Journal of Jilin University(Engineering and Technology Edition) ›› 2024, Vol. 54 ›› Issue (9): 2733-2740.doi: 10.13229/j.cnki.jdxbgxb.20221407

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Thrust rod ball hinge bionic surface improvement and finite element analysis

Hua-min LIU(),Shu-han YANG,Yi LI,Ce LIANG,Qi-gang Han()   

  1. College of Materials Science and Engineering,Jilin University,Changchun 130022,China
  • Received:2022-11-07 Online:2024-09-01 Published:2024-10-29
  • Contact: Qi-gang Han E-mail:liuhm@jlu.edu.cn;hanqg@jlu.edu.cn

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Abstract:

The bionic friction-increasing principle of locust foot pad was mainly applied to the rubber surface of the ball hinge of the thrust rod in commercial vehicles, and the bionic spherical crown-like flexible projections are constructed on the rubber ball hinge surface to increase the stiffness of the ball hinge. The height, radius and spacing of the bionic flexible projection were varied, and the radial stiffness, deflection stiffness and torsional stiffness of the thrust rod ball hinge were investigated by finite element analysis using Abaqus software. The results show that the optimum results are obtained for a projection height of 1 mm, radius of 4 mm and spacing of 10 mm. Finally, the optimal solution is analyzed comprehensively, and the feasibility of the solution is verified by simulation and experiment.

Key words: thrust rod ball hinge, bionic surface optimization, locust foot pad, finite element analysis

CLC Number: 

  • TG356

Fig.1

Schematic diagram of the position of the ball hinge of the thrust rod"

Fig.2

Comparison of the experimental curve and the fitted curve"

Table 1

Parameter settings for the 3N-Ogden model"

本构方程μnαnDn

Ogden

N=3

μ1=1.202α1=0.551D1=1.834
μ2=1.680e-03α2=11.334D2=1.066
μ3=1.180e-03α3=-13.469D3=-1.002

Fig.3

Locust foot pads"

Fig.4

Comparison of assembly of original rubber body mesh and rubber body mesh with bionic surface"

Fig.5

Schematic diagram of bionic flexible bump parameters"

Table 2

Values of variables a,b,c"

编号凸起高度a/mm凸起半径b/mm凸起间距c/mm
11110
21210
31310
41410
52410
63410
74410
8148
91412
101414

Fig.6

Comparison of static stiffness between original model and model 1~10"

Fig.7

Stress clouds of the original model and model 4 under deflection conditions"

Fig.8

Comparison of the original model and models 1~4 at 5 Hz"

Fig.9

Radial dynamic stiffness curves for the original model and models 1~4 at 5~20 Hz"

Fig.10

Comparison of radial hysteresis loops,torsional hysteresis loops and deflection hysteresisloops for models 4, 8~10 at 5 Hz"

Fig.11

Radial dynamic stiffness curves for models 4, 8-10 at 5-20 Hz,torsional dynamic stiffness curves and deflection stiffness curves"

Table 3

Variation of dynamic stiffness"

编号5 Hz10 Hz15 Hz20 Hz
径向扭转偏转径向扭转偏转径向扭转偏转径向扭转偏转
123.3514.3531.5535.4313.8316.6435.0212.044.8434.619.234.10
221.3227.2736.7230.1022.9220.5436.4118.928.9035.4714.888.82
318.7836.2240.4633.0130.4323.3937.3326.7814.4038.8923.0712.05
427.4151.7057.7538.3545.5937.4838.7143.2424.4844.4437.4922.74
825.8950.1457.0439.8147.0437.3343.3242.3824.3544.0237.6121.49
927.4451.2757.2237.8647.6936.7343.7842.6323.8244.4437.1822.11
1025.3852.2757.9340.2946.3837.1838.2543.4924.2142.3137.0221.86

Fig.12

Test stand and thrust rod ball hinge"

Fig.13

Comparison of simulated and experimental results of dynamic stiffness of thrust rod ball hinge"

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