SU1549554A1 - Installation for degassing fluid of hydraulic system - Google Patents

Abstract

The invention relates to the operation of hydraulic systems. The purpose of the invention is to expand the functionality of the installation. When a liquid (G) enters the installation, part G is sucked out of the pre-filled degassing tank (GH) 1 with ejector 5 into the hydraulic tank 8. Simultaneously, GF 1 from line 7 starts through GHD 6. is continuously removed to the compensation tank 20, compressing the bellows 21 connected to the piston 22. The DE 1 is evacuated, the vacuum is regulated by the throttle 6. The air released in the DE 1 accumulates in the accumulator 2 and is periodically removed from it through the valve 19 to the atmosphere 3 by means of the plunger 12. The periodicity of the removal of air from the accumulator 2 is ensured by means of the distributor 134, level sensors 17, 18 and 24 and springs 15 and 16. The difference in volumes removed and supplied to the DE 1 that occurs when air is removed from accumulator 2 displacing the bellows 21 with a piston 22 W from the compensation tank 20. 1 sludge.

Description

The invention relates to the operation of hydraulic systems, namely, devices for removing air from a liquid in hydraulic systems.

The purpose of the invention is to expand the functionality of the installation.

The drawing shows a schematic diagram of an installation for degassing a liquid.

The installation contains a degassing tank 1 with a cylindrical tank 2, in which a piston 3 is installed. In the piston 3 there is a central hole 4 connecting the degassing tank with the tank 2. The degassing tank 1 is connected to the suction channel of the ejector 5 and through an adjustable choke 6 to the input of this ejector . The ejector 5 is installed on line 7, through which the drain flow of the hydraulic system 9 fed by the pump 10 passes into the hydraulic tank 8. In the bottom wall of the degassing tank 1 there is a cylindrical guide 11 in which the plunger 12 is installed. The lower end of the plunger is connected through an electromagnetic distributor 13 to the suction the ejector channel 5 and with its entrance. In the hydroline connecting the end of the plunger 12 to the suction channel of the ejector 5, a throttle 14 is installed. Elastic elements in the form of springs 15 and 16 are located between the upper wall of the accumulator 2 and the piston 3, as well as between the plunger 12 and the piston 3 Vessels 1 contain level sensors 17 and 18. A valve 19 for air venting is built into the upper wall of accumulator 2. To the output of the ejector 5 is connected compensatory capacitance 20 with the bellows 21. placed in it. One of the ends of the bellows 21 is tightly connected to the wall of the reservoir 20, and the other with the piston 22. The inner cavity of the bellows 21 is connected to the atmosphere. In the cavity of the bellows 21 between the wall of the container 20 and the piston 22, an elastic element 23 is mounted. In the cavity of the bellows there is a sensor 24 for positioning the piston 22.

In the closed-type hydraulic system, the installation operates as follows.

The degassing tank 1 with accumulator 2 together with the hydraulic system 9 is completely completely filled with liquid up to the required pressure in the hydraulic tank 8 of the hydraulic system 9. At the same time, the pressure of the liquid on the piston 22 is balanced by spring force 23 so that after charging the installation with fluid the bellows 21 is in an undeformed state nii. When the working fluid from the hydraulic system 9 enters the inlet of the ejector 5, part of the liquid from the pre-filled degassing tank 1 is sucked out by the ejector 5 into the hydraulic tank 8. As a result, the pressure increases at the outlet of the ejector 5. Under the action of increased pressure, the bellows 21 is compressed

and the excess fluid entering the hydraulic system due to the fluid from the degassing tank 1, is discharged into the compensation tank 20. At the same time, the pressure at the ejector outlet increases by an amount which is not essential for the operating mode of the ejector 5.

As a result of the ejection of fluid from the vessel, the pressure in the latter drops. At the same time, in the tank 1, air begins to be released from the fluid filling it, which flows through the opening 4 into the accumulator 2 and accumulates under its upper wall. Simultaneously with the ejection of the sf of the degassing tank 1, the liquid from the line 7 through the adjustable throttle 6 begins to flow into it. At a certain value of the vacuum in the tank 1, the amount of liquid ejected and supplied to the tank 1 is balanced. As work goes on, drive 2 begins to fill with air,

0 released from the liquid, and the compensation tank 20 is filled with the appropriate amount of liquid. When the piston 22 reaches the level of the sensor 24 corresponding to the full filling of kakopitel 2 with air, the distributor 13 switches to a position that informs the lower end of the plunger 12 with the ejector inlet 5. Under the action of overpressure, the plunger 12 moves upward, overcoming the force of the spring 16, and rests

Into the piston 3, blocking the opening 4. Under the action of the plunger 12, the piston 3 begins to move upwards, overcoming the force of the spring 15. At the same time, the air in the accumulator 2 is forced out through the valve 19 into the atmosphere. At the same time with

By this, due to the flow of fluid from the hydraulic system under the plunger 12, the pressure at the outlet 5 drops. This causes the bellows 21 of the piston 22 to move downwards. The volume of liquid displaced in this case from tank 20 provides compensation for the additional volume of fluid supplied from the hydraulic system under the plunger 12 and into the degassing tank 1 to remove the released air.

5 In the process of removing air from the accumulator 2, the evacuation of the liquid in the tank 1 continues. When the piston 3 reaches the level of the sensor 17, the electric control system switches the distributor 13 to its original position.

0 Under the action of the spring 16, the plunger 12 moves away from the piston 3, opening channel 4. The piston 3 and plunger 12 return to their original position under the action of springs 15 and 16. At the same time, the throttle 14 ensures smooth movement of the plunger 12, protecting it

5 from hitting the bottom wall of the tank 1, and the air released in the degassing tank 1 during the period of removing the air from the accumulator 2, together with the liquid from the upper

layers in the tank 1 enters through the hole 4 into the drive 2. The cycle is repeated.

In an open-type hydraulic system, the installation operates in the same way, except for the work of the compensation capacitance 20 with the bellows 21 and piston 22, which, due to the absence of pressure changes at the outlet of the ejector 5 in this case, will not function. The function of sensor 24 will then be performed by sensor 18.

Supply of the installation with a compensation tank with bellows and a piston located in it, connected from the outside of the bellows to the ejector outlet, and from the inner surface of the bellows to the atmosphere, allows maintaining a constant volume of fluid in the hydraulic system by supplying excess hydraulic volume to the hydraulic system ejected from the degassing tank, or discharge from it into the hydraulic system of the fluid volume. required to fill the storage device when removing the evolved gas from it. The supply of an elastic element installed in the cavity of the bellows between the vessel wall and the piston provides compensation

0

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five

When selecting C and S of a certain value, the value of the value of AP will be insignificant for the operation mode of the ejector unit.

Supplying the installation with a position sensor to a piston located in the cavity of the bellows allows controlling the position of the valve of the distributor according to the volume of the liquid that has entered the cavity of the compensation tank.

All this ensures that the pressure of the ejector is almost unchanged during the operation of the installation in a closed-type hydraulic system and, therefore, it is possible to maintain a vacuum in the degassing tank to release the volume under the evolved air in it, and hence the fluid degassing in such a hydraulic system.

Claims (1)

Invention Formula Installation for degassing a hydraulic fluid containing a degassing tank connected to the ejector via an electromagnetic distributor, directed the force of fluid pressure on the piston 25, which contains the plunger. at the initial pressure at the outlet of the ejector. This allows you to ensure the non-deformed position of the bellows in the absence of liquid ejection from the degassing tank a cylindrical accumulator with a piston connected to a degassing tank, elastic elements and two level sensors located in a degassing tank and a storage device, characterized in that bellows deformation to compensate for the expansion of functionality, The installation is equipped with a compensation capacitance, inside which there is a piston sylph, an elastic element installed between the upper wall of the container and the piston, and a piston position sensor, at 35 this bellows is connected to the wall of the container, its internal cavity is in communication with the atmosphere, the cavity of the container on the outer side of the bellows, it communicates with the ejector outlet, and the piston position sensor is connected to the liquid electroma that is ejected into the hydraulic system from the degassing tank. In the process of compensation, the pressure at the outlet of the ejector changes by the value of AR: & P kW-C / S where AW is the change in the volume of fluid in the compensation tank; C is the stiffness of the bellows with a spring; effective bellows area. about magnet distributor. a cylindrical accumulator with a piston connected to a degassing tank, elastic elements and two level sensors located in a degassing tank and a storage device, characterized in that  extending functionality