RU2018141664A - METHOD OF VIBROACOUSTIC TESTS OF SAMPLES AND MODELS - Google Patents

Claims (15)

The method of vibro-acoustic testing of samples and models, which consists in the fact that on the base, on which, through at least three vibration isolators, a bulkhead is fixed, which is a single-mass oscillatory system of mass and stiffness, respectively, m ₂ and c ₂ , an eccentric oscillator is used as a harmonic oscillation generator a vibrator located on the bulkhead, on the bulkhead, a rack is installed to test the natural frequencies of the elastic elements of spring and plate vibration isolators of different lengths, geometric parameters, and also different masses attached to the ends of these test elements, while the mass fluctuations are fixed on each elastic element, they are fixed by a displacement indicator, according to the readings of which a resonance frequency corresponding to the parameters of each elastic element is determined, and vibration acceleration sensors are fixed on the base and bulkhead, the signals from which are sent to an amplifier, then an oscilloscope, a magnetograph and a computer ter to process the information received, in this case, a frequency meter and a phase meter are used to set up the stand, and to determine the eigenfrequencies of each of the studied vibration isolation systems, shock impulse loads are imitated on each of the systems and waveforms of free vibrations are recorded, the decoding of which determines the natural frequencies of the vibration isolation systems and the logarithmic decrement of oscillation attenuation by the formula:

where c ₁ and m ₁ are respectively the stiffness of the elastic elements of the vibration isolators and the mass of the base, c ₂ and m ₂ are the stiffness and mass of the bulkhead, respectively, h ₁ is the absolute value of viscous damping in the system, which is associated with the logarithmic attenuation coefficient δ _{1 of the} oscillatory system, this sound power level L _p is determined by measuring the average sound pressure level L _cf on the measuring surface S, m ² , for which the hemisphere area is taken:

where S = 2πr ² ; r is the distance from the center of the source to the measurement points; S ₀ = 1 m ² and the corrected sound power level L _pA :

where L _Acr is the average sound level on the measuring surface, while the magnitude of the decrease in sound pressure level ΔL in the reflected sound field of the sample is calculated by the formula:

where L is the sound pressure level at the design point before the acoustic treatment of the room, dB; L _region - sound pressure level at the design point after acoustic treatment of the room, dB; where B is the constant cabin of the vessel before its acoustic treatment, m ² ; In ₁ - the constant of the room after its acoustic treatment, m ² , which is determined by the formula:

where A ₁ = α (S _total -S _region ) is the equivalent area of sound absorption by surfaces not occupied by sound-absorbing lining; α = B / (B + S _total ) - the average coefficient of sound absorption in the room before its acoustic processing; α ₁ - the average coefficient of sound absorption of an acoustically treated room, determined by the ratio

ΔA is the value of the total additional absorption introduced by the design of the sound-absorbing cladding or piece sound absorbers, determined by the formula:

where α _reg - reverberation coefficient of sound absorption of the cladding; S _region - the area of this structure, m ² ; And _pcs - the equivalent sound absorption area of one piece absorber, m ² ; n is the number of piece sound absorbers in the room, characterized in that on each of the studied elastic elements of different lengths, geometric parameters, and also different mass values, strain gauges are fixed at the ends of these tested elements, while the oscillations of the mass attached to each elastic element are fixed as an indicator of displacements, and strain gauges, moreover, according to the indications of the indicator, an express assessment of the characteristics is carried out, and when processing signals from strain gauges entering the amplifier, then the oscilloscope, magnetograph and computer for processing the received information determine the amplitude-frequency characteristics and identify optimal characteristics : stiffness and damping coefficient of each of the elastic elements.