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引用次数: 0
摘要
形状记忆合金 (SMA) 是传感器、致动器或无源阻尼器的理想候选材料。本文研究了超弹性镍钛孔盘的动态响应,以评估其在基于 SMA 的阻尼器应用中相对于频率和温度的阻尼性能。这项研究涉及几个关键步骤。首先,通过拉伸测试对 SMA 的超弹性行为进行实验表征。该测试活动提供了所需的数据,用于确定热力学构成模型的材料参数,该模型已在有限元代码 Abaqus 中实施。利用确定的参数,进行了基于有限元的结构分析,以预测磁盘的工作范围,确保其保持在超弹性域内而不会造成潜在损坏。在静态分析之后,又对磁盘进行了动态机械分析(DMA)。通过采用复杂刚度方法,我们进一步检验了磁盘的阻尼效应。这种动态方法能够根据激励频率、测试温度、振动幅度和预定义的静态位移详细描述表观刚度和阻尼特性。结果表明,尽管圆盘具有很大的阻尼潜力,但结构效应明显优于相变效应。
Structural analysis of the dynamic response of a shape memory alloy based damper
Shape memory alloys (SMAs) are promising candidates for use in sensors, actuators, or passive dampers. This paper investigates the dynamic response of a superelastic NiTi holed disk to assess its damping performance relative to frequency and temperature for SMA-based damper applications. This study involved several key steps. Initially, the superelastic behavior of the SMA was experimentally characterized through tensile tests. This testing campaign provided the required data to identify material parameters of a thermomechanical constitutive model, already implemented in the finite element code Abaqus. Using the identified parameters, a finite element based structural analysis was conducted to predict the disk’s operational range, ensuring it remained within the superelastic domain without incurring potential damage. Following this static analysis, a dynamic mechanical analysis (DMA) was performed on the disk. By employing a complex stiffness approach, we further examined the disk’s damping effects. This dynamic method enabled a detailed description of the apparent stiffness and damping characteristics based on solicitation frequency, test temperature, vibration amplitude, and a predefined static displacement. The results indicated a clearly predominant structural effect over the phase transformation effect, despite the disk’s substantial damping potential.
期刊介绍:
The Journal of Vibration and Control is a peer-reviewed journal of analytical, computational and experimental studies of vibration phenomena and their control. The scope encompasses all linear and nonlinear vibration phenomena and covers topics such as: vibration and control of structures and machinery, signal analysis, aeroelasticity, neural networks, structural control and acoustics, noise and noise control, waves in solids and fluids and shock waves.