SU1276951A1 - Method for determining the damping of elastic vibrations in material - Google Patents

Abstract

The invention relates to the study of the mechanical properties of materials. The purpose of the invention is to increase the accuracy of determining the damping of vibrations in materials. The method involves the excitation of oscillations in the sample by impact and the comparison of the shock spectra of the excitation pulse and the response of the sample. The indicated spectra are recorded with shock spectrum analyzers having, respectively, band-pass filters with adjustable attenuation and without attenuation. The attenuation of oscillations in the sample material is determined by the attenuation value of the filters of the analyzer of the shock spectrum of the excitation pulse, which ensures the coincidence of the compared shock spectra. The attenuation accuracy of I is improved due to the high destructive power of shock analysis (L spectrum and fine tuning of the analyzer's digital filters on the sample resonance frequencies, 1 sludge.

Description

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Claims (2)

G SP The invention relates to the study of the mechanical properties of materials, and specifically to methods for determining the damping of vibrations in materials. The purpose of the invention is to improve the accuracy of determining the attenuation of oscillations in a material. The drawing shows a block diagram of a device for determining the attenuation of oscillations in a material. The device contains a drummer for initiating elastic oscillations in the material of sample 2, on the surface of which from the side of the drummer 1 and on the surface opposite to the drummer 1 there are transducers 3 and 4, respectively, of the excitation pulse and response of sample 2. The transducer 4 is switched on through matching amplifier 5 and filter block 6 low frequencies to the signal input of the analyzer 7 of the shock spectrum, having a band-pass filter without attenuation, the output of which is connected to the first input of the subtraction unit 8, the output of which is connected to the input The converter unit 9, the display 3 is connected via a matching amplifier 10, block II and the memory unit 12 filters the low hour to 3 impactor spectrum analyzer having a bandpass filter with adjustable damping vghod which is connected to the second input of the subtractor 8 block. The device also contains a trigger 14, the first output of which is connected to the control input of the memory block 11, and the second output - to the control input of the shock spectrum analyzer 7, to the first control input of the shock spectrum analyzer 13 and to the control input of the B subtractor and block 15 of settings, the output of which is connected to the second control input of the analyzer 13 of the shock spectrum. The method is carried out as follows. With the help of a hammer in sample 2, oscillations are excited with a single pulse, and with the help of transducers 3 and 4, the excitation and response pulses of sample 2 are converted into electrical signals. The signal from the converter 3 is amplified by the matching amplifier 10 and is fed to the input of the memory unit II. The signal of converter 4 is amplified by matching amplifier 5 is limited by the width of the spectrum by a block of 6 low-pass filters and is subjected to spectral analysis by a shock spectrum analyzer 7, the output of which forms a shock spectrum at zero value of the analyzer filter attenuation coefficient. The signal from the output of the setting block I5 is manually set the value of the attenuation coefficient of the band-pass filters of the analyzer 13 of the shock spectrum. The signal from the Start button, which enters the counting input of the trigger 14, sets a high level at its first output, which reads the excitation pulse from the memory block 11, restricts the width of the spectrum in the low-pass filter block 12 and then produces a spectral Analyzes analyzer 13 shock spectrum. As a result of transferring the trigger 14, a high level is established at its second output, according to which the shock spectrum analyzers 7 and 13 synchronously enter and subtract in the subtraction unit 8 the shock spectra of the response and the excitation pulse, respectively, and the result is fed to the input of the display unit 9, where the result is recorded comparing the response spectrum recorded at zero attenuation of the filters of the analyzer 7 of the shock spectrum with the excitation spectrum at the decay fi set with the help of block 15 of settings ltrov analyzer 13 shock spectrum. If the difference in the shock spectra differs from the straight line with a zero level from the output of the setpoint block 15, a new value of the attenuation coefficient is set for the band-pass filters of the shock spectrum analyzer 13, and the Start button is re-read from the memory I1 of the pulse signal, measurement of its shock spectrum and comparison of the obtained spectrogram with the shock spectrum at the output of the analyzer 7 of the shock spectrum. With the coincidence of the shock spectra of the excitation pulse and the output response of the subtraction unit 8, the selected value of the attenuation coefficient of the band filters of the analyzer 13 of the shock spectrum corresponds to the attenuation coefficient of elastic oscillations in the sample material 2. The invention improves the measurement accuracy of damping and elastic oscillations in the material due to the reduced scatter due to more accurate tuning of the digital filters of the shock spectrum analyzer to the frequencies of the sample resonators and in their surroundings due to the choice of arbitrary resolution within an arbitrary range. low resolution. Claims A method for determining the damping of elastic oscillations in a material that excites oscillations with a single pulse in a sample of material under investigation and records the parameters of the excitation pulses and the response of the sample, characterized in that, to improve accuracy, the shock spectra of the excitation pulse and the response of the sample are recorded shock spectrum analyzers having respectively band-pass filters with adjustable attenuation and without attenuation compare the response spectrum with the spectra of the excited pulses At different fixed values of the damping, and the damping of oscillations in the sample material is determined by the filter damping value, at which the shock spectra of the excitation, day and response pulses coincide.