Pressure-impulse diagrams are commonly used in preliminary blast resistant design to assess the maxima of damage related parameter(s) in different types of structures as a function of pulse loading parameters. It is well established that plastic dynamic response of elastic-plastic structures is profoundly influenced by the temporal shape of applied pulse loading (Youngdahl, 1970, "Correlation Parameters for Eliminating the Effect of Pulse Shape on Dynamic Plastic Deformation," ASME, J. Appl. Mech., 37, pp. 744-752; Jones, Structural Impact (Cambridge University Press, Cambridge, England, 1989); Li, and Meng, 2002, "Pulse Loading Shape Effects on Pressure-Impulse Diagram of an Elastic-Plastic, Single-Degree-of-Freedom Structural Model," Int. J. Mech. Sci., 44(9), pp. 1985-1998). This paper studies pulse loading shape effects on the dynamic response of continuous beams. The beam is modeled as a single span with symmetrical semirigid support conditions. The rotational spring can assume different stiffness values ranging from 0 (simply supported) to oo (fully clamped). An analytical solution for evaluating displacement time histories of the semirigidly supported (continuous) beam subjected to pulse loads, which can be extendable to very high frequency pulses, is presented in this paper. With the maximum structural deflection, being generally the controlling criterion for damage, pressure-impulse diagrams for the continuous system are developed. This work presents a straightforward preliminary assessment tool for structures such as blast walls utilized on offshore platforms. For this type of structures with semirigid supports, simplifying the whole system as a single-degree-of-freedom (SDOF) discrete-parameter model and applying the procedure presented by Li and Meng (Li and Meng, 2002, "Pulse Loading Shape Effects on Pressure-Impulse Diagram of an Elastic-Plastic, Single-Degree-of-Freedom Structural Model," Int. J. Mech. Sci., 44(9), pp. 1985-1998; Li and Meng, 2002, "Pressure-Impulse Diagram for Blast Loads Based on Dimensional Analysis and Single-Degree-of-Freedom Model," J. Eng. Mech., 128(1), pp. 87-92) to eliminate pulse loading shape effects on pressure-impulse diagrams would be very conservative and cumbersome considering the support conditions. It is well known that an SDOF model is a very conservative simplification of a continuous system. Dimensionless parameters are introduced to develop a unique pulse-shape-independent pressure-impulse diagram for elastic and elastic-plastic responses of continuous beams.
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机译:压力冲击图通常用于初步抗爆设计中,以评估不同类型结构中与损伤相关的参数的最大值,作为脉冲加载参数的函数。公认的是,弹塑性结构的塑性动力响应会受到施加的脉冲载荷的时间形状的深刻影响(Youngdahl,1970,“消除脉冲形状对动态塑性变形影响的相关参数”,ASME,J.Appl Mech。,第37页,第744-752页; Jones,《结构碰撞》(剑桥大学出版社,英格兰,剑桥,1989年); Li和Meng,2002年,“脉冲加载形状对弹塑性压力-脉冲图的影响”。 ,“单度自由结构模型”,Int。J. Mech。Sci。,44(9),第1985-1998页。本文研究了脉冲载荷形状对连续梁动力响应的影响。该梁被建模为具有对称半刚性支撑条件的单个跨度。旋转弹簧可以采用从0(简单支撑)到oo(完全夹紧)的不同刚度值。本文提出了一种分析解决方案,用于评估承受脉冲载荷的半刚性(连续)梁的位移时间历史,该位移可以扩展到非常高频率的脉冲。以最大的结构挠度(通常是损坏的控制标准)为基础,开发了连续系统的压力脉冲图。这项工作为海上平台上的爆炸墙等结构提供了一种简单的初步评估工具。对于这种具有半刚性支撑的结构,将整个系统简化为一个单自由度(SDOF)离散参数模型,并应用Li和Meng(Li and Meng,2002,“脉冲加载形状效应弹性-单自由度结构模型的压力-脉冲图,“ Int。J. Mech。Sci。,44(9),pp。1985-1998; Li and Meng,2002,”压力-基于尺寸分析和单度模型的爆炸荷载脉冲图,“ J. Eng。Mech。,128(1),第87-92页),以消除压力荷载图上的脉冲荷载形状影响考虑到支持条件,这将是非常保守和麻烦的。众所周知,SDOF模型是对连续系统的非常保守的简化。引入无量纲参数以开发唯一的独立于脉冲形状的压力脉冲图,以用于连续梁的弹性和弹塑性响应。
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