https://orcid.org/0009-0005-4605-6194
Abstract
Vacuum explosive welding technology has better performance, lower production cost, more environmentally friendly and other advantages. In order to meet the industrial demand for production in the area of metal composite plate, it is urgent to develop a super-large vacuum explosion containment vessel which can be used for explosive welding. Since soil is generally regarded as an effective energy-absorbing material, covering a certain thickness of soil above the steel plate can tremendously dissipate the energy of shock waves. Therefore, the dynamic response of the soil/steel composite structure on the explosion containment vessel under different explosive quantities and vacuum degrees was analyzed by experiments and numerical simulations. The dynamic strain curve collected by the experiment consists of an abruptly rising phase and a gradually decreasing vibration recovery phase. Comparing the peak strains, it was found that near-vacuum environment can significantly weaken the dynamic strain of soil/steel composite structures. Comparing the variation of the vibration amplitude of the composite structure with the cycles, it was found that reducing the amount of explosive and the vacuum degree inside the explosion containment vessel can effectively weaken the peak strain of the cover, and can also reduce the vibration amplitude of the composite structure. The dynamic response of soil/steel composite structure can be analyzed in four phases: Abrupt Increasing, Followed Impulse, Inertia Hysteresis, Static Pressure Stabilization.
Issue Section:
Fluid-Structure Interaction
References
1.
Niu
, A. H.
, 2018
, “Research and Practice of Vacuum Explosion Welding for Metal Cladding Product
,” Eng. Blasting
, 24
(4
), pp. 67
–70
.2.
Brode
, H. L.
, 1955
, “Numerical Solutions of Spherical Blast Waves
,” J. Appl. Phys.
, 26
(6
), pp. 766
–775
.10.1063/1.17220853.
Baker
, W. E.
, 1960
, “The Elastic-Plastic Response of Thin Spherical Shells to Internal Blast Loading
,” ASME J. Appl. Mech.
, 27
(1
), pp. 139
–144
.10.1115/1.36438884.
Baker
, W. E.
, Hu
, W. C. L.
, and Jackson
, T. R.
, 1966
, “Elastic Response of Thin Spherical Shells to Axisymmetric Blast Loading
,” ASME J. Appl. Mech.
, 33
(4
), pp. 800
–806
.10.1115/1.36251855.
White
, I. J. J.
, Trott
, B. D.
, and Backofen
, J. J. E.
, 1977
, “The Physics of Explosion Containment
,” Phys. Technol.
, 8
(3
), pp. 94
–100
.10.1088/0305-4624/8/3/I016.
White
, I. J. J.
, and Trott
, B. D.
, 1980
, “Scaling Law for the Elastic Response of Spherical Explosion-Containment Vessels
,” Exp. Mech.
, 20
(5
), pp. 174
–177
.10.1007/BF023271227.
Karpp
, R. R.
, Duffey
, T. A.
, and Neal
, T. R.
, 1983
, “Response of Containment Vessels to Explosive Blast Loading
,” ASME J. Pressure Vessel Technol.
, 105
(1
), pp. 23
–27
.10.1115/1.32642348.
Isaiah
, R.
, Young
, H. P.
, and Jordan
, U. S.
, 2019
, “Analytical and Numerical Studies of a Thick Anisotropic Multilayered Fiber-Reinforced Composite Pressure Vessel
,” ASME J. Pressure Vessel Technol.
, 141
(1
), p. 011203
.10.1115/1.40418879.
Liu
, Z.
, Li
, X.
, Wang
, Y.
, Yan
, H.
, and Zhou
, D.
, 2024
, “Shock Response of Water-Protected Spherical Explosion Containment Vessels
,” ASME J. Pressure Vessel Technol.
, 146
(5
), p. 051702
.10.1115/1.406589410.
Duan
, Z. P.
, 1994
, “The Experimental Study and Numerical Simulating of Explosion Containment Chamber
,” China Saf. Sci. J.
, 3
(1
), pp. 1
–7
.11.
Dong
, Q.
, Hu
, B. Y.
, Chen
, S. Y.
, and Gu
, Y.
, 2012
, “Engineering Design of a Multiple-Use Spherical Explosion Containment Vessel Subjected to Internal Blast Loading From 25 kg TNT High Explosive
,” ASME J. Pressure Vessel Technol.
, 134
(2
), p. 021205
.10.1115/1.400539712.
Dong
, Q.
, and Hu
, B. Y.
, 2016
, “Dynamic Behavior of Carbon Fiber Explosion Containment Vessels
,” ASME J. Pressure Vessel Technol.
, 138
(1
), p. 011202
.10.1115/1.403043513.
Zhu
, W. H.
, 1997
, “Combining Analytical Method With Numerical Simulation to Obtain Blast Load on Chamber Wall Produced by an Explosive Charge
,” J. Natl. Univ. Defense Technol.
, 19
(6
), pp. 102
–106
.14.
Zhu
, W. H.
, Xue
, H. L.
, Zhou
, G. Q.
, and Schleyer, G. K., 1997
, “Dynamic Response of Cylindrical Explosive Chambers to Internal Blast Loading Produced by a Concentrated Charge
,” Int. J. Impact Eng.
, 19
(9
), pp. 831
–845
.10.1016/S0734-743X(97)00022-515.
Dong
, Q.
, Li
, Q. M.
, and Zheng
, J. Y.
, 2010
, “Further Study on Strain Growth in Spherical Containment Vessels Subjected to Internal Blast Loading
,” Int. J. Impact Eng.
, 37
(2
), pp. 196
–206
.10.1016/j.ijimpeng.2009.09.00116.
Dong
, Q.
, Li
, Q. M.
, Zheng
, J. Y.
, and Hu
, B. Y.
, 2010
, “Effects of Structural Perturbations on Strain Growth in Containment Vessels
,” ASME J. Pressure Vessel Technol.
, 132
(1
), p. 011203
.10.1115/1.400037217.
Dong
, Q.
, Li
, Q. M.
, and Zheng
, J. Y.
, 2010
, “Interactive Mechanisms Between the Internal Blast Loading and the Dynamic Elastic Response of Spherical Containment Vessels
,” Int. J. Impact Eng.
, 37
(4
), pp. 349
–358
.10.1016/j.ijimpeng.2009.10.00418.
Liu
, W.
, Zhang
, Q.
, Zhong
, F.
, Cheng
, S.
, Zhang
, D.
, and Yang
, L.
, 2017
, “Further Research on Mechanism of Strain Growth Caused by Superposition of Different Vibration Modes
,” Int. J. Impact Eng.
, 104
, pp. 1
–12
.10.1016/j.ijimpeng.2017.01.02519.
Kubota
, S.
, Saburi
, T.
, Katoh
, K.
, Homae
, T.
, Ogata
, Y.
, and Iida
, M.
, 2010
, “Development of Compact Blast Containment Vessel for 10 kg Explosive
,” Mater. Sci. Forum
, 638-642
, pp. 1047
–1052
.10.4028/www.scientific.net/MSF.638-642.104720.
Sui
, Y. G.
, Zhang
, D. Z.
, Tang
, S. Y.
, Li
, J.
, and Lin
, Q.
, 2015
, “Theoretical Analysis of a Reactive Reinforcement Method for Cylindrical Explosion-Containment Vessels
,” ASME J. Pressure Vessel Technol.
, 137
(1
), p. 011206
.10.1115/1.402745021.
Trabia
, M. B.
, O’Toole
, B. J.
, Thota
, J.
, and Matta
, K. K.
, 2008
, “Finite Element Modeling of a Lightweight Composite Blast Containment Vessel
,” ASME J. Pressure Vessel Technol.
, 130
(1
), p. 011205
.10.1115/1.282643722.
Liu
, Z.
, Li
, X.
, Zhou
, D.
, Wang
, X.
, and Yan
, H.
, 2024
, “Influence of Water Cover on the Blast Resistance of Circular Plates
,” ASME J. Pressure Vessel Technol.
, 146
(6
), p. 061402
.10.1115/1.406680723.
Li
, X. J.
, Qin
, X. Y.
, Yan
, H. H.
, 2010
, “Base Constraint Forms of Hemispherical Shock-Waves Trap Structures
,” Explos. Shock Waves
, 30
(1
), pp. 7
–11
.https://www.researchgate.net/publication/297299718_Base_constraint_forms_of_hemispherical_shock-waves_trap_structures24.
Wang
, Q.
, Lin
, C. J.
, Li
, Z. M.
, Lu, J. W., and Li, R., 2021
, “Vibration and Noise Characteristics of a Cylinder Body Caused by the Explosion in an Explosion Tank Under Negative Pressure
,” J. Vib. Shock
, 40
(6
), pp. 135
–139
.https://jvs.sjtu.edu.cn/EN/Y2021/V40/I6/13525.
Silnikov
, M. V.
, Chernyshov
, M. V.
, and Mikhaylin
, A. I.
, 2015
, “Blast Wave Parameters at Diminished Ambient Pressure
,” Acta Astronaut.
, 109
, pp. 235
–240
.10.1016/j.actaastro.2014.12.00726.
Veldman
, R. L.
, Nansteel
, M. W.
, Chen
, C. C.-T.
, and Toner
, B. A.
, 2017
, “The Effect of Ambient Pressure on Blast Reflected Impulse and Overpressure
,” Exp. Tech.
, 41
(3
), pp. 227
–236
.10.1007/s40799-017-0171-827.
Zhang
, G. H.
, Li
, B. B.
, Shen
, F.
, Wang, S. Q., and Wang, H., 2020
, “Experimental Research on the Explosion Performance of Explosives Under Vacuum Conditions
,” Chin. J. Explos. Propellants
, 43
(3
), pp. 308
–313
.28.
Li
, K. B.
, Li
, X. J.
, Yan
, H. H.
, Wang, X. H., and Yang, C. C., 2018
, “Numerical Simulation for Near-Field Characteristics of Air Explosion Under Different Degrees of Vacuum
,” J. Vib. Shock
, 37
(17
), pp. 270
–276
.10.13465/j.cnki.jvs.2018.17.03829.
Li
, Z. M.
, Wang
, X. G.
, Wang
, Q.
, Lu, J. W., and Lin, C. J., 2021
, “Experimental Study on the Effect of Negative Pressure Environment on Explosion Shock Wave
,” Chin. J. Explos. Propellants
, 44
(1
), pp. 35
–40
.10.14077/j.issn.1007-7812.20200702530.
Zhou
, D.
, Li
, X.
, Wang
, Y.
, Wang
, J.
, Yan
, H.
, and Wang
, X.
, 2023
, “Research on Evolution of Shock Wave of Ground Explosion in Pit Type Explosion Containment Vessel
,” Structures
, 50
, pp. 1164
–1172
.10.1016/j.istruc.2023.02.08231.
Gan
, L.
, Zong
, Z.
, Gao
, C.
, Li
, M.
, and Qian
, H.
, 2022
, “Influence of Shape of Cuboid Explosives on Response of Plates Subjected to Blast Loads
,” Thin-Walled Struct.
, 174
, p. 109077
.10.1016/j.tws.2022.10907732.
Cheng
, S.
, Li
, X.
, Wang
, Y.
, Zhou
, D.
, Yan
, H.
, and Wang
, Q.
, 2021
, “Analysis of Explosion Load in a Cylindrical Container With Sand Bottom
,” ASME J. Pressure Vessel Technol.
, 143
(3
), p. 031401
.10.1115/1.404841733.
Xiang
, D. L.
, Rong
, J. L.
, and Li
, J.
, 2014
, “Effect of Al/O Ratio on the Detonation Performance and Under Water Explosion of HMX-Based Aluminized Explosives
,” Propellants, Explos., Pyrotech.
, 39
(1
), pp. 65
–73
.10.1002/prep.20130002634.
Lin
, L.
, Zhi
, X. D.
, Fan, F., Meng, S. J., and Su, J. J., 2014
, “Determination of Parameters of Johnson-Cook of Q235B Steel
,” J. Vib. Shock
, 33
(9
), pp. 153
–158
.10.13465/j.cnki.jvs.2014.09.02835.
Zhou
, D.
, Li
, X.
, Wang
, Y.
, Wang
, J.
, Yan
, H.
, and Wang
, X.
, 2023
, “Research on the Influence of Vacuum Degree on the Shock Wave in Pit Type Explosion Containment Vessel
,” Structures
, 56
, p. 105033
.10.1016/j.istruc.2023.10503336.
Tang
, C.
, and Hui
, H. H.
, 2013
, “Gaussian Curve Fitting Solution Based on Matlab
,” Comput. Digital Eng.
, 41
(8
), pp. 1262
–1263
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