SU1262365A1 - Method for vibroacoustical check of articles - Google Patents

Abstract

The invention relates to non-destructive testing and can be used to control thin-walled products using elastic vibrations. The aim of the invention is to accelerate the monitoring by eliminating the preliminary determination of the resonant frequency of the oscillations of the defect-free section. On the controlled area of the product, a massive corpuscular bell is installed and, with its help, a section in the form of a figure with different moments of inertia about its main axes is limited. With the help of a source of oscillations, elastic oscillations are excited in this region and the resonant frequency of this region is fixed. The bell housing is rotated around the axis at a predetermined angle, again excite elastic oscillations in a limited area, measure the resonant frequency of the new section, etc. Then, depending on the dependence of the resonant iD frequency of the section on the angle of rotation, determine whether the tested area is defective. 2 ill.

Description

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Claims (1)

SP The invention relates to non-destructive testing and can be used to control thin-change products using elastic vibrations. The purpose of the invention is to increase the monitoring performance by eliminating the preliminary determination of the resonant frequency of oscillations of the defect-free section. FIG. 1 shows a device for implementing the proposed method; in fig. 2 shows the dependence of the frequency of resonant oscillations of a limited area on the angle of rotation for defect-free (I) and defective (II) control zones. The device comprises a bell housing 1, which allows to restrict in the controlled zone 2 of the article section 3 as a figure with different moments of inertia about its main axes. A source of 4 sound vibrations (loudspeaker) is mounted in the top of the bell-case 1, which is connected to a sound generator 5 and a frequency meter 6. The rotary telescope 7 is also mounted in the bell-case 1, which is equipped with a directional illuminator 8. In order to ensure a snug fit of the contact surface of the bell 1 to the controlled section 3 of the article, a gasket 9 made of a easily deformable material is installed between them. In the product control zone 2, a sound oscillation receiver 10 is installed (for example, a piezoelectric accelerometer), which is connected to a millivoltmeter 11. In addition, the device is equipped with a circular ruler 12 for controlling the amount of rotation of the bell housing 1. The method of vibro-acoustic control of the products is as follows . A massive bell housing 1 is installed on the controlled area 2 of the article and with its help the area 3 of the control is defined as a figure with different moments of inertia about its main axes (for example, an ellipse or rectangle). Then, using a rotatable telescope 7 and an illuminator 8, they fix the position of the axis of rotation of the housing-bell 1. The frequency of the voltage supplying the sound source 4 is measured with a sound generator 5, and excites resonant oscillations of a portion of the control zone limited by the housing-bell 1. The occurrence of the resonant mode of oscillations is determined with the aid of a receiver of 10 acoustic oscillations and the associated millivoltmeter 1 1 to the maximum of the readings of the latter. Using a frequency meter 6 connected to a sound generator 5, the frequency is measured from the resonant oscillations of a limited area, the measured value of ω is recorded. Then, the Cornus bell 1 is turned at an angle φ around a fixed axis of rotation (about an axis passing through point O). To control the angle f, a circular ruler 12 and a protrusion on the bell housing 1 mounted on the controlled section 3 of the product (Figs. 1 and 2) are monitored by turning the bell housing 1 by means of the telescope and the illuminator 8. Then the bell 1 is rotated again at a predetermined angle f and the frequencies are measured, measurements are made until the total angle of rotation is reached 360 °. The dependence of the resonant frequencies of the sections on the angle of rotation is constructed. If the controlled zone 2 is defect free, then the resonant frequency of all sections 3 is the same and the above dependence is represented as a straight line parallel to the abscissa axis (Fig. 2). When monitoring the defective zone 2, the frequency w of the resonant oscillations of the limited area 3 is smaller than for a similar defect-free area. When the bell housing 1 is rotated, the relative position of the restricted portion 3 with respect to the direction of the crack changes. This causes a change in the stiffness of the limited area and, accordingly, the resonant frequency. Claims The method of vibro-acoustic testing of products, which consists in installing a vibration source with a bell-shaped case on the product, excites elastic oscillations in the parts of the product limited by the case and measures the resonant frequency of these vibrations, which are designed to increase the control performance due to the exclusion of a preliminary determination of the resonance frequency of oscillations of the defect-free area, the product sections having the shape of A figure with different moments of inertia about its main axes, successively rotate the body around a fixed axis at a predetermined angle, the excitation of elastic oscillations in the sections is performed at each angle of rotation of the body, and the defectiveness of the control zone is determined from the dependence of the resonant frequencies of the sections. 90 ° 780 ° 270 ° 360 ° FIG. 2