SU1578555A1 - Method of dynamic tests of elastodissipative elements - Google Patents

Abstract

The invention relates to vibration tests, in particular to methods and means of testing elastic-dissipative elements, for example, vibration isolators, springs, bellows, spacers, etc., and can be used in mechanical engineering to determine the elastic characteristics of their strength characteristics. The aim of the invention is to increase the informativeness of the tests by conducting a series of tests with various loading parameters. The method consists in fixing one end of the elastic-dissipative element, displacing the other end and changing the period and amplitude at the same number of times, recording the dependence of the total force characteristic on its displacement, analyzing the parameters of the elastic component with respect to the difference of the measured total power characteristic and the amplitudes of displacements, or change the period of the element displacements, registering the dependence of the total power characteristic on its displacement, analytically determine the pair The meter of the dissipative component is relative to the difference in the measured power characteristic and the amplitudes of the vibration velocities, and the parameters of the other component are determined from the difference in the power characteristic and the first component.

Description

The invention relates to vibration tests, namely, methods and means of testing elastic-dissipative elements, for example, vibration isolators, springs, bellows, spacers, etc., and can be used in mechanical engineering to determine the elastic and dissonative components of their force characteristics.

The aim of the invention is to increase the informativeness of the tests by conducting a series of tests with various loading parameters.

Operatively, the method is implemented as follows.

Claims (3)

1. Install the element in the test device, one end is rigidly fixed, and the other end is connected to the moving element of the device. 2. The movement of the moving end of the element is reported and the movement, speed, and force characteristic or reaction of the element in time are recorded. 3. Change the amount of displacement while changing the period ate 00 ate ate ate rotation, in order to keep the rate of deformation unchanged, the change in movement, speed and reaction with time is recorded. 4, The tests of clause 3 are carried out repeatedly with different deflation values. 5, The next series of tests was carried out with the same movement, jg but with a different period of rotation. 6, According to the records of the reaction and displacements in the function of the Phase Angle, the elastic component of the reaction is determined, and then the dissipative component. 15 7, In the second series of tests, the dissipation component of the reaction is determined by the implementations of the reaction and rate as a function of the phase angle, and then h elastic component. 8, Comparison of the results according to claim 7 shows the degree of accuracy of the characteristics found and the direction of the search to refine them. Example, Determination of parameters of a vibration isolator made of rubber material, One end of the tested elastic-dispersed element is fixed, for example, to the sensitive element of a recording device, and the other is connected to a drive, which can be used as a crank-slider mechanism or an eccentric on a rotating shaft. The basis of the method is based on the expression of the components of the force characteristic or reaction in the form of the sum of the elastic and dissipative components R ($ sp СЈ + Ю элемента, where С is the element stiffness coefficient, К is the damping coefficient, and Ј are displacement and velocity. The drive informs one of the spring of the elastic-dissipating element of a given dynamic displacement with a period T. During the loading process, the change of displacements, velocities, and force characteristics — reactions in time t is continuously recorded and presented in the form of diagrams values of T and A again record the displacements, velocities and reactions, and build their diagrams as a function of phase angles. These test modes are characterized by the immutability of the dissipative component of the power characteristics of the element. After subtracting the value obtained at the second test 35 40 force characteristic — the reaction curve R (c) from the value of the reaction R (0) obtained during the first test, determines the change in the elastic component of the element. By dividing the difference in the values of the total reactions or force characteristics by the difference in the values and displacements of the data element in the example of two tests, the parameters of the stiffness coefficient of the elements of the elastic component are determined analytically. Knowing the parameters of the total force characteristic and the elastic component, the parameters of the dissipative component are determined from the difference between the total force characteristic and its elastic component. In the next series of tests, only the period of movement of the elastic-dissipative element is changed, the movement, speed and reaction are recorded and their diagrams are plotted as a function of phase angles. These test modes are characterized by the invariance of the elastic component of the power characteristics of the element. By subtracting the value of the power characteristic obtained in this series of tests — the reaction R (0) from the values R1 (0) —the change in the dissipative component is determined. The parameters of the other component are determined by the difference of the power characteristic and the first component. Invention Formula their The method of dynamic testing of elastic-dissipative elements, including fixing one the ordinate axis of which is the CQ end of the elastic-dissipative element, imparting to the other end a periodic displacement and measurement of the parameters of this displacement and the power characteristic, characterized in that, in order to increase the informativity of the tests, either the period or the amplitude of the displacements of the element is changed one and the same number of times, the value of F is additionally delayed newborn angle 6 2TG / T t. After removing the diagrams at certain values of the period Г and amplitudes A of the harmonic components of the displacement, the period of oscillations Γ, for example, decreases by n times and simultaneously decreases the amplitudes of the movements by the same number of times. When changed 55 with jg 85554 values of T and A again record the displacements, velocities and reactions, and build their diagrams as a function of phase angles. These test modes are characterized by the immutability of the dissipative component of the power characteristics of the element. After subtracting the value obtained at the second test force characteristic — the reaction curve R (c) from the value of the reaction R (0) obtained during the first test, determines the change in the elastic component of the element. By dividing the difference in the values of the total reactions or force characteristics by the difference in the values and displacements of the data element in the example of two tests, the parameters of the stiffness coefficient of the elements of the elastic component are determined analytically. Knowing the parameters of the total force characteristic and the elastic component, the parameters of the dissipative component are determined from the difference between the total force characteristic and its elastic component. In the next series of tests, only the period of movement of the elastic-dissipative element is changed, the movement, speed and reaction are recorded and their diagrams are plotted as a function of phase angles. These test modes are characterized by the invariance of the elastic component of the power characteristics of the element. By subtracting the value of the power characteristic obtained in this series of tests — the reaction R (0) from the values R1 (0) —the change in the dissipative component is determined. The parameters of the other component are determined by the difference of the power characteristic and the first component. Invention Formula  55 51578555 the dependence of the force characteristics, the displacement of the movement, the anatistics, on the displacement, are hidded, the parameters of the elastic component are analytically determined lytically; relative to the difference between the difference of the measured power, ha-measured power characteristic of the characteristics and the amplitudes of the vibrations, the amplitudes of displacements, or arrays, and the parameters of the other component of the displacements of the element, are determined by the difference the dependence of the power characteristic and the first component is recorded.