Safe vibration velocity of directly buried pressure pipeline under blasting P wave

ZHU Bin; JIANG Nan; ZHOU Chuan-bo; JIA Yong-sheng; WU Ting-yao

doi:10.13374/j.issn2095-9389.2021.01.10.001

Volume 44 Issue 8

Aug. 2022

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Article Navigation > Chinese Journal of Engineering > 2022 > 44(8): 1444-1452

ZHU Bin, JIANG Nan, ZHOU Chuan-bo, JIA Yong-sheng, WU Ting-yao. Safe vibration velocity of directly buried pressure pipeline under blasting P wave[J]. Chinese Journal of Engineering, 2022, 44(8): 1444-1452. doi: 10.13374/j.issn2095-9389.2021.01.10.001

Citation:

ZHU Bin, JIANG Nan, ZHOU Chuan-bo, JIA Yong-sheng, WU Ting-yao. Safe vibration velocity of directly buried pressure pipeline under blasting P wave[J]. Chinese Journal of Engineering, 2022, 44(8): 1444-1452. doi: 10.13374/j.issn2095-9389.2021.01.10.001

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Safe vibration velocity of directly buried pressure pipeline under blasting P wave

doi: 10.13374/j.issn2095-9389.2021.01.10.001

ZHU Bin¹,
JIANG Nan^{1, 2
,
,},
ZHOU Chuan-bo¹,
JIA Yong-sheng^{2, 3},
WU Ting-yao¹

1.
Faculty of Engineering, China University of Geosciences, Wuhan 430074, China
2.
Hubei Key Laboratory of Blasting Engineering, Jianghan University, Wuhan 430024, China
3.
Wuhan Explosion & Blasting Co., Ltd, Wuhan 430023, China

More Information

Corresponding author: E-mail: jiangnan@cug.edu.cn
Received Date: 2021-01-10
Available Online: 2021-12-28
Publish Date: 2022-07-06

Abstract

Abstract

With the continuous development of urban underground space in China, safety problems between urban underground pipelines and underground engineering construction that are in active service are constantly emerging. As an important way of excavating engineering rock and soil mass, blasting has a particularly prominent impact on pressure pipelines due to its harmful seismic effect. It is of great significance to study the vibration damage effect of the pressure pipeline under the excavation blasting earthquake to guide the safety production of the adjacent pipeline blasting construction and the safety design of the pressure pipeline under the influence of adverse factors such as blasting vibration. Based on the above research requirements, the stress characteristics of a thin-walled pipe with uniform internal pressure under an incident P-wave caused by blasting are first analyzed. The stress analytical calculation model under the seismic wave of pressure pipeline blasting is then established by quasi-static analysis and superposition principle. Based on the yield characteristics of pressure pipeline materials and the Tresca yield theory, a safety criterion calculation model for the vibration velocity of pressure pipeline under P-wave blasting is established. Combined with two engineering cases of a directly buried pressure thin-walled pipeline under explosion, the calculation model is verified. Results show that before the application of blasting load, the pipeline is only subjected to uniform internal pressure with initial axial and tangential stresses. After blasting, the pipeline is subjected to both internal pressure and blasting seismic P-wave load. Results reveal that the peak stress of the pipeline decreases with the increase of the incident angle. Moreover, the tensile failure mainly occurs at normal incidence, and the tangential failure mainly occurs at the total reflection. The vibration velocity of the safety control of the pressure pipeline increases with the increase of the incident angle. In the actual project, according to the actual situation of the internal pressure of the pipeline, the smaller value is selected as the safety control value.
- buried pipeline,
- uniform internal pressure,
- blasting P wave,
- blasting dynamic stress,
- safe vibration velocity

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References(27)

References

[1]	張黎明, 趙明生, 池恩安, 等. 爆破振動對地下管道影響試驗及風險預測. 振動與沖擊, 2017, 36(16):241 Zhang L M, Zhao M S, Chi E A, et al. Experiments for effect of blasting vibration on underground pipeline and risk prediction. J Vib Shock, 2017, 36(16): 241
[2]	管曉明, 張良, 王利民, 等. 隧道近距下穿管線的爆破振動特征及安全標準. 中南大學學報(自然科學版), 2019, 50(11):2870 doi: 10.11817/j.issn.1672-7207.2019.11.026 Guan X M, Zhang L, Wang L M, et al. Blasting vibration characteristics and safety standard of pipeline passed down by tunnel in short distance. J Central South Univ Sci Technol, 2019, 50(11): 2870 doi: 10.11817/j.issn.1672-7207.2019.11.026
[3]	鄭爽英, 楊立中. 下穿隧道爆破地震作用下埋地輸氣管道的動力響應規律研究. 爆破, 2015, 32(4):69 doi: 10.3963/j.issn.1001-487X.2015.04.014 Zheng S Y, Yang L Z. Dynamic response law of buried gas pipeline caused by blasting seismic waves of undercrossing tunneling. Blasting, 2015, 32(4): 69 doi: 10.3963/j.issn.1001-487X.2015.04.014
[4]	夏宇磬, 蔣楠, 姚穎康, 等. 粉質黏土層預埋承插式混凝土管道對爆破振動的動力響應. 爆炸與沖擊, 2020, 40(4):73 Xia Y Q, Jiang N, Yao Y K, et al. Dynamic responses of a concrete pipeline with bell-and-spigot joints buried in a silty clay layer to blasting seismic waves. Explos Shock Waves, 2020, 40(4): 73
[5]	朱斌, 蔣楠, 賈永勝, 等. 下穿燃氣管道爆破振動效應現場試驗研究. 巖石力學與工程學報, 2019, 38(12):2582 Zhu B, Jiang N, Jia Y S, et al. Field experiment on blasting vibration effect of underpass gas pipelines. Chin J Rock Mech Eng, 2019, 38(12): 2582
[6]	張黎明, 趙昌龍, 池恩安, 等. 地下管道爆破振動安全允許峰值振速試驗研究. 爆破, 2019, 36(4):146 Zhang L M, Zhao C L, Chi E A, et al. Experimental investigation on allowed blasting vibration velocity of underground pipeline. Blasting, 2019, 36(4): 146
[7]	鐘冬望, 龔相超, 涂圣武, 等. 高飽和黏土中爆炸波作用下直埋聚乙烯管的動力響應. 爆炸與沖擊, 2019, 39(3):51 Zhong D W, Gong X C, Tu S W, et al. Dynamic responses of PE pipes directly buried in high saturated clay to blast wave. Explos Shock Waves, 2019, 39(3): 51
[8]	龔相超, 鐘冬望, 司劍峰, 等. 高飽和黏性土中爆炸波作用下直埋鋼管(空管)動態響應. 爆炸與沖擊, 2020, 40(2):13 Gong X C, Zhong D W, Si J F, et al. Dynamic responses of hollow steel pipes directly buried in high-saturated clay to blast waves. Explos Shock Waves, 2020, 40(2): 13
[9]	Mokhtari M, Alavi Nia A. A parametric study on the mechanical performance of buried X65 steel pipelines under subsurface detonation. Arch Civ Mech Eng, 2015, 15(3): 668 doi: 10.1016/j.acme.2014.12.013
[10]	Mokhtari M, Alavi Nia A. The application of CFRP to strengthen buried steel pipelines against subsurface explosion. Soil Dyn Earthq Eng, 2016, 87: 52 doi: 10.1016/j.soildyn.2016.04.009
[11]	劉優平, 喬蘭, 徐斌. P波作用下飽和土中輸流管道動力響應. 巖土力學, 2013, 34(11):3151 Liu Y P, Qiao L, Xu B. Dynamic response of liquid-filled pipe embedded in saturated soil due to P waves. Rock Soil Mech, 2013, 34(11): 3151
[12]	王鐵成, 王卉. P波作用下地下輸流管道的動力響應分析. 天津大學學報, 2010, 43(4):349 Wang T C, Wang H. Dynamic analysis of underground liquid-filled pipe impacted by P waves. J Tianjin Univ, 2010, 43(4): 349
[13]	Ghaznavi A, Oskouei A V. The effect of three-dimensional earthquake P-wave propagational speed on buried continues straight steel pipelines. Eng J, 2017, 21(4): 39 doi: 10.4186/ej.2017.21.4.39
[14]	何兆洋, 劉海瀟, 何利民, 等. 管道內氣液兩相流流激力研究進展. 工程科學學報, 2021, 43(1):129 He Z Y, Liu H X, He L M, et al. Research progress of fluctuating force caused by internal gas-liquid flow. Chin J Eng, 2021, 43(1): 129
[15]	高啟棟, 盧文波, 楊招偉, 等. 垂直孔爆破誘發地震波的成分構成及演化規律. 巖石力學與工程學報, 2019, 38(1):18 Gao Q D, Lu W B, Yang Z W, et al. Components and evolution laws of seismic waves induced by vertical-hole blasting. Chin J Rock Mech Eng, 2019, 38(1): 18
[16]	Li J C, Ma G W, Zhou Y X. Analytical study of underground explosion-induced ground motion. Rock Mech Rock Eng, 2012, 45(6): 1037 doi: 10.1007/s00603-011-0200-3
[17]	周俊汝, 盧文波, 張樂, 等. 爆破地震波傳播過程的振動頻率衰減規律研究. 巖石力學與工程學報, 2014, 33(11):2171 Zhou J R, Lu W B, Zhang L, et al. Attenuation of vibration frequency during propagation of blasting seismic wave. Chin J Rock Mech Eng, 2014, 33(11): 2171
[18]	陳明, 盧文波. 爆炸應力波對新澆混凝土襯砌的影響研究. 巖土力學, 2008, 29(2):455 doi: 10.3969/j.issn.1000-7598.2008.02.031 Chen M, Lu W B. The influence of explosive stress wave on young concrete lining. Rock Soil Mech, 2008, 29(2): 455 doi: 10.3969/j.issn.1000-7598.2008.02.031
[19]	劉小寧, 劉岑, 劉兵, 等. 承壓容器爆破壓力計算公式的評價方法研究. 機械強度, 2017, 39(6):1409 Liu X N, Liu C, Liu B, et al. Study on the evaluation method of the pressure vessel burst pressure calculation formula. J Mech Strength, 2017, 39(6): 1409
[20]	李洪濤, 盧文波, 舒大強, 等. P波作用下襯砌混凝土的爆破安全振動速度研究. 爆炸與沖擊, 2007, 27(1):34 doi: 10.3321/j.issn:1001-1455.2007.01.006 Li H T, Lu W B, Shu D Q, et al. Study on the safety velocity for concrete lining under P wave loading. Explos Shock Waves, 2007, 27(1): 34 doi: 10.3321/j.issn:1001-1455.2007.01.006
[21]	胡守云, 周傳波, 蔣楠, 等. P波作用下機場跑道的爆破安全振動速度研究. 華南理工大學學報(自然科學版), 2018, 46(4):129 Hu S Y, Zhou C B, Jiang N, et al. Study on safety blasting vibration velocity for concrete airport runway subjected to P-waves. J South China Univ Technol Nat Sci, 2018, 46(4): 129
[22]	Zhang J, Zhang H, Zhang L, et al. Buckling response analysis of buried steel pipe under multiple explosive loadings. J Pipeline Syst Eng Pract, 2020, 11(2): 04020010 doi: 10.1061/(ASCE)PS.1949-1204.0000431
[23]	孔令超. 壓力容器用球墨鑄鐵的性能研究. 鑄造技術, 2015, 36(12):2855 Kong L C. Study on properties of nodular cast iron used for pressure vessel. Foundry Technol, 2015, 36(12): 2855
[24]	中華人民共和國建設部. GB 50251—2015 輸氣管道工程設計規范. 北京: 建筑工業出版社, 2015 Ministry of Construction of the People's Republic of China. GB20251—2015 Code for design of gas transmission pipeline engineering. Beijing: China Industrial Press, 2015
[25]	王海濤, 金慧, 賈金青, 等. 地鐵隧道鉆爆法施工對鄰近埋地管道影響的模型試驗研究. 巖石力學與工程學報, 2018, 37(增刊1): 3332 Wang H T, Jin H, Jia J Q, et al. Model test study on the influence of subway tunnel drilling and blasting method on adjacent buried pipeline. Chin J Rock Mech Eng, 2018, 37(Suppl 1): 3332
[26]	中華人民共和國建設部. GB 50028—2006 城鎮燃氣設計規范. 北京: 中國建筑工業出版社, 2006 Ministry of Construction of the People’s Republic of China. GB50028—2006 Urban Gas Design Code. Beijing: China Industrial Press, 2006
[27]	中華人民共和國國家質量監督檢驗檢疫總局. GB 6722—2014爆破安全規程. 北京: 中國標準出版社, 2015 General Administration of Quality Supervision. GB 6722—2014 Blasting Safety Code. Beijing: Standards Press of China, 2015