An Experimental Investigation of the Displacement Transmissibility for a Two-Stage HSLD Stiffness System

IF 1.9 Q3 ENGINEERING, MECHANICAL Vibration Pub Date : 2022-10-08 DOI:10.3390/vibration5040040
Janik Habegger, Marwan Hassan, M. Oliver
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引用次数: 1

Abstract

Vibration isolation across the frequency spectrum is a challenge in many applications, particularly at low frequencies where linear oscillators amplify excitation forces. To overcome this, nonlinear high static low dynamic (HSLD) stiffness oscillators have been proposed with the aim of reducing the resonant frequency while maintaining the high load capacities of much stiffer linear systems. A two-degree of freedom (2DOF) HSLD stiffness system is proposed to investigate the effectiveness of such systems. Experiments reveal that a 2DOF non-linear HSLD stiffness system outperforms a similar single-degree of freedom (SDOF) HSLD stiffness system, as well as similar SDOF and 2DOF linear systems. Three performance criteria are used to assess these systems, including (1) minimizing the resonant frequency and maximizing the isolation zone, (2) minimizing the magnitude of amplification at resonance, and (3) maximizing the ability to isolate large input frequencies. Exact numerical and approximate analytical simulations are validated using these experimental data. A sensitivity analysis of system parameters reveals that it is necessary to incorporate adjustability into the geometry of a design to counteract unavoidable manufacturing tolerances. Changes of less than 2% to the stiffness or geometry of a system can drastically change its dynamic response.
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两级HSLD刚度系统位移传递率的实验研究
在许多应用中,跨频谱的隔振是一个挑战,特别是在低频时,线性振荡器会放大激振力。为了克服这一点,提出了非线性高静态低动态(HSLD)刚度振荡器,目的是在降低谐振频率的同时保持更刚性线性系统的高负载能力。提出了一种两自由度的HSLD刚度系统来研究这种系统的有效性。实验表明,2DOF非线性HSLD刚度系统优于类似的单自由度HSLD刚度系统,以及类似的SDOF和2DOF线性HSLD刚度系统。三个性能标准用于评估这些系统,包括(1)最小化谐振频率和最大化隔离区,(2)最小化谐振时的放大幅度,以及(3)最大化隔离大输入频率的能力。利用这些实验数据验证了精确的数值模拟和近似的解析模拟。对系统参数的敏感性分析表明,有必要将可调性纳入设计的几何结构中,以抵消不可避免的制造公差。系统的刚度或几何形状只要改变不到2%,就会极大地改变其动态响应。
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来源期刊
CiteScore
3.20
自引率
0.00%
发文量
0
审稿时长
10 weeks
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