Longitudinal and Vertical Coupled Dynamic Model and Power Characteristics of Tracked Vehicle

被引：0

作者：

Li C. ^{[1
]}

Wu W. ^{[2
]}

Guo Z. ^{[2
]}

Yuan S. ^{[2
]}

Chen S. ^{[2
]}

机构：

[1] China North Vehicle Research Institute, Beijing

[2] School of Mechanical Engineering, Beijing Institute of Technology, Beijing

来源：

Binggong Xuebao/Acta Armamentarii | 2021年 / 42卷 / 03期

关键词：

Coupling dynamic model; Longitudinal and vertical coupling; Off-road condition; Power characteristics; Power flow; Tracked vehicle;

D O I：

10.3969/j.issn.1000-1093.2021.03.001

中图分类号：

学科分类号：

摘要：

The dynamics of tracked vehicle in the off-road condition is the basis of the prediction of the off-road driving ability. A longitudinal and vertical coupled dynamic modeling method of tracked vehicle is presented, in which the coupling effect of longitudinal and vertical motion of high speed tracked vehicle is considered. A vehicle coupling dynamic model is established. The driving performance of vehicle on the typical road was simulated and verified in the real vehicle test. On this basis, the power flow characteristics of the tracked vehicle were analyzed. The simulated results indicate that the proposed model can be used to calculate the influence of the different road conditions on the vehicle driving performance. In the off-road condition, the road roughness makes the body vertical, pitching and other movements consume part of the power, and then have a certain impact on the speed of the vehicle. The instantaneous non-driving power of the tracked vehicle fluctuates widely. With the deterioration in the road conditions and the increase in speed, the ratio of non-driving power to total input power increases.The demand for the total power increases, which limits the effective use of the driving power.The results can be used for the dynamic model construction and the power flow analysis of high-speed tracked vehicles. © 2021, Editorial Board of Acta Armamentarii. All right reserved.

引用

页码：449 / 458

页数：9

共 21 条

[1] ZHU J J, KHAJEPOUR A, ESMAILZADEH E, Et al., Ride quality evaluation of a vehicle with a planar suspension system, Vehicle System Dynamics, 50, 3, pp. 395-413, (2012)
[2] ZHANG Y X, ZHANG X J, ZHAN M, Et al., Study on a novel hydraulic pumping regenerative suspension for vehicles, Journal of the Franklin Institute, 352, 2, pp. 485-499, (2015)
[3] MURPHY N R, AHLVIN R B., AMC-74 vehicle dynamics module, pp. 1-52, (1976)
[4] MCCULLOUGH M K, HAUG E J., Dynamics of high mobility track vehicles, Journal of Mechanical Design, 108, 2, pp. 189-196, (1986)
[5] RAKHEJA S, AFONSO M F R, SANKAR S., Dynamic analysis of tracked vehicles with trailing arm suspension and assessment of ride vibrations, International Journal of Vehicle Design, 13, 1, pp. 56-77, (1992)
[6] DHIR A, SANKAR S., Ride dynamics of high-speed tracked vehicles: simulation with field validation, Vehicle System Dyna-mics, 23, 1, pp. 379-409, (1994)
[7] MA Z D, PERKINS N C., A track-wheel-terrain interaction model for dynamic simulation of tracked vehicles, Vehicle System Dynamics, 37, 6, pp. 401-421, (2002)
[8] MATEJ J., Terrain-adaptive auxiliary track tensioning system for tracked vehicles, Journal of Computational & Nonlinear Dynamics, 8, 3, (2013)
[9] WANG H Y, CHEN B, RUI Q, Et al., Analysis and experiment of steady-state steering of tracked vehicle under concentrated load, Acta Armamentarii, 37, 12, pp. 2196-2204, (2016)
[10] ATA W G, OYADIJI S O., An investigation into the effect of suspension configurations on the performance of tracked vehicles traversing bump terrains, Vehicle System Dynamics, 52, 7, pp. 969-991, (2014)

← 1 2 3 →