泡沫支撑无筋砖砌体墙体抗撞性建模及抗爆性能预测

IF 2.1 Q2 ENGINEERING, CIVIL
S. Anas, M. Shariq, Meraj Alam, M. Umair
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引用次数: 1

摘要

世界许多地方不断发生爆炸,危及人的生命,并严重影响基础设施和设施的健康。高度低于13米的低层建筑通常是由无加固砌体(URM)制成的承重结构,特别是在半城市地区、村庄和易受战争影响的边境地区。许多重要的建筑,包括在独立前和独立后建造的法院、纪念碑等,都是砖石承重结构。URM也用作非承重隔墙和复合/边界墙。这样的墙容易受到面外爆炸载荷的影响。在这样的荷载作用下,这些墙体无法存活,从而严重损坏或倒塌,危及整个结构的稳定性。砌体墙抗爆炸荷载的能力对建筑物及其使用者的安全至关重要,因为造成伤害和人员伤亡的原因通常不是爆炸,而是由砌体墙的脆性动态断裂和碎片、窗户玻璃破碎和其他被爆炸像导弹一样推进的次要物体造成的。一般来说,建筑物不是为爆炸荷载而设计的。为了建筑物使用者的安全,墙体必须承受如此短时间的高强度极端载荷,不仅不会发生灾难性的倒塌,而且不会产生可能对使用者造成严重伤害的致命碎片。为了保护URM壁免受高强度冲击波的影响,一种即用即用的护壁技术使用聚合物泡沫(例如聚氨酯)和金属,即;铝和钛,被认为是面墙暴露在爆炸压力下。本文介绍了在ABAQUS/Explicit软件中实现的一种数值技术,用于预测上述三种不同抗撞泡沫外加固URM墙体的整体抗爆性能。为此,考虑Badshah等人于2021年在4.34 kg和7.39 kg- tnt的化学爆炸载荷下,在2.19 m/kg1/3和1.83 m/kg1/3的比例距离下,采用粘土砖制成的两端各有一面横向支撑墙的支撑URM墙作为参考模型,并根据试验观测结果进行验证。利用ABAQUS内置的ConWep仿真程序对爆炸载荷进行建模,模拟自由场中墙-爆波相互作用。通过考虑应变率效应的本构律,将砌体材料非线性归因于砖、接缝砂浆和砖-砂浆界面。使用ABAQUS内置的可破碎泡沫塑性硬化模型对泡沫进行建模,考虑泡沫硬化和速率相关方案。结果表明,较高的杨氏模量和非弹性刚度有助于消散更多的爆炸能量,提高墙体抵抗野蛮爆炸的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modeling of crashworthy foam mounted braced unreinforced brick masonry wall and prediction of anti-blast performance
Explosions are continually occurring in many parts of the world endangering human lives and seriously affecting the health of infrastructures and facilities. Low-rise buildings having a height of fewer than 13 m are load-bearing structures generally made of unreinforced masonry (URM), particularly in semi-urban areas, villages, and war-prone border areas. Many structures of importance including buildings constructed in the pre- and post-independence era of courts, monuments, etc., are masonry load-bearing structures. URM is also used as non–load-bearing partition walls and compound/boundary walls. Such walls are susceptible to out-of-plane blast loading. Under such loadings, these walls fail to survive and thus either get severely damaged or collapsed, jeopardizing the stability of the entire structure. Resistance of masonry walls against blast loading is vital for the safety of the building and its users as injuries sustained and casualties are generally not caused due to explosion, but by the brittle dynamic fracture and fragments of masonry walls, window glass panes shattering, and other secondary objects propelled as missiles by the blasts. In general, buildings are not designed for blast loading. For the safety of the building users, it is imperative that the walls must withstand such short-duration high-magnitude extreme loadings without not only undergoing catastrophic collapse but also not producing deadly fragments which could cause grievous injuries to the users. To protect URM walls from high-intensity blast waves, an out-of-box wall protecting technique using foams of polymer (e.g., polyurethane) and metals namely; aluminum and titanium, is considered on the face of the wall exposed to the blast pressure. This study describes a numerical technique implemented in ABAQUS/Explicit software to predict the overall anti-blast performance of URM wall strengthened externally with the above three different crashworthy foams. For this purpose, a braced URM wall made of clay bricks, with two transverse bracing walls one at each end on the same side, tested experimentally by Badshah et al. in the year 2021 under the chemical explosive loads of 4.34 kg and 7.39 kg-TNT, respectively, at scaled distances 2.19 m/kg1/3 and 1.83 m/kg1/3 is considered as the reference model and is validated against the test observations. Explosion load is modeled with ABAQUS built-in ConWep simulation program to simulate the wall-explosion wave interactions in the free field. Material nonlinearities of the brickwork have been attributed to bricks, joint-mortar, and brick-mortar interfaces through constitutive laws considering strain-rate effects. The foams are modeled using ABAQUS’s inbuilt Crushable Foam Plasticity Hardening model considering foam hardening and rate-dependent schemes. Results show that the higher Young’s modulus and inelastic stiffness of the foams contribute to dissipating more explosion energy and improve the resistance of the walls from savage explosions.
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来源期刊
CiteScore
4.30
自引率
25.00%
发文量
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