基于ABAQUS模拟的准零刚度织物隔振器制备

doi:10.13475/j.fzxb.20241207401

摘要/Abstract

摘要： 为解决线性隔振器在低频条件下隔振性能与承载能力之间的矛盾,通过设计具备非线性刚度的结构来构建准零刚度隔振器。受弯曲折纸启发,首先构建一种弯曲折痕模型,通过有限元模拟的方法发现其具有非线性压缩力,进而研究了模型参数对力-位移的影响,揭示了准零刚度原理,并通过织物压缩实验验证,阐明了非线性刚度的可调机制;然后以缝合方式制备2种不同折痕曲率的织物立体单元,利用仿真模拟和压缩实验验证其具备不同刚度特性;最后通过施加正弦激励信号检测2种织物立体单元阵列的振动响应。结果表明,两种织物单元的压缩力-位移曲线实验结果与模拟值呈显著相关,准零刚度织物单元阵列在18 Hz下隔振性能最优,振幅传递性为-14.5 dB,在低频(5~25 Hz)下较正刚度织物单元阵列有着良好的隔振性能,可以用作非线性隔振器。

关键词: 弯曲折痕模型, 隔振性能, 刚度可调, 织物单元, 织物隔振器

Abstract:

Objective In order to solve the contradiction between the isolation bearing capacity and isolation frequency of linear isolators at low frequencies, a quasi-zero stiffness fabric isolator with this characteristic is designed using diagonal fabric based on the principle of nonlinear stiffness. A sinusoidal excitation signal is applied to the vibration isolator to evaluate its vibration isolation performance through vibration testing.

Method A bending crease model was developed in SolidWorks, and finite element analysis (FEA) was conducted using ABAQUS to simulate the compression behavior of the model. The same bending crease pattern was then applied to the fabric, followed by compression experiments. Two fabric solid elements with different crease curvatures were designed based on the bending crease model. Finite element simulations and experimental compression tests were performed. Vibration isolation performance tests were carried out on different fabric three-dimensional unit arrays to verify the low-frequency vibration isolation performance of the quasi-zero stiffness fabric isolator.

Results Finite element simulation compression was performed on the bending crease model. The simulation results showed that during the compression process of the model, the stress was first concentrated at the creases on both sides with a symmetrical distribution. As the degree of bending increased, the stress was transferred to the middle of the crease. The stress value on the bending surface was always lower than that at the crease throughout the process. The compression force-displacement curve was analyzed to assess the performance. Three different types of stiffness curves were obtained by changing the model parameters (chord height h, folding angle β). When other parameters were held constant, the chord height h was increases from 2.0 mm to 5.5 mm, the stiffness of the model was changed from negative stiffness to quasi-zero stiffness and then to positive stiffness, and the initial compression force value demonstrated a decrease from 30 cN to 21 cN. As the crease angle β varied from 90° to 150°, the model's stiffness was changed from negative stiffness to positive stiffness. Compression experiments were performed on fabric samples using the same bending crease pattern. The compression force displacement curves of the fabric at folding angles β of 110°, 130°, and 150° were highly similar to those obtained from finite element simulation, verifying the correctness of the finite element simulation and jointly elucidating the adjustable mechanism of nonlinear stiffness. Finite element simulation and experimental compression were conducted on fabric units with two different fold curvatures. The correlation coefficients between the simulation results and the experimental results were both above 0.833. Two types of fabric unit arrays were placed on an excitation table. Loads were applied to them to achieve quasi-zero stiffness and positive stiffness, respectively. The experimental results demonstrated that the designed quasi-zero stiffness fabric unit exhibited superior isolation performance compared to the positive stiffness fabric unit in the frequency range of 5-25 Hz.

Conclusion A fabric three-dimensional unit isolator was designed to solve the problem of low-frequency isolation in linear isolators. A bending crease model was proposed, which was subjected to finite element simulation compression and fabric experimental compression. The influence of model parameters on the compression force displacement curve was revealed in two ways. Three distinct stiffness curves were obtained, which elucidate the mechanism of nonlinear stiffness adjustment. Based on this mechanism, two types of fabric three-dimensional units with different bending crease curvatures were designed and simulated and experimentally verified. The experimental compression force-displacement curves of the two fabric units exhibited a strong correlation with the simulation results, with quasi-zero stiffness and positive stiffness demonstrated, respectively. The results show that in the low-frequency range, the vibration transmission of quasi-zero stiffness fabric array is negative, while that of positive stiffness fabric array is positive. The quasi-zero stiffness fabric array exhibits better isolation performance than the positive stiffness fabric array, indicating that the former can be used as a nonlinear isolator.

Key words: bending crease model, vibration isolation performance, adjustable stiffness, fabric unit, fabric vibration isolator

中图分类号:

TS101.8

张兆栋, 王蕾, 潘如如. 基于ABAQUS模拟的准零刚度织物隔振器制备[J]. 纺织学报, 2025, 46(09): 163-170.

ZHANG Zhaodong, WANG Lei, PAN Ruru. Preparation of quasi-zero stiffness fabric isolator based on ABAQUS simulation[J]. Journal of Textile Research, 2025, 46(09): 163-170.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20241207401

http://www.fzxb.org.cn/CN/Y2025/V46/I09/163

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参考文献 14

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样品编号	原料	组织	纱线线密度/tex		密度/(根·(10 cm)^-1)		面密度/ (g·m^-2)	厚度/ mm
样品编号	原料	组织	经纱	纬纱	经密	纬密	面密度/ (g·m^-2)	厚度/ mm
1	100%棉	斜纹	29.50	29.50	300	250	387	0.68
2	100%棉	斜纹	36.88	36.88	232	228	435	0.74
3	涤纶/棉(70/30)	平纹	45.38	45.38	107	92	446	1.20
4	100%棉	斜纹	39.33	39.33	266	178	470	0.93
5	100%棉	斜纹	36.88	36.88	285	174	350	0.76
6	100%棉	斜纹	36.88	36.88	259	167	415	0.90
7	100%棉	平纹	15.94	15.94	180	173	283	0.47
8	100%棉	平纹	36.88	36.88	242	161	378	0.76
9	涤纶/棉(65/35)	平纹	39.33	39.33	112	90	487	1.07

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