The Damage to Thick Steel Plates by Local Contact Explosions

He, Yanghua; Liu, Zhenyi; Li, Mingzhi; Li, Pengliang; Zhao, Yao; Liu, Qiqi; Liu, Chuang

doi:10.3390/ma16082966

Cited by 3 publications

(2 citation statements)

References 34 publications

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“…Other blast loading mitigation design improvements can be simulated in future studies to compare what methods are the most effective at reducing the failure of hyperloop infrastructure. Examples could include redesigning the hyperloop tube by adding composite isotropic shell configurations into the internal thin shell to improve its capacity to withstand pressure loading [14,[53][54][55][56][57][58][59][60]. As previously mentioned, modelling different blasts using the LOAD_BLAST_ENHANCED keyword, such as hemispherical or surface blasts, could be investigated to see how deformation varies.…”

Section: Discussionmentioning

confidence: 99%

Blast Effects on Hyperloop’s Cylindrical Thin-Shell Structures

Kaewunruen,

Roxburgh,

Remennikov

2023

Machines

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Super-high-speed guided systems such as hyperloops and MagLev are highly at risk of cyber and physical threats from either natural or man-made hazards. This study thus adopts a nonlinear finite element method to investigate and analyse blast responses of a spatial thin-shell structure formed as an essential part of the Hyperloop tunnelling system. The thin-shell structure is a longitudinal cylindrical tube used in hyperloop rail concepts that will have the capability to carry passenger pods travelling at speeds in excess of 1000 km/h. A robust parametric study has been carried out on a thin-shell metallic cylinder in accordance with experimental results to validate the blast simulation modelling approach. In addition, case studies have been conducted to simulate the effects of varied charge loading (TNT equivalent) of 10 kg, 15 kg and 20 kg. Since the hyperloop system is in its development stages, potential design modifications to adjust the thickness of the thin-shell cylinder are also simulated. Our findings demonstrate that thicker walls of 30 mm yield almost negligible dynamic displacements with lower blast pressures. However, this modification can cause serious ramifications in terms of infrastructure costs. On this ground, venting ports for blast mitigation have been proposed to alter and alleviate blast effects on the tube deformations. The novel insights reveal that increased venting port sizes can significantly increase the impulse deformations of the hyperloop tube but are key in reducing blast pressures within the asset infrastructure. These findings will inform hyperloop engineers about potential design solutions to ensure safety and reliability of future hyperloop rail travels amid the risks and uncertainties of cyber and physical threats.

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Section: Discussionmentioning

confidence: 99%

Blast Effects on Hyperloop’s Cylindrical Thin-Shell Structures

Kaewunruen,

Roxburgh,

Remennikov

2023

Machines

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“…Unlike traditional metal or concrete materials [4][5][6][7], the structurally weak materials represented by fibers have shown great promise for internal blast mitigation. The structurally weak materials can convert the blast energy into their own kinetic and internal energy and are almost completely converted into small soft particles after loading, which have virtually no secondary damage compared to rigid materials such as metals [8].…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation on Anti-Explosion Performance of Non-Metallic Annular Protective Structures

Bian,

Yang,

Wang

et al. 2023

Materials

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Explosive shock wave protection is an important issue that urgently needs to be solved in the current military and public security safety fields. Non-metallic protective structures have the characteristics of being lightweight and having low secondary damage, making them an important research object in the field of equivalent protection. In this paper, the numerical simulation was performed to investigate the dynamic mechanical response of non-metallic annular protective structures under the internal blast, which were made by the continuous winding of PE fibers. The impact of various charges, the number of fiber layers, and polyurethane foam on the damage to protective structures was analyzed. The numerical results showed that 120 PE fiber layers could protect 50 g TNT equivalent explosives. However, solely increasing the thickness of fiber layers cannot effectively enhance the protection efficiency. By adding polyurethane foam in the inner layer, the stress acting on the fiber could be effectively reduced. A 30 mm thick polyurethane layer can reduce the equivalent stress of the fiber layer by 41.6%. This paper can provide some reference for the numerical simulations of non-metallic explosion protection structures.

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Design and characterization of high-performance energetic hydrogels with enhanced mechanical and explosive properties

Liu,

Luo,

et al. 2024

Sci Rep

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Polymeric hydrogels, known for their excellent mechanical properties and pre-cross-linking flowability, provide a promising solution for recycling waste propellants, ensuring safety and maintaining explosive performance. This study developed a double cross-linked network energetic hydrogel that effectively combines mechanical strength with explosive capabilities. Using a Ford 4 Cup, temperature data logger, universal testing machine, and detonation performance tests, we examined the impacts of kinematic viscosity, cross-linking time, compressive strength, and explosive properties. The optimal kinematic viscosity for stabilizing hollow glass microspheres (GM) was found to be 129.7 mm 2 /s. Cross-linking time was negatively correlated with initiator, catalyst levels, and reaction temperature, but positively correlated with retarder content. Compressive strength increased with acrylamide (AM) content and showed an initial rise before decreasing with N,N′-methylenebisacrylamide (MBAA) content and reaction temperature. The maximum compressive strength was achieved with 5% MBAA (of AM mass fraction) at 40 °C. Detonation velocity and steel plate damage decreased with increasing AM content and initially increased then decreased with GM content. A balance of mechanical and explosive properties was achieved with 6% AM and 4% GM, resulting in a detonation velocity of 4536 m/s. This hydrogel shows significant potential for waste munitions management. Supplementary Information The online version contains supplementary material available at 10.1038/s41598-024-79737-w.

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The Damage to Thick Steel Plates by Local Contact Explosions

Cited by 3 publications

References 34 publications

Blast Effects on Hyperloop’s Cylindrical Thin-Shell Structures

Blast Effects on Hyperloop’s Cylindrical Thin-Shell Structures

Numerical Investigation on Anti-Explosion Performance of Non-Metallic Annular Protective Structures

Design and characterization of high-performance energetic hydrogels with enhanced mechanical and explosive properties

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