Co-simulation of self-propelled artillery based on virtual prototype technology

In present study, a virtual prototype of self-propelled artillery was constructed based on virtual prototype technology, and the whole impact process of artillery firing simulation was completed using ADAMS and AMEsim software. Results showed that the constructed artillery firing simulation system w...

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Published in:Journal of mechanical science and technology 2023, 37(12), , pp.6617-6627
Main Authors: Guo, Zhangxia, Yuan, Zekun, Yang, Yuliang, Jin, Yanxiang, Zhao, Jiajun, Li, Taiyang
Format: Article
Language:English
Subjects:
Control
Dynamic response
Dynamical Systems
Engineering
Fatigue life
Industrial and Production Engineering
Mechanical Engineering
Original Article
Simulation
Stability analysis
Vibration
Vibration response
Virtual prototyping
기계공학
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container_end_page 6627
container_issue 12
container_start_page 6617
container_title Journal of mechanical science and technology
container_volume 37
creator Guo, Zhangxia
Yuan, Zekun
Yang, Yuliang
Jin, Yanxiang
Zhao, Jiajun
Li, Taiyang
description In present study, a virtual prototype of self-propelled artillery was constructed based on virtual prototype technology, and the whole impact process of artillery firing simulation was completed using ADAMS and AMEsim software. Results showed that the constructed artillery firing simulation system was reasonable. It could add a recoil dynamic response suitable for live firing to the tested artillery and could detect the vibration response characteristics of the artillery through the test device. Through numerical simulation, a quantitative analysis of artillery firing stability, stress state, and fatigue life under different working conditions was performed. All simulation results were in good agreement with the real situation. This research provides a certain reference for the evaluation of artillery firing stability and lays a good theoretical foundation for the engineering development and practical application of the test device.
doi_str_mv 10.1007/s12206-023-1133-y
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subjects Control
Dynamic response
Dynamical Systems
Engineering
Fatigue life
Industrial and Production Engineering
Mechanical Engineering
Original Article
Simulation
Stability analysis
Vibration
Vibration response
Virtual prototyping
기계공학
title Co-simulation of self-propelled artillery based on virtual prototype technology
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