非理想气体和惰性小固体颗粒混合物中冲击波后非定常绝热流动的解析解

IF 0.8 4区 综合性期刊 Q3 MULTIDISCIPLINARY SCIENCES
G. Nath
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引用次数: 0

摘要

本文用摄动法分析了真实气体和惰性固体颗粒混合物中强圆柱或球形爆炸(激波)的自相似解。利用Sakurai的摄动方法,导出了一阶近似的解析形式的相似解,并导出了一组二阶近似的ODE。物理变量在冲击波后整个流场的分布如图所示。研究了固体惰性颗粒密度与初始气体密度之比、颗粒质量浓度、实气体效应参数对物理变量、冲击波峰值压力和冲击波损伤半径的影响。研究发现,随着固体颗粒的质量浓度或混合物中气体的非理想性的增加,爆炸冲击波的峰值压力和爆炸冲击波的破坏半径都减小。圆柱几何和球面几何也作了比较。研究发现,在球形几何条件下,冲击波的影响比圆柱几何条件下更大。爆炸波衰减是由于固体颗粒质量浓度或气体非理想性参数的增加引起的,其强度随固体颗粒与初始气体密度之比的增加而增加。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Analytical Solution for Unsteady Adiabatic Flow Behind the Blast Wave in a Non-ideal Gas and Small Inert Solid Particles Mixture

Analytical Solution for Unsteady Adiabatic Flow Behind the Blast Wave in a Non-ideal Gas and Small Inert Solid Particles Mixture

In this paper, the self-similar solutions for a strong cylindrical or spherical blast (shock) wave in real gas and inert solid particles mixture are analyzed on the basis of the perturbation method. The similarity solution in analytical forms is derived for first-order approximation, and a set of ODE for second-order approximations is also derived using the perturbation method proposed by Sakurai in perfect gas. The physical variable’s distribution in the entire flow field after the blast wave is shown in the figures. The effects of the ratio of the density of the solid inert particles to the initial gas density, mass concentration of particles, and the parameter of real gas effect on the physical variables, the peak pressure on blast wave and the damage radius of blast wave are investigated. It is found that the peak pressure on the blast wave and the damage radius of the blast wave both decrease with an increase in the value mass concentration of solid particles or non-idealness of the gas in the mixture. A comparison has also been made between the cylindrical and spherical geometries. It is found that the blast (shock) wave is more influential in the case of spherical geometry in contrast to that in the cylindrical geometry case. Also, the blast wave decay is due to an increase in the solid particle’s mass concentration or gas non-idealness parameter, and its strength increases with an increase in the ratio of the solid particles to the initial gas density.

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来源期刊
CiteScore
2.60
自引率
0.00%
发文量
37
审稿时长
>12 weeks
期刊介绍: To promote research in all the branches of Science & Technology; and disseminate the knowledge and advancements in Science & Technology
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