波, 崔大雄, 刘何清, 鲁义, 杨芯宇. 不同隔热材料下的深井巷道隔热降温模拟研究[J]. 中国安全科学学报, 2024, 34(2): 153-160.
[2]	周玉竹, 魏丁一, 曹伟杰, 卢增雄, 林明磊, 杜小坤. 钻爆法施工深埋隧道喷雾降尘数值模拟研究[J]. 中国安全科学学报, 2024, 34(11): 66-72.
[3]	崔大雄, 游波, 高科, 杨明, 韩巧云, 陈元森. 铺设隔热层对巷道降温效果的影响分析[J]. 中国安全科学学报, 2024, 34(11): 153-162.
[4]	高建良，杨明. 巷道围岩温度分布及调热圈半径的影响因素分析[J]. 中国安全科学学报, 2005, 15(2): 73-.