Experimental and Numerical Investigation of Internal Explosion in an Earth-Covered Magazine

Xu, Guangan; Qiu, Yanyu; Xing, Huadao; Li, Xiaodong; Chen, Gong

doi:10.3390/buildings12111872

Cited by 3 publications

(2 citation statements)

References 16 publications

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“…Liu et al [8] and Li et al [9] analyzed the factors infuencing the safety distance of earth-covered magazine, emphasizing the mitigating efect of soil on shock wave overpressure and its efcacy in blocking structural debris pathways. Furthermore, Xu et al [10,11] conducted scaled tests on earth-covered magazines to investigate overpressure and debris distribution in various directions. Tese fndings were integrated with numerical simulations to estimate the distance that concrete fragments would project.…”

Section: Introductionmentioning

confidence: 99%

Study on the Earth-Covered Magazine Models under the Internal Explosion

Gong,

Qiu,

Long

et al. 2024

Shock and Vibration

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The use of earth-covered magazines (ECMs) is increasingly prevalent in protective engineering due to their concealment and cost-effectiveness. To explore the optimal thickness of earth covering for ECMs, scaled model tests were conducted under explosive charges equivalent to 30 kilograms of TNT. The resulting overpressure outside the model in the 180° direction was measured. Subsequently, computational analyses were conducted employing LS-DYNA software to examine these experimental findings. The findings indicate that increasing the thickness of the rear soil can mitigate peak overpressure, delay the air shock wave’s arrival time, and reduce the impulse of the positive phase. The numerical calculations closely align with experimental data, with peak overpressure deviation remaining under 10%. The shock wave initially impacts the top of the model before reaching the rear, with soil scattering more pronounced in the 90° direction compared to the 180° direction. Furthermore, an analysis of soil energy absorption rate variation was conducted based on energy conservation principles. These results provide valuable insights for optimizing the design and construction of ECMs.

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Section: Introductionmentioning

confidence: 99%

Study on the Earth-Covered Magazine Models under the Internal Explosion

Gong,

Qiu,

Long

et al. 2024

Shock and Vibration

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“…Material parameters such as air and explosives are widely used in the simulation, while different material models are selected when simulating concrete materials. CSC (Continuous Surface Cap) [10], HJC (Johnson-Holmquist Concrete) [16], K&C (Karagozian and Case Concrete) [17], and the RHT model are widely used in the simulation of reinforced concrete explosion damage. The RHT material model [18] was first proposed in 1999 and applied well to the response of concrete under explosive loads [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Damage Zone of the Reinforced Concrete Beam under Rectangular Explosive Contact Explosions

et al. 2023

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This paper investigates the damaged area of a reinforced concrete beam under rectangular explosive contact explosion, through full-scale beam tests and numerical simulation. The calculation equation of beam surface load distribution based on equivalent impulse is established, with a consideration of the effect of the length and height of rectangular explosive on the load distribution, and the calculation equation of beam damage area is further proposed. Through changing the mass of the rectangular TNT explosive (1~6 kg) and the shape of the 1 kg rectangular explosive, 5 cases of the test were carried out on a full-scale reinforced concrete beam. The damaged area of the beam is divided into three parts: blasting crater, damage span of the front face, and damage span of the bottom face. The RHT (Riedel–Hiermaier–Thoma) material model is used to simulate concrete for numerical simulation. Curve fitting was performed based on the numerical simulation results. With the prediction of the load distribution on the beam surface, the size of the surface crushing area and the span of the damaged area are calculated; the section resistance function of the beam is introduced to calculate the depth of the blasting crater; and the correlation curve between the damaged span of the front face, the depth of the blasting crater, and the mass of the block TNT is established. The local damage to the beam under the contact explosion load can be evaluated more accurately when the mass of the rectangular TNT is 1~6 kg.

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