SU1370472A1 - Device for exciting resonance oscillations of complex structures - Google Patents

Abstract

The invention relates to a test technique and can be used to determine the frequency and shape of the natural oscillations of the tested products. The aim of the invention is to reduce the test duration by automating the installation of the initial amplitudes of the test signal in the dependent measurement channels. The goal is achieved by having two triggers, three controlled switches, a pulse counter, a variable division factor, a reversible counter, each triggered channel, a device consisting of a main channel for auto-tuning the test signal and dependent channels for selecting the amplitudes of the test signals. a reproducing digital-to-analog converter, a driver, an input / output unit containing a sequentially connected keyboard, register and indicator. 1 il. L

Description

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The invention relates to a testing technique and can be used to test products at resonant frequencies.

The purpose of the invention is to reduce the duration of the tests due to the automatic installation of the initial amplitudes of the test signal in the dependent measurement channels,

The drawing shows a functional electrical circuit of the device.

The device contains the main channel 1 of the auto-tuning of the test signal frequency and the dependent channels 2 of the selection of the amplitudes of the test signals. Each channel contains a power amplifier 3, the output of which is connected to the input of vibration exciter A, which is connected to the test structure 5. A vibration sensor 6 (each channel) is installed on the test structure, the output of which is connected to the first input of the phase detector 7

The main channel also includes a frequency controller 8, the input of which is connected to the output of the phase detector 7, and the output to the input of a controlled oscillator 9, the output of which is connected to the input of the amplifier 3 power and the second input of each phase detector 7.

Each dependent channel includes the first trigger 10, the inputs of which are connected to the output of the phase detector 7, and the first controlled switch 11, the inputs of which are connected to the outputs of the first trigger 10,

The device also contains a counter 12 pulses with a variable division factor, the input of which is connected to the output of the controlled generator 9, and the output connected to the input of the second controlled switch 13. The control input of the second controlled switch 13 is connected to the output of the first controlled switch 11. Outputs the second controlled switch 13 is connected to the counting inputs of the reversible counter 14, the outputs of which are connected to the inputs of the multiplying digital-to-variable converter 15, One of the inputs of the digital-analog conversion The oscillator 15 is connected to the output of the controlled oscillator 9, and the output of the inverter 15 is connected to the input of the inverter 16 and to one of the inputs

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The outputs of the third controlled switch 17, the second input of which is connected to the output of the inverter 16. The output of the loan of the reversible counter 14 is connected to the input of the former 18, the output of which is connected to the counting input of the second trigger 19,

In addition, the device contains an input-output unit 20, in which a serially connected keyboard 21, a register 22 and an indicator 23 are included. The inputs of the register 22 are connected to the outputs of the reversible counter 14 and the second trigger 19, and the outputs of the register are connected to the installation inputs of the reversible counter 14 and the second trigger 19. The output of the second trigger 19 is also connected to the control inputs of the first controlled switch 11 and the third controlled switch 17, the output of which is connected to the input of the power divider 3.

The device works as follows.

When the main channel is turned on in a closed loop containing the structure under test, a mode is established in which the in-phase signals arrive at the input of the phase detector 7 of the main channel 1. At the same time, an extracting signal is formed at the output of the controlled oscillator 9, the frequency of which is close to one of the resonant frequencies of the structure under test and depends on the connection point of the main channel vibration exciter. In this case, the relative phase shifts between the oscillations at the points of connection of the vibration sensors of the dependent and main channels are not equal to O or 180, which is typical of nonresonant oscillations of the structure under test.

Before closing the dependent channels, the initial amplitudes Xj - Xf, the test signals are set, and the signals are in phase or antiphase Xn relative to the reference signal X, from the output of the controlled oscillator 9. For this information from the register 22 is fed to the installation the inputs of the second trigger 19, the reversing counter 14. By the signal Q 1 from the output of the second trigger 19, the input of the power amplifier 3 is controlled by the controlled switch 17 to the output of the multiplier

a digital-to-analog converter 15, as a result of which the signals X, and X p any transducer gain 15 will be in phase. The signal Q O from the output of the second trigger 19 provides the antiphase signals X, and Xj.

The nature of the adjustment process after closing one of the dependent channels is determined by the set value of the initial amplitude of the test signal in channel 1.

For example, if X 0, the signal Y from the output of the vibration sensor of the dependent channel lags in phase from the reference signal X, and the level of logic 1 is set at the output of the first trigger 10.

The first controlled switch 1 1 with the signal Q 1 from the output of the second trigger 19 forms the level of the logical unit at its output. This signal to the output of the pulse counter 12 with a variable division factor through the second switch 13 connects the summing counting input of the reversing counter 14, the reverse counter performs a direct count, i.e. when another pulse arrives at the summing input from the pulse output of the pulse counter 12, the number at the output of the reversible counter increases by one.

the maximum force distribution Xj / X, 0.15.

If the amplitude value of the test signal in the dependent channel exceeds the optimal value, the signal Y from the output of the vibration sensor of the dependent channel will be ahead in phase of the reference signal X ,,

as a result, the Q 0 level is established at the output of the first trigger 10. The Q 0 level is formed at the output of the first switch 11. With this signal, the subtracting counter input of the reversing counter 14 is connected to the variable division factor through the second switch 13 counting, i.e. when another pulse arrives at its input, the number at the output decreases by one, as a result of which the transfer coefficient of the multiplying device begins to decrease to a value that provides the power distribution optimal for this resonant frequency.

Thus, in the proposed device (unlike the known ones), it is possible to preset the initial amplitudes of the test signal in the dependent channels, which shortens the test time. Also excluded

Thus, the coefficient of damage to the tested subscriber of transferring the multiplying digital-design by forces exceeding the analog converter 15 is increased, which leads to a change in the type of amplitude-phase characteristics W, (jco) and W (jco) and, therefore, changes in phase 40 shifts of the signals arriving at the inputs of the phase detectors of the main and dependent channels. The closed phase locked loop systems of the main and dependent channels, which are connected 45 to each other through the tested structure 5, work out phase mismatches. Phase-locked loop processes terminate when signals

specified limits.

The economic effect from the introduction of the proposed device is to reduce the duration of testing and depends mainly on the cost of one experiment and the number of tests per year.

Claims (1)

Invention Formula A device for exciting resonant oscillations of complex structures, consisting of a main channel from the outputs of nibro-sensors 6, provide Q test-frequency auto-tuning with in-phase with reference test signal and dependent selection channels the output signal of the controlled oscillator 9. The regime that is established as a result of the adjustment is characterized by the ratio of amplitudes applied to the structure of the forces under test, which is optimal for a given resonant frequency. So, for example, for the resonant frequency W, it is characteristic that the test structure can be damaged by forces exceeding specified limits. The economic effect from the introduction of the proposed device is to reduce the duration of testing and depends mainly on the cost of one experiment and the number of tests per year. Invention Formula the amplitudes of the test signals, each of which contains a power amplifier, connected to an exciter and vibration sensor connected to the gg design, and a phase detector, the first input of which is connected to the output of the vibration sensor, are connected in series between the output of the phase detector and the power amplifier inputs a frequency controller and a controlled oscillator, the output of which is connected to the second input of each phase detector, characterized in that, in order to shorten the duration and automate uu tests, each dependent channel administered first trigger-io under house power amplifier formation. The first controlled switch connected to the output of the phase detector, the inputs of which are connected to the outputs of the first trigger, a pulse counter with a variable division factor, the input of which is connected to the output of the controlled oscillator, a second controlled switch whose input is connected to the output of a counter with a variable coefficient dividing, and the control input 2o the hysteres and the indicator, the inputs of the register are connected to the code of the first controlled switch, a reversible counter, the counting inputs of which are connected to the outputs of the second control avlaemogo commutator, multiplier digital-analogue 25 trigger. a second converter connected by inputs to the outputs of a reversible counter and a controlled oscillator; an inverter connected to the output of a multiplying digital-to-analog converter; a third controlled switch whose inputs are connected to the input and output of the inverter, and a code with an input A second trigger is connected to the output of the reversible counter, whose counter input is connected to the output of the former, and the output to the control input of the third controlled switch and the control input of the first controlled switch; enabled keyboard, connected to the outputs of the reversible counter and the second trigger, and the outputs of the register are connected to the installation inputs of the reversible counter and the second