SU565135A1 - Mechanical vibration hydraulic damper - Google Patents

Description

one

The invention relates to vibration damping and can be applied in distribution units of hydraulic machines.

A vibration damping device is known that contains a resonator of adjustable volume, made in the form of a cylinder, a piston located in it, a regulator controlling the movement of the piston connected to the cylinder, and a pipeline of adjustable length connecting the resonator with the valve of the hydraulic distributor 1. Periodically occurring pressure pulsations in the distributor oscillations of pressure in the resonator, which will be dephased relative to the pressure pulsations, are excited.

A disadvantage of the known device is the complicated mechanism for regulating the monitoring of the working pressure of the hydraulic machine and large dimensions.

The closest in technical essence to the proposed device is a hydraulic vibration damper of mechanical vibrations, comprising a housing with pressure and discharge channels made therein, a nozzle-flap element located in the housing and a movable element controlling it, dividing the housing into a cavity located under it, connected to the discharge channel, and the cavity located above it 2.

This vibrator does not reduce the level of vibration of hydraulic machines in transient conditions with varying pressure. The purpose of the invention is to reduce the level

vibrations of hydraulic machines in transient conditions with varying pressure. This goal is achieved by the fact that the vibration damper is equipped with a compensator, which forms the side of the cavity opposite to the movable element located above the movable element and the throttle connecting this cavity with the inlet channel.

The drawing shows the described hydraulic vibration damper, longitudinal section.

In the housing 1 of the inhaler, the injection and discharge channels 2 and 3 are made. The pressure channel 2 enters the nozzle 4. Above the nozzle there is a nozzle chamber 5, from which

A discharge channel 3 comes out. A damper 6 is located above the nozzle and is connected to a movable element in the form of a piston 7. The piston is placed in a chamber 8, which it divides into a cavity 9 located under it and connected by a channel 10 with an injection channel, and a cavity located over it. In the over-piston cavity there is a compensator, which is an elastic membrane 11. A shank of a piston 12 with a diameter equal to the diameter of the valve for leveling the upper and lower areas is rigidly fixed to the membrane. The membrane 11 divides the sub-piston cavity into two parts. The lower part 13 of the piston cavity is connected by a channel 14, in which there is a throttle 15, with an injection channel 2. The upper part 16 of the piston cavity is filled with compressible gas, such as air, and is closed with a stopper 17. In the subshell and supra piston cavities there are springs 18 and 19 stabilizing piston position

During the operation of the hydraulic machine, pressure pulsation of the working fluid occurs, which causes vibration. The delivery channel 2 is connected to the hydraulic cavity of the distributor. As a result of the pressure pulsation, the piston 7 comes into oscillatory motion; the change in the hydraulic resistance of the nozzle element occurs — the damper is in phase with the rise and fall of the average value of the working fluid pressure.

When the pressure increases, the piston 7 with the valve 6 moves upwards and opens the nozzle 4, and as the pressure decreases, the piston 7 with the valve 6 moves downwards and covers the nozzle 4. This oscillatory movement leads to a smoothing of the pressure pulsations of the working fluid in the delivery channel 2 and, therefore, switchgear and to reduce the vibration of the entire hydraulic machine.

In order to ensure the operability of the device at various average pressure values, a hydraulic piston cavity is provided in the hydraulic machine. The pressure pulsations pass through the channel 14 through the choke 15, the parameters of which are chosen in such a way that the pressure pulsations, falling into the over-piston cavity, smooth and dephase to the pressure pulsations in the piston cavity.

With periodic oscillations of the piston 7 under the action of pressure pulsations, the membrane 11 bends due to the compressibility of air in the upper part of the piston cavity, which creates conditions for the movement of the piston.

Claims (2)

1. "Axial-piston adjustable hydraulic drive, ed. In, N. Prokofiev, M, Mashinostroenie, 1969, p. 404. 2. The copyright certificate number 260327, cl. F 16 F 15/04, 1968. P // / 13