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长安大学学报（自然科学版）[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2023年1期

Page:

62-71

Research Field:

隧道工程

Publishing date:

Info

Title:

Energy distribution and prediction of rock vibration generated in blasting excavation of a deep tunnel

Author(s):

TU Ying¹;  YAN Yu-song¹;  YANG Jian-hua¹;  ZHANG Wei-peng²;  LIU Da³

(1. School of Infrastructure Engineering, Nanchang University, Nanchang 330031, Jiangxi, China; 2. China Railway Water Conservancy & Hydropower Planning and Design Group Co., Ltd, Nanchang 330029, Jiangxi, China; 3. Jiangxi Academy of Water Science and Engineering, Nanchang 330029, Jiangxi, China)

Keywords:

tunnel engineering;  blasting excavation;  rock vibration;  wavelet packet;  energy distribution;  vibration prediction

PACS:

U455

DOI:

10.19721/j.cnki.1671-8879.2023.01.007

Abstract:

During blasting excavation of deep tunnels, the rapid in-situ stress release occurring on blast-created free surfaces was an important factor that produces vibration in surrounding rock masses. In order to understand the characteristics of the rock vibration caused by the combined effects of blast loading and rapid stress release, the rock vibration monitored in the blasting excavation of the upper middle pilot tunnel in Jinping Underground Laboratory was investigated. The monitored vibration signals were first separated into blasting vibration and stress release-induced vibration by using the variational mode decomposition(VMD)method. The wavelet packet method was then employed to study the energy distribution characteristics, and their influencing factors for the respective blasting vibration and stress release-induced vibration. A model was finally developed to predict the rock vibration caused by the combined effects of blast loading and rapid stress release. The results show that the energy of the blasting vibration is mainly distributed in the frequency band of 200 to 300 Hz. While the energy of the stress release-induced vibration is mainly concentrated in 0 to 150 Hz. The frequency of the stress release-induced vibration is significantly lower than that of the blasting vibration. As the travel distance increases, the ratio of the energy in lower frequencies to the total energy increases significantly, whether for the blasting vibration or the stress release-induced vibration. The energy distribution of the blasting vibration is also affected by the amount of charge filled in the blastholes. With an increase in the charge weight, the proportion of the low-frequency energy increases. However, the amount of charge has no effect on the energy distribution of the stress release-induced vibration. The energy distribution of the stress release-induced vibration is also independent of the level of the initial in-situ stress on the blast-created free surfaces, but is related to the duration of the stress release and the size of the free surfaces. A back propagation neural network based on the genetic algorithm(GA-BPNN)model is developed to predict the peak particle velocity(PPV), and center frequency of the rock vibration caused by the combined effects of blast loading and rapid stress release. In the GA-BPNN prediction model, seven physical quantities, including charge weight per delay, charge weight per blasthole, number of blastholes, blasthole spacing, blasting-to-monitoring distance, initial normal stress on the free surfaces and stress release duration, are considered as input parameters. The relative errors of the predicted PPV and center frequency are 10.4% and 3.2%, respectively.1 tab, 9 figs, 26 refs.

References:

[1] 谢和平,张 茹,任 利,等.川藏铁路深埋隧道围岩灾变分析与思考[J].工程科学与技术,2022,54(2):1-20.
XIE He-ping,ZHANG Ru,REN Li,et al.Analysis and thoughts on surrounding rock mass catastrophe of deep-buried tunnels along Sichuan-Tibet Railway[J].Advanced Engineering Sciences,2022,54(2):1-20.
[2]张新辉,付 平,尹健民,等.滇中引水工程香炉山隧洞地应力特征及其活动构造响应[J].岩土工程学报,2021,43(1):130-139.
ZHANG Xin-hui,FU Ping,YIN Jian-min,et al.In-situ stress characteristics and active tectonic response of Xianglushan Tunnel of Middle Yunnan Water Diversion Project[J].Chinese Journal of Geotechnical Engineering,2021,43(1):130-139.
[3]MURPHY M M,WESTMAN E C,IANNACCHION E A.Relationship between radiated seismic energy and explosive pressure for controlled methane and coal dust explosions in an underground mine[J].Tunnelling and Underground Space Technology,2012,28:278-286.
[4]李志文,李建春,洪胜男,等.考虑黏性效应的爆破震动区的理论分析[J].振动与冲击,2018,37(17):107-114.
LI Zhi-wen,LI Jian-chun,HONG Sheng-nan,et al.Theoretical analysis of blasting vibration zone considering viscous effect[J].Journal of Vibration and Shock,2018,37(17):107-114.
[5]陶铁军,汪旭光,池恩安,等.基于能量的爆破地震波衰减公式[J].工程爆破,2015,21(6):78-83.
TAO Tie-jun,WANG Xu-guang,CHI En-an,et al.Attenuation formula of blasting seismic wave based on energy theory[J].Engineering Blasting,2015,21(6):78-83.
[6]XIA X,YU C,LIU B,et al.Experimental study on the seismic efficiency of rock blasting and its influencing factors[J].Rock Mechanics and Rock Engineering,2018,51(8):2415-2425.
[7]RODRíGUEZ R,MARINA L G D,BASCOMPTA M,et al.Determination of the ground vibration attenuation law from a single blast:A particular case of trench blasting[J].Journal of Rock Mechanics and Geotechnical Engineering,2021,13(5):1182-1192.
[8]吕虎波,李 佳,彭亚雄,等.下穿高速公路输水隧洞爆破振动响应分析[J].爆破,2021,38(4):136-142.
LU Hu-bo,LI Jia,PENG Ya-xiong,et al.Study on blasting vibration of diversion tunnel undercrossing expressway[J].Blasting,2021,38(4):136-142.
[9]邓祥辉,陈建勋,罗彦斌,等.水平层状围岩隧道爆破控制技术[J].长安大学学报(自然科学版),2017,37(2):73-80,88.
DENG Xiang-hui,CHEN Jian-xun,LUO Yan-bin,et al.Blasting control technology of horizontal stratified rock tunnel[J].Journal of Chang’an University(Natural Science Edition),2017,37(2):73-80,88.
[10]唐 海,马谕杰,夏 祥,等.负高差地形爆破振动规律研究[J].工程爆破,2021,27(5):16-25.
TANG Hai,MA Yu-jie,XIA Xiang,et al.Study on blasting vibration law of negative height difference topographic[J].Engineering Blasting,2021,27(5):16-25.
[11]CHEN S H,WU J,ZHANG Z H.Blasting vibration characteristics and PPV calculation formula considering cylindrical charge length[J].Environmental Earth Sciences,2017,76(20):1-12.
[12]DUMAKOR-DUPEY N K,ARYA S,JHA A.Advances in blast-induced impact prediction-A review of machine learning applications[J].Minerals,2021,11(6):601.
[13]TOKS?Z M N,KEHRER H H.Tectonic strain release by underground nuclear explosions and its effect on seismic discrimination[J].Geophysical Journal International,1972,31(1/2/3):141-161.
[14]CARTER J P,BOOKER J R.Sudden excavation of a long circular tunnel in elastic ground[J].International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts,1990,27(2):129-132.
[15]卢文波,杨建华,陈 明,等.深埋隧洞岩体开挖瞬态卸荷机制及等效数值模拟[J].岩石力学与工程学报,2011,30(6):1089-1096.
LU Wen-bo,YANG Jian-hua,CHEN Ming,et al.Mechanism and equivalent numerical simulation of transient release of excavation load for deep tunnel[J].Chinese Journal of Rock Mechanics and Engineering,2011,30(6):1089-1096.
[16]CAO W Z,LI X,TAO M,et al.Vibrations induced by high initial stress release during underground excavations[J].Tunnelling and Underground Space Technology,2016,53:78-95.
[17]LI C J.Dynamic response of existing tunnel under cylindrical unloading wave[J].International Journal of Rock Mechanics and Mining Sciences,2020,131:104342.
[18]XU H,YANG X G,ZHANG J H,et al.A closed-form solution to spherical wave propagation in triaxial stress fields[J].International Journal of Rock Mechanics and Mining Sciences,2020,128:104266.
[19]TAO J,SHI A C,LI H T,et al.Thermal-mechanical modelling of rock response and damage evolution during excavation in prestressed geothermal deposits[J].International Journal of Rock Mechanics and Mining Sciences,2021,147:104913.
[20]严 鹏,卢文波,罗 忆,等.基于小波变换时-能密度分析的爆破开挖过程中地应力动态卸载振动到达时刻识别[J].岩石力学与工程学报,2009,28(增1):2836-2844.
YAN Peng,LU Wen-bo,LUO Yi,et al.Identification of arriving time of vibration induced by geostress dynamic unloading during blasting-excavation employing method of time-energy analysis based on wavelet transform[J].Chinese Journal of Rock Mechanics and Engineering,2009,28(S1):2836-2844.
[21]杨建华,章伟鹏,姚 池,等.基于变分模态分解的深埋洞室爆破开挖围岩振动特性分析[J].岩土力学,2021,42(12):3366-3375.
YANG Jian-hua,ZHANG Wei-peng,YAO Chi,et al.Characteristic analysis of rock vibrations caused by blasting excavation in deep cavern based on variational mode decomposition[J].Rock and Soil Mechanics,2021,42(12):3366-3375.
[22]卢文波,HUSTRULID W.质点峰值振动速度衰减公式的改进[J].工程爆破,2002,8(3):1-4.
LU Wen-bo,HUSTRULID W.An improvement to the equation for the attenuation of the peak particle velocity[J].Engineering Blasting,2002,8(3):1-4.
[23]范 勇,卢文波,杨建华,等.深埋洞室开挖瞬态卸荷诱发振动的衰减规律[J].岩土力学,2015,36(2):541-549.
FAN Yong,LU Wen-bo,YANG Jian-hua,et al.Attenuation law of vibration induced by transient unloading during excavation of deep caverns[J].Rock and Soil Mechanics,2015,36(2):541-549.
[24]YANG J H,LU W B,JIANG Q H,et al.A study on the vibration frequency of blasting excavation in highly stressed rock masses[J].Rock Mechanics and Rock Engineering,2016,49(7):2825-2843.
[25]YEN G G,LIN K C.Wavelet packet feature extraction for vibration monitoring[J].IEEE Transactions on Industrial Electronics,2000,47(3):650-667.
[26]郭钦鹏,杨仕教,朱忠华,等.运用GA-BP神经网络对爆破振动速度预测[J].爆破,2020,37(3):148-152.
GUO Qin-peng,YANG Shi-jiao,ZHU Zhong-hua,et al.Prediction of blasting vibration velocity using GA-BP neural network[J].Blasting,2020,37(3):148-152.

Memo

Memo:

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Common functions

Last Update: 2023-01-30