Installation and test procedure for frequency stability under cyclic loading of metals and alloys

V. V. Mylnikov, E. A. Dmitriev, D. I. Shetulov
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Abstract

Manufacture of parts operating under difficult conditions of cyclic loading, as well as products with stable dimensions necessitates the use of materials with minimal manifestations of inelastic properties. Study of these materials suggests conducting specialized narrowly focused tests using newly developed machines and installations with appropriate experimental techniques. We present the design, operation and control features of the original electromagnetic installation for testing fatigue and frequency stability and operating in a self- oscillating mode, which provides the equality of the frequency of cyclic loading and natural frequency of the sample. The system of the installation control contains two closed circuits: for excitation of self-oscillations and for stabilization of the oscillation amplitude. The sample is loaded by electromagnetic force, and unloading occurs due to the elastic forces of the material. The methodology and algorithms for calculating the stresses of samples of various geometric shapes for estimating changes in amplitude-frequency characteristics are presented. The calculated relationship between the force applied to the sample and its movement at the point of application of force is derived with subsequent determination of the stress by a known force. The results of calibration tests for the static mode of sample loading are presented and the forces acting on the sample (external, inertia, and elastic forces) are evaluated taking into account the maximum stress and maximum strain amplitude. Static and cyclic loading modes are compared. The frequency characteristics obtained during testing steel samples according to the proposed method are obtained. The experimental results of tests with interruptions in the process of cyclic loading and continuous testing are analyzed. It is shown that interruptions in cyclic tests lead to a jump-like increase in the frequency, whereas continuous tests revealed no jumps. At the same time, a comparative analysis with the results of continuous tests showed that the overall frequency deviation is approximately the same for the entire operating cycle in both cases. It is shown that an increase in the frequency after rest is random and does not depend on the number of operating cycles.
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金属和合金循环载荷下频率稳定性的安装和测试程序
要制造在困难的循环加载条件下工作的零件以及尺寸稳定的产品,就必须使用非弹性特性表现最小的材料。要对这些材料进行研究,就必须使用新开发的机器和装置,并采用适当的实验技术,进行专门的狭义测试。我们介绍了用于测试疲劳和频率稳定性的原始电磁装置的设计、运行和控制特点,该装置以自振荡模式运行,可实现循环加载频率与样品固有频率相等。装置控制系统包含两个闭合回路:自振荡激励回路和振荡幅度稳定回路。样品由电磁力加载,卸载由材料的弹性力产生。本文介绍了计算各种几何形状样品应力的方法和算法,以估算振幅-频率特性的变化。通过计算得出了施加在样品上的力与样品在施加力处的运动之间的关系,并随后确定了已知力的应力。介绍了样品静态加载模式的校准测试结果,并根据最大应力和最大应变幅值评估了作用在样品上的力(外力、惯性力和弹性力)。对静态加载模式和循环加载模式进行了比较。根据所提出的方法,获得了测试钢材样品时的频率特性。分析了在循环加载和连续测试过程中中断测试的实验结果。结果表明,循环测试中的中断会导致频率的跳跃式增长,而连续测试则不会出现跳跃。同时,与连续测试结果的对比分析表明,在两种情况下,整个运行周期的总体频率偏差大致相同。这表明,静止后频率的增加是随机的,并不取决于运行周期的次数。
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