• Title/Summary/Keyword: Blast-Resistant Door

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Performance Evaluation on Blast-resistant of Gastight Door using Numerical Simulation (수치해석을 활용한 가스차단문의 폭발압력저항 성능평가)

  • Shin, Baegeun;Kim, Jiyu;Kim, Euisoo
    • Journal of the Korean Institute of Gas
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    • v.26 no.1
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    • pp.27-33
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    • 2022
  • As the scale of explosions diversifies along with the expansion of gas handling and storage facilities, studies on explosion-proof facilities in preparation for accidents is being actively conducted. The gastight door blocks the expansion pressure caused by blast waves or internal fires, and at the same time protects the personnel and equipment inside. For gastight doors, the regulations related to explosion-proof design are not clearly presented, and studies on the explosion pressure resistance performance evaluation of the facility are insufficient. In this study, the gastight door was modeled in a 3D shape with reference to the regulation ASTM regarding the gastight door standard. Afterwards, evaluation for blast-resistant performance of gastight door using Numerical simulation was evaluated by using ANSYS Explicit Dynamics to compare the deformation.

Analysis of Rebound Behavior of Blast-Resistant Door Subjected to Blast Pressure (폭압 작용에 의한 방폭문의 반발거동 해석)

  • Shin, Hyun-Seop
    • Journal of the Computational Structural Engineering Institute of Korea
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    • v.34 no.6
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    • pp.371-383
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    • 2021
  • Steel-concrete single-leaf blast-resistant doors, having steel box and slab inside, are installed on the wall using supporting members such as hinges and latches. Several studies have been conducted on their deflection behavior in the same direction as that of the blast pressure, but studies on their deflection behavior in the opposite direction, that is, studies on negative deflection behavior are relatively insufficient. In this study, we conducted a parameter analysis using finite element analysis on blast-resistant doors, on their rebound behavior in the negative deflection phase. Results revealed that the plastic deformation of the door, and the change in momentum and kinetic energy during rebound, were major factors influencing the rebound behavior. Greater rebound force was developed on the supporting members in the impulsive region, than in the quasi-static region; due to the characteristics in the impulsive region, where the kinetic energy developed relatively greater than the strain energy. In the design process, it is necessary to consider excessive deformation that could occur in the supporting members as the rebound behavior progresses. Additionally, it was found that in the case of steel-concrete blast doors, the rebound force increased relatively more, when the effects of both rebound and negative blast pressure contributed to the negative deflection of the door. Since conditions for the occurrence of this superposition effect could vary depending on structural characteristics and explosion conditions, further investigation may be required on this topic.

FE Analysis on the Structural Behavior of a Double-Leaf Blast-Resistant Door According to the Support Conditions (지지조건 변화에 따른 양개형 방폭문의 구조거동 유한요소해석)

  • Shin, Hyun-Seop;Kim, Sung-Wook;Moon, Jae-Heum;Kim, Won-Woo
    • Journal of the Computational Structural Engineering Institute of Korea
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    • v.33 no.5
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    • pp.339-349
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    • 2020
  • Double-leaf blast-resistant doors consisting of steel box and slab are application-specific structures installed at the entrances of protective facilities. In these structural systems, certain spacing is provided between the door and wall. However, variation in the boundary condition and structural behavior due to this spacing are not properly considered in the explosion analysis and design. In this study, the structural response and failure behavior based on two variables such as the spacing and blast pressure were analyzed using the finite element method. The results revealed that the two variables affected the overall structural behavior such as the maximum and permanent deflections. The degree of contact due to collision between the door and wall and the impact force applied to the door varied according to the spacing. Hence, the shear-failure behavior of the concrete slab was affected by this impact force. Doors with spacing of less than 10 mm were vulnerable to shear failure, and the case of approximately 15-mm spacing was more reasonable for increasing the flexural performance. For further study, tests and numerical research on the structural behavior are needed by considering other variables such as specifications of the structural members and details of the slab shear design.

FE Analysis on the Structural Behavior of the Single-Leaf Blast-Resistant Door According to Design Parameter Variation (설계변수에 따른 편개형 방폭문의 구조거동 유한요소해석)

  • Shin, Hyun-Seop;Kim, Won-Woo;Park, Gi-Joon;Lee, Nam-Kon;Moon, Jae-Heum;Kim, Sung-Wook
    • Journal of the Korea Academia-Industrial cooperation Society
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    • v.20 no.11
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    • pp.259-272
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    • 2019
  • Steel-concrete single-leaf blast-resistant doors are protective structures consisting of a steel box and reinforced concrete slab. By the domestic blast-resistant doors, the structure is not designed efficiently because few studies have examined the effects of variables, such as the blast pressure, rebar ratio, and steel plate thickness on the structural behavior. In this study, the structural behavior of the doors was analyzed using the FE method, and the support rotation and ductility ratio used to classify the structural performance were reviewed. The results showed that the deflection changes more significantly when the plate thickness increases than when the rebar spacing is a variable. This is because the strain energy absorbed by the door is reduced considerably when the plate thickness increases, and as a result, the maximum deflection becomes smaller. According to a comparison of the calculated values of the support rotation and the ductility ratio, the structural performance of the doors could be classified based on the support rotation of one degree and ductility ratio of three. On the other hand, more explosion tests and analytical studies will be needed to classify the damage level.