SU1402823A1 - Vibration-testing machine - Google Patents

Abstract

The invention relates to the field of mechanical engineering and can be used for vibration testing of products with compensation for their mass. The purpose of the invention is to increase the accuracy of determining the dynamic characteristics of the tested products, as well as the possibility of testing non-linear product designs by reducing the influence of the suspension on the oscillation parameters of the test product, as well as by using a vibration sensor as a vibration generator, which measures the vibration parameters product. The signal from oscillation generator 1 is amplified by amplifier 2, additional amplifier 3. Signal from amplifier 2 excites oscillations of vibrator 4, which loads product 5, the mass of which is compensated by the tension of suspension 6. Carriage 7 is driven by additional vibrator 9. During loading of the product 5, the amplitude of the oscillation of the product and the carriage 7 and the phase shift between them are measured. When the vibrostand is operating, to test non-linear product designs, by changing the gain of the additional amplifier 10, the amplitude of oscillation of the carriage 7 is adjusted to equal the amplitude of oscillation of the product 5. 1 Cp. File, 2 ill. (Oh (L

Description

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The invention relates to mechanical engineering, in particular to vibrostands used in testing large-sized products with compensation for their weight.

The purpose of the invention is to increase the accuracy of determining the dynamic characteristics of the tested products by reducing the effect of the suspension on the vibration parameters of the tested product, as well as using the vibration sensor, measuring 1 1, its vibration parameters at the point of attachment of the suspension and the product.

FIG. 1 is a block diagram of a shaker for testing linear designs; in fig. 2 - the same non-linear.

The vibration table for testing linear designs consists of oscillation generator 1, amplifier 2, additional amplifier 3, vibrator 4, exciting vibrations of the test product 5 mounted on suspension 6 (for example, in the form of a cable) mounted on carriage 7 located on rails 8. The vibrating table includes an additional vibrator 9.

The vibrostand for testing nonlinear structures consists of a generator I oscillations, an amplifier 2, a vibrator 4, loading test article 5, which is mounted on a suspension 6, which is fixed on a carriage 7 mounted on rails 8. A carriage 7 is driven by an additional vibrator 9, 10 oscillations excited by the generator (as the generator 10, a vibration sensor was taken measuring the parameters of the oscillations at the point of attachment of the product to the suspension) through an additional amplifier 3.

A vibration stand for loading linear structures works as follows.

The signal from oscillation generator 1 is amplified by amplifier 2 and additional amplifier 3, the signal from amplifier 2 excites oscillations of vibrator 4, which loads test product 5, whose weight is compensated by tension of suspension 6. Carriage 7, on which suspension 6 is fixed, moves along guide rails 8 The carriage 7 is oscillated by an additional vibrator 9. During loading of the test article 5, the oscillation amplitude of the test article and the carriage 7 and the phase shift between them are measured. By varying the gain and the phase of the oscillation of the additional amplifier 3, adjust the amplitude of oscillation of the carriage 7, equal to the amplitude of oscillation of the product under test, and the phase shift equal to zero. When the common-mode movement of the carriage 7 is relatively

product 5 and at equal amplitudes from oscillations, the suspension 6 remains all the time vertical and does not excite vertical oscillations (as it happens if

the carriage was missing, and the suspension would have been fixed to a fixed point, then in this case the suspension would have oscillated as a symbol.

A shaker for testing non-linear structures works as follows.

0 The signal from oscillation generator 1 is amplified by amplifier 2. The signal from amplifier 2 excites oscillations of vibrator 4, which loads the test product 5. The weight of the test product 5 is compensated

 the suspension 6 fixed to the carriage 7. The carriage 7 moves along the guides 8 under the action of the force of the additional vibrator 9. The additional vibrator 9 is excited by a signal from the vibration sensor 10, amplified by the additional amplifier 3.

0 During tuning of the vibrostand, the amplitude of oscillations of the tested product is measured at the place of its attachment to the suspension. By changing the gain of the additional amplifier 3, adjust the amplitude of oscillation of the carriage 7, equal to the amplitude of oscillations of the test product. As a result of such work of the vibrator, the suspension 6 remains all the time vertical and does not excite vertical vibrations. The length of the suspension is small, and therefore its mass

Q is small. Thus, the effect of the suspension in the proposed device is reduced due to the low weight of the suspension, the absence of its deviation from the vertical.

Claims (2)

1. A vibration table containing an oscillator, an amplifier, a vibrator connected in series, a suspension, characterized in that, in order to increase the accuracy of determining the dynamic characteristics of the test product, carriages are inserted on the rails on which the suspension is fixed, an additional amplifier and an additional vibrator connected in series, an additional amplifier is connected to the oscillator, an additional vibrator is connected to the carriage. 2. A vibration stand according to claim 1, characterized in that, in order to improve accuracy, when testing non-linear structures, a vibration sensor is inserted into it, fixed at the point of attachment of the test product to the suspension, connected through an additional amplifier and an additional vibrator with a carriage. f (1.2.1