SU1330547A1 - Method of vibration-acoustic check of thin-walled structures - Google Patents

Abstract

The invention relates to non-destructive testing and can be used to control thin-walled structures using elastic vibrations. The aim of the invention is to reduce the cost of control by reducing the excitement force. According to the method, elastic oscillations with a constant amplitude in the loaded zones of the structure under study are excited. To do this, at each location of the added mass, the amplitude of the exciting force is varied so that the amplitude of oscillation of the added mass is kept minimal. The amplitude of the exciting force is then measured, and the measurement of this amplitude from the location of the added mass is judged on the presence of the defect and its location. 2 Il. W (L & 0 00 SP 4

Description

 13305Д7

The invention relates to

This control and can be used for the control of thin-walled structures with the help of elastic vibrations,

The purpose of the invention is to reduce control costs by reducing the excitation force.

FIG. 1 shows a scheme for implementing a vibro-acoustic control method; in fig. 2 is a graph of the amplitude of the exciting force versus the location of the added mass.

Scheme contains 5 {screened end 20

sensitivity and control accuracy.

in block 5, the comparison compares the actual amplitude Y of the oscillations of the added mass 2, measured by means of the displacement sensor 3, with the given amplitude YQ, dd. With

Oh, where is -U „, gain

fbY,

VX ,, aA-Yo.

in controllable amplifier 7 increasing

25

liY o gain is reduced30

35

The structure I installed on it resides minimal with sufficient connected mass 2 and displacement sensor 3 connected in series with measured amplifier 4 and comparison unit 5, the output of which is connected to electric signal generator 6 through controlled amplifier 7 connected to vibrator 8 and a 9 amplitude meter.

The method of vibroacoustic control of thin-walled structures is carried out as follows.

The local areas of structure 1 are loaded, with a connected mass of 2, the attached mass is preset in the middle of structure 1, using a generator 6 of electric signals controlled by force 7 in a constant amplification mode and the vibrator 8 is excited through an added mass 2 elastic oscillations, determine amplitude - frequency response of the system using a 3. displacement sensor and measuring force connected to it, body 4,

The working frequency of the exciting harmonic force is taken to be the frequency, the value of which corresponds to the amplitude of the amplitude-frequency characteristic, 1/3 lower than the maximum value. ,

Set the maximum gain value in the controlled amplifier 7 (to limit the amplitude of the exciting force in the structural parts closest to the supports) and the magnitude of the oscillation amplitude Y, one in the comparison unit 5, depending on the structure being examined.

eats when

the gain is kept constant. A controlled amplifier 7 amplifies a signal of a generator of electric signals 6, From the output of a controlled amplifier 7, a signal is fed to a vibrator 8, the bark of which is mechanically connected to the connected mass 2, Amplitude meter 9 measures the amplitude of an electrical signal from the output of a controlled amplifier 7, proportional to the amplitude of the exciting force.

A curve of the dependence of the amplitude of the exciting force on the 4Q location of the added mass 2 (Fig. 2) is plotted.

This dependence in the area of the defect has a sharp peak, the height of which depends on the size of the defect. The obtained peak of the curve is judged on the presence of the defect and its location in the structure.

Plots a and b 2 of the curve are obtained by operating a controlled amplifier 7 with a maximum gain K., t, e. in the parts of the structure closest to the supports. With an increase in the specified maximum value of gain K in the controlled amplifier 7 and with a decrease in the value of the given value of the amplitude of oscillations YO. Jg, in block 5 of the comparison, these segments decrease.

As a result, by reducing the amplitude of the exciting force, 50 are reduced.

The location of the attached mass 2 is successively changed, fixing the coordinate points of its placement. At each location of the attached mass 2 in the loaded zones, elastic oscillations are excited by a harmonic force with a previously selected operating frequency. At the same time, the amplitude of oscillations of the loaded zones is kept constant (equal to YO ,.), for which the amplitude of the exciting force is changed so that the amplitude of the cobalt of the added mass 2

sensitivity and control accuracy.

in block 5, the comparison compares the actual amplitude Y of the oscillations of the added mass 2, measured by means of the displacement sensor 3, with the given amplitude YQ, dd. With

Oh, where is -U „, gain

fbY,

VX ,, aA-Yo.

in controllable amplifier 7 increasing

liY o gain is reduced

live with a minimum

eats when

the gain is kept constant. A controlled amplifier 7 amplifies a signal of a generator of electric signals 6, From the output of a controlled amplifier 7, a signal is fed to a vibrator 8, the bark of which is mechanically connected to the connected mass 2, Amplitude meter 9 measures the amplitude of an electrical signal from the output of a controlled amplifier 7, proportional to the amplitude of the exciting force.

Build a dependence curve change-. nor the amplitude of the exciting force from the location of the added mass 2 (Fig 2).

This dependence in the area of the defect has a sharp peak, the height of which depends on the size of the defect. The resulting peak of the curve determines the presence of the defect and its location in the structure.

Plots a and b 2 of the curve are obtained by operating a controlled amplifier 7 with a maximum gain K., t, e. in the parts of the structure closest to the supports. With an increase in the set maximum gain value K in the controlled amplifier 7 and with a decrease in the set value of the oscillation amplitude YO .jg, in block 5 of the comparison, these sections decrease.

As a result, by reducing the amplitude of the exciting force, the

the cost of energy consumed when oscillations are excited, and the likelihood of damage to the structure under study during control is reduced.

Claims (1)

Invention Formula The method of vibroacoustic control of thin-walled structures, which consists in first measuring the amplitude-frequency characteristic of the structure when the attached mass is located in its center, fixes the frequency of the first extremum of this characteristic, determines the magnitude of the operating frequency corresponding to the amplitude, 1/3 lower than the amplitude of successively load local zones of the structure with an attached mass, excite harmonic force with an operating frequency, elastic oscillations in the loaded zones, parameters of elastic oscillations are measured at each location of the added mass and the dependence of the parameters of elastic oscillations on the location of the attached mass is judged to indicate the presence of a defect and its location in the structure, about the fact that, with the purpose of reducing control costs, excite elastic coils with a constant amplitude in the loaded zones of the structure; measure the amplitude of the exciting force, from which the controlled parameters are determined.  five e shig.1 oh oh TsOZ 0.01, Ts05 QOB ozig.g Oh, O7 Tsoag, t Editor L. Povhan Compiled by And, Ardashev Tehred i.Popovich Proofreader c. But ha Order 3576/46 Circulation 776 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4