Study on Correlation Characteristics of Static and Dynamic Explosion Temperature Fields

Authors

  • Liangquan Wang Nanjing University of Science and Technology, China
  • Fei Shang Nanjing University of Science and Technology, China
  • Deren Kong Nanjing University of Science and Technology, China

DOI:

https://doi.org/10.30564/frae.v2i4.1545

Abstract

The warheads such as missiles and artillery shells have a certain speed of motion during the explosion. Therefore, it is more practical to study the explosion damage of ammunition under motion. The different speeds of the projectiles have a certain influence on the temperature field generated by the explosion. In this paper, AUTODYN is used to simulate the process of projectile dynamic explosion. In the experiment, the TNT spherical bare charges with the TNT equivalent of 9.53kg and the projectile attack speed of 0,421,675,1020m/s were simulated in the infinite air domain. The temperature field temperature peaks and temperature decay laws at different charge rates and the multi-function regression fitting method were used to quantitatively study the functional relationship between the temperature and peak temperature correlation calculations of static and dynamic explosion temperature fields. The results show that the temperature distribution of the dynamic explosion temperature field is affected by the velocity of the charge, and the temperature distribution of the temperature field is different with the change of the charge velocity. Through the analysis and fitting of the simulation data, the temperature calculation formula of the static and dynamic explosion temperature field is obtained, which can better establish the relationship between the temperature peak of the static and dynamic explosion temperature field and various influencing factors, and use this function. Relational calculations can yield better results and meet the accuracy requirements of actual tests.

Keywords:

Model building; Numerical simulation; Data analysis; Correlation function establishment

References

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Issue

Vol. 2 , Iss. 4 (October 2019)

Article Type

Research Paper

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