装药形状对爆炸压力的影响分析

H. Draganić, S. Lukić, I. Radić, Goran Gazić, M. Jeleč
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引用次数: 0

摘要

爆炸波强度取决于几个参数,即:炸药种类、装药重量、形状和方向、爆震点位置、起爆剂类型(初爆类型)、爆炸药相对于预定目标的位置(距离)和地面。环境条件,特别是空气温度、湿度和大气压力,也会影响爆破压力。如果综合考虑这些参数,很难准确预测爆炸冲击波对目标结构的作用。本文主要研究了装药形状对爆炸压力测量的影响。球形和半球形装药通常被认为是球形和半球形装药形状,因此,对于爆炸冲击波压力的近似,有准确和可靠的解析表达式。球形装药爆炸波的形式和传播被认为已经被彻底研究和了解。在今天的城市战争和游击战中,行动速度是一个至关重要的因素。绘制爆炸装药的精细形状既耗时又不必要,因此需要研究除球形外的不同装药形状。这项研究包括对不同形状装药起爆引起的入射压力(自由场)和反射压力的现场范围实验测量。考虑的形状有:球形、圆柱形和矩形。利用ANSYS Autodyn hydrocode软件对实验进行了数值验证和验证。数值模拟采用耦合欧拉-拉格朗日平面解算器,采用理想空气环境和PEP500炸药。根据实验大纲,电荷形状变化,测量点是恒定的,以便对测量数据进行比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
ANALYSIS OF CHARGE SHAPE INFLUENCE ON BLAST PRESSURE
Blast wave intensity depends on several parameters, namely: explosive material type, charge weight, shape and orientation, detonation point position, detonation initiator type (primary explosive type), the position (distance) of the explosive charge in relation to the intended target (standoff distance) and ground surface. Environmental conditions, particularly air temperature, humidity and atmospheric pressure, also influence blast pressures. It is difficult to accurately predict the blast wave action on target structures if all of these parameters are considered. This research concentrates on the influence of the shape of the explosive charge on blast pressure measurements. Spherical and hemispherical charge shapes are considered usual and, as such, accurate and reliable analytical expressions for the blast wave pressure approximation are available. The form and propagation of spherical charge blast waves are considered to have been thoroughly studied and known. In today’s urban and guerrilla warfare, speed of action is a crucial factor. Rendering the careful shaping of explosive charges is time consuming and unnecessary, hence the need for investigating different charge shapes, other than spherical. This investigation consisted of field range experimental measurements of the incident (free-field) and reflected pressures caused by detonating differently shaped charges. The shapes considered were: spherical, cylindrical and rectangular. The experiments were numerically validated and verified using ANSYS Autodyn hydrocode software. Numerical simulations utilised a coupled Euler–Lagrange planar solver, using an ideal air environment and PEP500 explosive material. Charge shapes varied, according to the experimental outline, and the measuring points were constant, to allow comparison of the measured data.
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