Research on fairings with different aspect ratio under subsonic flow Based On FLUENT-Reference-Cited by-同舟云学术

Research on fairings with different aspect ratio under subsonic flow Based On FLUENT

Published:2022-12-27 Issue: Volume:27 Page:866-869
ISSN:2791-0210
Container-title:Highlights in Science, Engineering and Technology
language:
Short-container-title:HSET

Author:

Hu Keqing

Abstract

When rocket flying at high speed, large air resistance will generate at the front and around the rocket fairing. Results in significant reduction of the rocket's range and speed. The research shows that the air resistance produced by the fairing accounts for more than half of the total resistance of the rocket. As the shape of fairing is axisymmetric, a 2D model with triangle mesh was used for simulation to analyze the pressure around fairing. Eight group of fairing with aspect ratio from 0.25 to 2 were studied under the compressible non viscous airflow with 200 m/s incoming speed. The air resistance decreases with the increase of the aspect ratio, and the high pressure area around the fairing also reduces from more than a half to one third of the total fairing length. In these eight groups of fairings, the fairing with aspect ratio 2 performs best, receives the minimum air resistance and with pressure mainly distributed at the front end of the fairing.

Publisher

Darcy & Roy Press Co. Ltd.

Reference16 articles.

1. Ernesto F. Subsonic Compressible Fluid Flow Analysis by the Finite Element Method. Academia Journal of Scientific Research, 2021, 5(10): 460-467.

2. Chen Z., Guo F. Numerical simulation research on flow distribution of tube system of furnace based on Fluent-Impact of Different manifold bland structures on flow distribution. Petroleum Refinery Engineering, 2015, 67: 78-83.

3. Hilton F. Tests of a Fairing to Reduce the Drag of a Supersonic Swept-Wing Root. Physics of Fluids, 2012, 56(3): 120-128.

4. Zhou Y., Yang S., Luo B. Research on the Pressure-flow Performance of a Large-diameter Spool Valve Based on Fluent. Machine Tool & Hydraulics, 2011, 78(8): 79-83.

5. Bai X., Tang K., Hui L. I. Research on Three-Dimensional Flow Field Numerical Simulation and Its Experiment Based on FLUENT. Mechanical Engineer, 2012, 67: 230-239.