Study on traceability of dangerous gas leakage based on complex algorithm

doi:10.16265/j.cnki.issn1003-3033.2024.10.1950

Abstract

Abstract:

In order to ensure the efficiency of response and disposal and reduce the damage caused by the hazardous gas leaks, it was necessary to quickly and accurately trace the location of the leak point as well as the source strength. In this article, a method of hazard location and source strength determination based on a complex algorithm was proposed. The basis of the algorithm was to compare the difference between the concentration of the monitored gas and the concentration calculated by the atmospheric diffusion model, and take the difference as the objective function, so that the parameter with the smallest objective function value was the optimal result of the source intensity and position. The results show that the complex algorithm can quickly and accurately obtain the location and source strength of the leakage source. Compared with the traditional simplex method, the compound algorithm has no restriction on the selection of initial value. Even if the selected initial value has a large deviation from the true value, the position and intensity of the source can be quickly obtained through the iteration of the complex algorithm, avoiding the shortcoming of the traditional simplex method, which has high requirements on the selection of initial value. A comparison of particle swarm optimization, genetic algorithm, simplex and complex algorithm is made in three aspects: traceability efficiency, traceability accuracy and traceability stability, which depicts that the complex algorithm is progressive. The complex algorithm can be applied to trace sources and determine source strength for continuous and instantaneous releases.

Key words: dangerous gas leakage, trace to the source, complex algorithm, accuracy, efficiency

CLC Number:

X937

ZHANG Jianwen, LU Shilin, FENG Leilei. Study on traceability of dangerous gas leakage based on complex algorithm[J]. China Safety Science Journal, 2024, 34(10): 58-63.

Figures/Tables 4

Fig.1

Fig.2

Fig.3

Table 1

References 16

[1]	王轶宏, 翟越, 李艳, 等. 城市燃气管网泄漏蒸气云爆炸事故风险评估[J]. 中国安全科学学报, 2023, 33(2): 194-201. doi: 10.16265/j.cnki.issn1003-3033.2023.02.0285
	WANG Yihong, ZHAI Yue, LI Yan, et al. Risk assessment of steam cloud explosion accident in city gas pipeline network[J]. China Safety Science Journal, 2023, 33(2): 194-201. doi: 10.16265/j.cnki.issn1003-3033.2023.02.0285
[2]	JEREMIC J, NEHORAI A. Landmine detection and localization using chemical sensor array processing[J]. IEEE Transactions on Signal Processing, 2000, 48(5): 386-395.
[3]	CHOW F K, KOSOVIC B, CHAN S. Source inversion for contaminant plume dispersion in urban environments using building-resolving simulations[J]. Journal of Applied Meteorology and Climatology, 2008, 47(6): 1553-1572.
[4]	BERA B, BHATTACHARJEE S, SENGUPTA N, et al. Variation and dispersal of PM₁₀ and PM_2.5 during COVID-19 lockdown over Kolkata metropolitan city, India investigated through HYSPLIT model[J]. Geoscience Frontiers, 2022, 13(1): 291-302.
[5]	PORAT B, NEHORAI A. Localizing vapor-emitting sources by moving sensors[J]. IEEE Transactions on Signal Processing, 1996, 44(4): 1018-1021.
[6]	SOHN M D, REYNOLDS P, GADGIL A J, et al. Rapidly locating sources and predicting contaminant dispersion in buildings[C]. the Indoor Air 2002 Conference, 2002: 211-216.
[7]	SOHN M D, SEXTRO R G, GADGIL A J, et al. Responding to sudden pollutant releases in office buildings: framework and analysis tools[J]. Indoor Air, 2003, 13(3): 267-276.
[8]	CUI Shigang, GUANG Mingzeng, FAN Liang, et al. Simulated annealing algorithm based single robot odor source localization strategy[J]. Applied Mechanics and Materials, 2014, 494/495: 1286-1289.
[9]	KEATS A, YEE E, LIEN F S. Bayesian inference for source determination with applications to a complex urban environment[J]. Atmospheric Environment, 2007, 41(3): 465-479.
[10]	ZOU Yuhua, LUO Dehan. A modified ant colony algorithm used for multi-robot odor source localization[C]. 4^th International Conference on Intelligent Computing:Advanced Intelligent Computing Theories and Applications with Aspects, 2008: 502-509.
[11]	SAXENA N, NATESAN D, SANE S P. Odor source localization in complex visual environments by fruit flies[J]. The Journal of Experimental Biology, 2018, 221(2): 1-15.
[12]	陈增强. 混合遗传-模式搜索算法在毒气泄漏中的源强反算研究[D]. 北京: 北京化工大学, 2009.
	CHEN Zengqiang. Research on source-strength inversion of hybrid genetic-pattern search algorithm in gas leakage[D]. Beijing: Beijing University of Chemical Technology, 2009.
[13]	张建文, 王煜薇, 郑小平, 等. 基于混合遗传-Nelder Mead 单纯形算法的源强及位置反算[J]. 系统工程理论与实践, 2011, 31(8): 1581-1587.
	ZHANG Jianwen, WANG Yuwei, ZHENG Xiaoping, et al. Inverse calculation of source strength and position based on mixed genetic Nelder Mead simplex algorithm[J]. Systems Engineering-Theory and Practice, 2011, 31(8): 1581-1587.
[14]	刘畅, 苏腾, 周汝, 等. 修正高斯模型下气体泄漏源项信息反算研究[J]. 中国安全科学学报, 2022, 32(7): 98-104. doi: 10.16265/j.cnki.issn1003-3033.2022.07.0741
	LIU Chang, SU Teng, ZHOU Ru, et al. Research on inverse calculation of gas leakage source term information under modified Gaussian Model[J]. China Safety Science Journal, 2022, 32(7): 98-104. doi: 10.16265/j.cnki.issn1003-3033.2022.07.0741
[15]	LUANGPAI BOON P. Variable neighborhood simplex search methods for global optimization models[J]. Journal of Computer Science, 2012, 8(4): 613-620.
[16]	NELDER J, AMEAD R A. Simplex method for function minimization[J]. The Computer Journal, 1965, 7(4): 308-313.

溯源方法	粒子群算法	遗传算法	混合粒子群—单纯形	复合形算法
初始值选取	无影响	无影响	无影响	无影响
寻优迭代次数:场景1、2	20/50	50/100	120/221	900/1022
溯源时间/s:场景1、2	0.62/2.12	0.19/0.56	1.11/3.32	0.35/1.20
泄漏源位置/m:场景1、2	(9.8, 5.2, 3.6)/ (10.5, 21.1, 3.3)	(9.3, 5.6, 3.3) / (10.8, 21.8, 3.4)	(9.5, 5, 2.5) / (9.5, 20, 2.6)	(9.9, 5.0, 3.4) / (10.9, 20.1, 2.8)
源强Q/(mg.s^-1) :场景1、2	99 63/9 952	10 489/ 9651	9 873/9 893	10 047/9 712
泄漏发生时间T/s:场景2	14.1	15.5	14.3	15.2
溯源误差/%:场景1、2	24.4/27.0	35.2/37.2	23.0/24.1	13.7/19.1
稳定性:场景1、2	0.85/0.85	0.6/0.6	1/1	1/1