RU2637718C1 - Method for examining dual-mass vibration insulation systems - Google Patents

Abstract

FIELD: testing equipment.

SUBSTANCE: additional plates with vibration-insulated objects attached to them are placed on the base, and recording equipment is adjusted, and two identical on-board compressors are mounted to obtain compressed air on board the aircraft. One compressor is mounted on standard rubber vibration insulators and another compressor is mounted on the examined dual-mass vibration insulation system, consisting of rubber vibration insulators and an elastically damping intermediate plate with vibration insulators, for example, in the form of plates made of polyurethane, which are placed on the rigid bulkhead mounted on the base through the vibration cushioning gasket, as well as the standard rubber vibration insulators. A vibratory sensor is mounted on the rigid bulkhead, between the compressors, a signal from the vibratory sensor is sent to the amplifier and recording equipment, such as octave spectrometer, operating in the frequency band (Hz): 2; 4; 8; 16; 31.5; 63; 125; 250; 500; 1000; 2000; 4000; 8000 Hz, and then the obtained amplitude-frequency operation characteristics of each compressor are compared. Then the conclusions about the effectiveness of vibration insulation of each system on which they are mounted are drawn, and in order to determine the natural frequencies of each of the examined vibration insulation systems, imitation of shock pulse loads on each of the systems is carried out and oscillograms of free vibrations are recorded, while interpreting which natural frequencies of the system and an oscillation damping constant in each of the examined dual-mass vibration insulation systems are assessed.

EFFECT: expanded technological capabilities of testing the objects having several elastic couplings with the body parts of the flying object.

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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 method of studying two-mass vibration isolation systems, which consists in the fact that additional plates with vibration-insulated objects are mounted on the base and the recording equipment is set up, and two identical on-board compressors are installed on the base to receive compressed air on board the aircraft , while one compressor is installed on standard rubber vibration isolators, and the other compressor is installed on the studied two-mass vibration isolation system, including 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 between the compressors on a rigid bulkhead fix the vibration sensor, the signal from which is sent 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 the vibration isolation of each system on which they are installed, and to determine the natural frequencies of each of the studied vibration isolation systems, shock impulse loads on each of the systems are simulated and oscillograms of free oscillations are recorded, when decrypted, they judge the eigenfrequencies of the system and the logarithmic decrement of damping of oscillations of each of the two mass vibration isolation system.

In FIG. 1 shows a general view of a device (vibration stand) for implementing the method, 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.

A device for implementing the method of research of two-mass 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 equipment 9 registering the vibrations, 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.

A device for implementing the method of research of two-mass vibration isolation systems works as follows.

The compressor 1 is turned on, which is installed on the standard rubber vibration isolators 7, and the amplitude-frequency characteristics (AFC) are taken using a sensor 3, an amplifier 10, and a spectrometer 9. Then, the compressor 1 is turned off and the compressor 2 is turned on, which is installed on the two-mass vibration isolation system, including include 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 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 oscillations of free vibrations (not shown), when deciphering them, they judge the eigenfrequencies of the systems (see Fig. 4 and formula (1)) .

The method of research of two-mass vibration isolation systems is 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 vayut received from the AFC operation of each of the compressors 1 and 2, and conclusions are drawn about the effectiveness of each vibration isolation 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 oscillations of free vibrations (not shown), when deciphering them, they judge the eigenfrequencies of the systems (see Fig. 4 and formula (1)) .

It is possible that the amplitude-frequency characteristics are pre-recorded from the operation of each of the compressors 1 and 2 in turn, when installed on the base 12, and then when they work together, after which the compressors 1 and 2 are mounted on a rigid bulkhead 8 through a vibration damping pad 11 and repeat the recording cycle of the amplitude-frequency characteristics when the compressors work in turn, and when they work together, and according to the results of the recording processing, the vibration-damping properties of the gasket 11 are evaluated between the rigid bulkhead th 8 and base 12.

Claims (1)

A method for studying two-mass vibration isolation systems, namely, that vibration-insulated objects are fixed on the base and the recording equipment is set up, two identical on-board compressors are installed on the base to receive compressed air on board the aircraft, with one compressor installed on standard rubber vibration isolators and the other the compressor is installed on the studied two-mass vibration isolation system, including rubber vibration isolators and an elastic damping intermediate a 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 a vibration sensor is fixed on the rigid bulkhead between the compressors, the signal from which sent 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 the vibration isolation of each system on which they are installed, and to determine the eigenfrequencies of each of the studied vibration isolation systems, shock impulse loads on each system are simulated and oscillograms of free oscillations are recorded, when decrypted, they judge the eigenfrequencies of the system and the logarithmic decrement of damping of oscillations of each of the studied two Khmass vibration isolation system, characterized in that the amplitude-frequency characteristics are pre-recorded from the operation of each of the compressors in turn, when installing them on the base, and then when they work together, after which the compressors are installed on a rigid bulkhead through a vibration-damping pad and the amplitude-recording cycle is repeated frequency characteristics during the operation of compressors in turn, and during their joint operation, and according to the results of processing the records, the vibration damping properties of the gasket between rigid bulkhead and base.

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