Method for Vibration Suppressing of New Type of Slender Support Rods

doi:10.12068/j.issn.1005-3026.2024.10.008

Abstract

Abstract:

Based on the advantages of high specific stiffness， light weight and designability of the lattice structure， a new type of slender support rod with the lattice structure filled with viscoelastic damping material was proposed， which enables the structure have strong damping performance on the basis of sufficient load?bearing capacity. The finite element method was used to analyze the dynamics of the lattice support rod and damping filled lattice support rod， and a response surface approximate model of dynamic stiffness peak corresponding to the first?order resonance frequency was established by the response surface method. The influence of the structural parameters on the dynamic characteristics was analyzed， and the dynamic stiffness peak was optimized by the genetic algorithm. Finally， the test demonstrated 57.14% reduction in the acceleration response amplitude for the lattic support rod filled with damping， confirming their superior damping performance.

Key words: slender support rod, vibration suppressing, lattice structure, viscoelastic damping material, parameter optimization

CLC Number:

TB 53

Ru-yu JIA, Hong-liang YAO, Ya-qiang CHEN, Chen-wei TANG. Method for Vibration Suppressing of New Type of Slender Support Rods[J]. Journal of Northeastern University(Natural Science), 2024, 45(10): 1425-1434.

Figures/Tables 25

Fig.1 Schematic diagram of the solid support rod structure

Fig.2 Schematic diagram of the Lattice support rod structure

Fig.3 Body?centered cubic sandwich cell structure

Fig.4 Simplified model of the support system

Fig.5 Dynamic mechanical properties of neoprene

Fig.6 Damping filled body?centered cubic lattice support rod model with circumferential cell number of 6

Table 1 Range of the response surface test parameters

因素	水平
因素	-1	0	1
H₁	0.5	2	3.5
H₂	0.5	2	3.5
D	0.5	1.25	2

Fig.7 Predicted values compared with the actual values

Fig.8 Response surface diagram of Kd on parameters H1 and H2 （D=1.25 mm）

Fig.9 Response surface diagram of Kd on parameters H1 and D （H2=1.25 mm）

Fig.10 Response surface diagram of Kd on parameters H2 and D （H1=1.25mm）

Fig.11 Iterative process of genetic algorithm optimization

Fig.12 Optimized front and rear rod sections

Table 2 Comparison of modal parameters between the solid support and the optimized damping filled lattice support rod

阶次	固有频率/Hz		损耗因子/%
阶次	实心	优化后	实心	优化后
一	368.25	326.61	0.03	0.103 9
二	368.25	326.72	0.03	0.103 9
三	2 117.1	1 839.9	0.03	0.134 6
四	2 117.1	1 840.5	0.03	0.134 6
五	2 653.9	2 364.8	0.03	0.089 9
六	4 277	3 642.4	0.03	0.338 5

Fig.13 Harmonic response analysis boundary conditions

Fig.14 Amplitude?frequency response curves of the solid support and damping filled lattice support rod

Fig.15 Time?domain steady?state response under first?order resonant frequency excitation

Fig.16 Steady state response under excitation with non?resonant frequency of 100 Hz

Fig.17 Time domain attenuation curves of the solid and damping filled lattice support rod

Fig.18 Unfilled neoprene rubber reinforced dot?matrix rod

Fig.19 Modal testing of the solid support

Fig.20 Modal testing coherence of the damping filled lattice support rod

Table 3 Results of the first?order modal test

支杆类型	固有频率/Hz	阻尼比
实心支杆	357.40	0.018 7
阻尼填充点阵支杆	307.98	0.032 6

Fig.21 Sweep test of the damping filled lattice support rod

Fig.22 Frequency sweep results of the solid support in the frequency range of 0~500 Hz

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