RU2558678C1 - Test rig to study impact loads of vibration insulation systems - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: test rig contains a base, on which additional plates with secured vibration insulation devices, and registering device are located. On base the aircraft devices are installed, for example, two similar onboard compressors for compressed air production on board of the aircraft, at that one compressor is installed in standard rubber vibrator isolators, and another compressor is installed on tested two-weight vibration insulation system. This system comprises rubber vibrator isolators and elastic deformation intermediate plate with the vibrator isolators, for example, in form of polyurethane plates, that similar to the standard rubber vibrator isolators of the compressor are installed on rigid partition, that via the shock-absorbing gasket is installed on the base. On the rigid partition between the compressors the vibration detector is installed its signal enters the amplifier and registration devices, for example octave spectrometer operating in frequency band. At that the obtained amplitude-frequency characteristics due to each compressor operation are compared, and conclusions are made on the vibration insulation efficiency of each system, on which they are installed.

EFFECT: extension of process possibilities of testing of the objects having several elastic constraints with hull structures of the aircraft.

2 cl, 5 dwg

Description

The invention relates to test equipment.

The closest technical solution to the technical nature and the achieved result is a vibration stand according to the patent of the Russian Federation No. 2335747, G01M 7/08, G01N 3/313, containing bases, protected object, measuring equipment and vibration and shock generators (prototype).

The disadvantage of the prototype is the relatively low capabilities and accuracy for the study of systems having several elastic connections with the hull parts of an aircraft.

A technically achievable result is the expansion of the technological capabilities of testing objects that have several elastic connections with the hull parts of an aircraft.

This is achieved by the fact that in the stand for studying the shock loads of vibration isolation systems, containing a base on which additional plates with vibration-insulated devices are mounted, and recording equipment, aircraft equipment is installed on the base, for example, two identical on-board compressors for receiving compressed air on on board the aircraft, while one compressor is installed on standard rubber vibration isolators, and the other compressor is installed on the two-mass the vibration isolation system, which includes rubber vibration isolators and an elastic damping intermediate plate with vibration isolators, for example in the form of polyurethane plates, which, like the standard rubber compressor vibration isolators, are mounted on a rigid bulkhead, which is mounted on the base through a vibration-damping pad and on a rigid one to the bulkhead, between the compressors, a vibration sensor is fixed, the signal from which is fed to the amplifier and recording equipment, for example, an octave spectrometer operating in the frequency band (Hz) : 2; four; 8; 16; 31.5; 63; 125; 250; 500; 1000; 2000; 4000; 8000 Hz, and then compare the obtained amplitude-frequency characteristics from the operation of each of the compressors and draw conclusions about the effectiveness of vibration isolation of each system on which they are installed.

In FIG. 1 shows a general view of the shaker, in FIG. 2 is a circuit diagram thereof, in FIG. 3 is a mathematical model of the system “compressor 2 on a two-mass vibration isolation system”, FIG. 4 - characteristics of the logarithmic damping decrement of free vibrations of a two-mass vibration isolation system depending on the input shock pulse, in FIG. 5 is a diagram of a diagnostic shock device.

The stand for the study of shock loads of vibration isolation systems (Fig. 1) consists of a base 12 on which the aircraft equipment is installed, for example, two identical on-board compressors 1 and 2 for receiving compressed air on board the aircraft. In this case, one compressor 1 (Fig. 2) is installed on standard rubber vibration isolators 7, and another compressor 2 is installed on the studied two-mass vibration isolation system, including rubber vibration isolators 5 and an elastic damping intermediate plate 4 with vibration isolators 6, for example, in the form of polyurethane plates, which, like the standard rubber vibration isolators 7 of the compressor 1, are mounted on a rigid bulkhead 8, which is mounted on the base 12 through the vibration damping pad 11. FIG. 3 shows a mathematical model of a two-mass system "compressor 2 on the intermediate plate 4 with vibration isolators 5 and 6",

where c ₁ and m ₁ - respectively, the stiffness of the elastic elements of the plate 4 and its mass,

where c ₂ and m ₂ - respectively, the stiffness of the vibration isolators 5 and the mass of the compressor 2,

h ₁ - the absolute value of viscous damping in the system, which is associated with the logarithmic attenuation coefficient δ _{1 of the} oscillatory system by the following dependence (1):

On a rigid bulkhead 8, between the compressors 1 and 2, a vibration sensor 3 is fixed, the signal from which is fed to the amplifier 10 and then to the oscillation recording apparatus 9, for example, an octave spectrometer operating in the frequency band (Hz): 2; four; 8; 16; 31.5; 63; 125; 250; 500; 1000; 2000; 4000; 8000 Hz.

The stand for the study of shock loads of vibration isolation systems works as follows.

First, turn on compressor 1, which is installed on standard rubber vibration isolators 7, and take the amplitude-frequency characteristics (AFC) using a sensor 3, amplifier 10 and spectrometer 9. Then turn off compressor 1 and turn on compressor 2, which is installed on the two-mass vibration isolation system under study, including rubber vibration isolators 5 and an elastic damping intermediate plate 4 with vibration isolators 6, and also take the amplitude-frequency characteristics using a sensor 3, an amplifier 10 and a spectrometer 9. Then compare they determine the obtained frequency response from the operation of each of the compressors 1 and 2 and draw conclusions about the effectiveness of vibration isolation of each system on which they are installed. In order to determine the eigenfrequencies of each of the studied vibration isolation systems, they simulate shock impulse loads on each of the systems and record the oscillations of free vibrations (not shown in the drawing), when deciphering which they judge the eigenfrequencies of the systems (see Fig. 4 and the formula ( one)).

The diagnostic impact device (Fig. 5) comprises a quick-change impact element 13 located coaxially to the housing 15 and made of an elastomer, which, by means of the sleeve 30, is attached to the membrane transmission element 14, mounted on the cylindrical housing 15 by means of a flange 28 located perpendicular to the axis of the housing 15, using screws 29. Inside the housing 15 and coaxially to it is located a membrane transmitting element 14, which has a cylindrical-conical part installed in the housing with a toroidal gap 27 in the lower part having petal shape in cross section of a toroidal surface. The membrane transmitting element 14 is connected by a threaded part 26 of the pin 25 located along the axis of the housing with the main mass 17 of the percussion device in contact with the piezoelectric dynamometer 16 placed in the dielectric protective sheath 34. The voltage arising from shock or accidental impacts is removed from the piezoelectric dynamometer 16 through the contact element 33, mounted in the housing 15, and connected by a wire 36 with the contact element 31, mounted in the hollow cylindrical handle 21 of the percussion device, while d 36 is fixed in the clamp 32, rigidly connected with the outer surface of the handle 21, the axis of which is perpendicular to the axis of the housing 15, and which, through the threaded part 22, is rigidly fixed in the threaded hole 23 of the main mass 17. Above the main mass 17 is an additional mass 18 of the percussion device made in the form of a cylinder, and in which an axisymmetric threaded hole 19 is made, into which the threaded part of the protrusion 20 is included, which is integral with the main mass 17, which, in turn, is fastened by means of screws 24 to the housing 15, and the head of the stud 25 rests on the end surface of the threaded part of the protrusion 20, connecting the main mass 17 of the percussion device with the membrane transmitting element 14 through a piezoelectric dynamometer 16, in which a central axisymmetric hole 35 is made through which the smooth cylindrical part of the stud 25 passes.

Diagnostic shock device operates as follows.

Upon impact on the test surface of the test object (not shown in the drawing) by means of a quick-change shock element 13, impulse or random excitation is simulated. The force applied to the object under study is measured using a piezoelectric dynamometer 16. An additional mass of 6 and the material of the shock part 13 can be used to change the pulse duration, and hence the frequency range of the excitation spectrum. The voltage arising from shock or accidental impacts is discharged from the piezoelectric dynamometer 16 through the contact element 33 fixed in the housing 15 and connected by a wire 36 to the contact element 31 fixed in the hollow cylindrical handle 21 of the percussion device. The signals from the piezoelectric dynamometer 16 are transmitted to a data processing unit (not shown in the drawing), in which the frequency characteristics are obtained using spectral analysis of complex signals, the basis of which is fast Fourier transform, for example, using a two-channel analyzer (not shown), which performs fast the Fourier transform, and measuring the excitation signals from the shock device, and their reactions on the test surface 37 of the investigated object, then determine the frequency characteristics of Based on these measurements.

Claims (2)

1. A stand for studying the shock loads of vibration isolation systems, comprising a base on which additional plates with vibration-insulated devices fixed to them are located, and recording equipment, characterized in that the equipment of the aircraft is installed on the base, for example, two identical on-board compressors for receiving compressed air on on board the aircraft, while one compressor is installed on standard rubber vibration isolators, and the other compressor is installed on the two-mass system under study vibration isolation system, which includes rubber vibration isolators and an elastic damping intermediate plate with vibration isolators, for example in the form of polyurethane plates, which, like the standard rubber compressor vibration isolators, are mounted on a rigid bulkhead, which is installed on the base through a vibration-damping pad and on a rigid bulkhead , between the compressors, a vibration sensor is fixed, the signal from which is fed to the amplifier and recording equipment, for example, an octave spectrometer operating in the frequency band (Hz): 2; four; 8; 16; 31.5; 63; 125; 250; 500; 1000; 2000; 4000; 8000 Hz, and then compare the obtained amplitude-frequency characteristics from the operation of each of the compressors and draw conclusions about the effectiveness of vibration isolation of each system on which they are installed. 2. A stand for studying shock loads of vibration isolation systems according to claim 1, characterized in that for determining the natural frequencies of each of the studied vibration isolation systems, shock impulse loads are simulated for each of the systems using a diagnostic shock device containing a housing, a piezoelectric dynamometer and a shock element , the shock element is made of quick-change, located coaxially to the body, made of elastomer, and by means of a sleeve is attached to a membrane transmitting element fixed to the cylindrical housing through a flange located perpendicular to the axis of the housing, with screws, and inside the housing, and coaxially to it, is a membrane transmitting element that has a cylindrical-conical part installed in the housing with a toroidal gap in the lower part having a petal shape in the cross-section of the torus surface, while the membrane transmitting element is connected by a threaded part of the stud located along the axis of the housing with the bulk of the percussion device in contact with the piezoelectric dynamometer, placed in a dielectric protective sheath, while the voltage arising from shock or accidental impacts is removed from the piezoelectric dynamometer through a contact element fixed in the housing and connected by a wire to the contact element fixed in the hollow cylindrical handle of the percussion device, while the wire is fixed in a clamp, rigidly connected to the outer surface of the handle, the axis of which is perpendicular to the axis of the housing, and which, through the threaded part, is rigidly fixed in the threaded a verst of the main mass, over which the additional mass of the percussion device, made in the form of a cylinder, and in which an axisymmetric threaded hole is made, into which the threaded part of the protrusion, which is integral with the main mass, which, in turn, is screwed to the body, and the head of the stud rests on the end surface of the threaded portion of the protrusion, connecting the bulk of the percussion device with the membrane transmitting element through a piezoelectric dynamometer in which axisymmetric central aperture through which passes a smooth cylindrical portion of the stud.

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