RU2017102541A - STAND FOR RESEARCH OF SHOCK LOADS OF VIBROINSULATION SYSTEMS - Google Patents

Claims (1)

A stand for studying the shock loads of vibration isolation systems, containing a base on which additional plates with vibration-insulated devices fixed to them and recording equipment are located, 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 board the aircraft , while one compressor is installed on standard rubber vibration isolators, and the other compressor is installed on the studied two-mass system vibration isolation, 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 installed on a rigid bulkhead, which is installed on the base through a vibration-damping pad, and between the compressors on a rigid bulkhead , 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 the vibration isolation of each system on which they are installed, while to determine the natural frequencies of each of the studied vibration isolation systems, shock impulse loads are simulated for each of systems using a diagnostic shock device containing a housing, a piezoelectric dynamometer and a shock element, the shock element is made quick-change, located coaxially the housing is made of elastomer, and by means of a sleeve is attached to a membrane transmitting element mounted on a cylindrical housing by means of a flange located perpendicular to the axis of the housing, using screws, and inside the housing and coaxially located there is a membrane transmitting element that has a cylindrical-conical part mounted in a housing with a toroidal gap in the lower part, having a petal shape in cross section of a toroidal surface, while the membrane transmitting element is connected by a threaded part of the stud, located laid 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 an 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 is rigidly fixed by means of the threaded part in the threaded hole of the main mass, over which the additional mass of the percussion device, made in the form of a cylinder, and in which the axisymmetric threaded hole is made, into which the threaded part of the protrusion is integral with the main mass, which, in turn, is screwed to the body, and the head of the stud connecting the main mass abuts against the end surface of the threaded portion of the protrusion su percussion device with a membrane transmitting element through a piezoelectric dynamometer, in which a central axisymmetric hole is made through which a smooth cylindrical part of the stud passes.