RU1817068C - Liquid pressure regulator - Google Patents

Abstract

The invention relates to automatic control technology and can be used in industrial and municipal water supply systems. The purpose of the invention is to increase the sensitivity and reliability of the regulator. The pressure regulator through the pipe 8 delivers compressed air to the elastic sleeve 6, where the pressure required in the output pipe is 1619 t 3. The piston 5 is positioned at the restrictor 10. When the pressure of the liquid increases in the area of the output pipe 3, this pressure is transmitted through the bypass pipe 13 into the cavity 11. Due to the pressure difference in the cavity 11 and in the elastic sleeve 6, the piston 5 moves towards the cover 7. The movement of the piston 5 towards the cover 7 is transmitted until the fluid pressure in the outlet pipe 3 and the air pressure in astichnom sleeve 6 are not balance. The rod 14, rigidly connected to the piston 5, with the help of the handle 16 will rotate the regulating body - the disk 17. When the pressure in the nozzle 3 decreases, the compressed air moves the piston 5 towards the end 12. The regulating body opens. To reduce the rotational forces of the regulator 17, its axis 19 is offset from the axis of the pipeline. 2 ill. 77 3 SL S

Description

The invention relates to an automatic control technique and can be used in industrial and municipal water supply systems. A pressure regulator is known in which a part of the cross-section of the pipe is blocked by an actuator in the form of a plate that is deployed across the flow. To turn the plate, great efforts are required, and therefore this device has low sensitivity.

The aim of the invention is to increase the sensitivity and reliability of the regulator,

In FIG. 1 shows a pressure regulator, section; in FIG. 2 - also, a top view.

The pressure regulator has a cylindrical body 1 and inlet 2 and output 3 nozzles, an actuator with a pressure transducer 4 in the form of a sealed vessel with a piston 5 and an elastic sleeve 6, which is attached to the piston 5 at one end and the cap on the other, Inside sleeves 6 through the pipe 8 air is pumped.

The air pressure is controlled by a pressure gauge 9. The upper position of the piston 5 is fixed by the stop 10. The cavity 11 between the upper end 12 of the pressure sensor 4 and the stop 10 is connected by the bypass pipe 13 to the outlet pipe 3 of the pipeline. The rod 14c is rigidly connected on one side to the piston 5, and on the other, by means of a hinge 15, to the handle 16 of the regulating disc 17. regulatory authority 17.

The device operates as follows.

By the pressure transmitter (compressor, pump, etc.), compressed air is supplied through the nozzle 8 to the elastic sleeve 6, where the pressure required in the outlet nozzle 3 is created. The piston 5 occupies a position at the restrictor 10. With increasing liquid pressure in the area of the outlet nozzle 3, this pressure is transmitted through the bypass pipe 13 to the cavity 12. Due to the pressure difference in the cavity 11 and the elastic sleeve

6, the piston 5 moves towards the cap 7. The movement of the piston 5 toward the cap

7 will be transmitted until the fluid pressure in the outlet pipe 3 (and therefore also in the cavity 12) and the air pressure in the elastic sleeve 6 are not balanced. The piston 5 will occupy the position shown in Fig. 1 by a dotted line. The rod 14 is rigidly connected to the piston 5, with the help of the handle 16 will rotate the regulating element 17. At the boundary position of the piston 5, the regulating body 17 will completely block the pipeline section. This state will be until the pressure at the outlet pipe 3 drops below a predetermined value. When the pressure in the nozzle 3 (and, consequently, in the cavity 11) decreases, the compressed air in the elastic sleeve will move the piston 5 towards the end face 12. The regulating body 17 opens. To reduce the turning forces of the adjusting element 17, its axis 19 is offset relative to the axis of the pipeline.

The use of a separate pressure regulator with a cross-section, which can significantly differ from the cross-section of the pipeline, allows to obtain large forces sufficient to move the control

body. The rod connected to the pressure adjuster is connected to the regulating element through a rotary handle; the moment of force increases, which reduces the force required for regulation. In addition, the rotary axis of the control element is offset relative to the axis of the pipeline, which also reduces the forces and, therefore, increases the sensitivity of the regulator. No adjustment

by the magnitude of the inlet pressure, and by the magnitude of the outlet, which increases the reliability of the regulator and pipelines.

Technical and economic advantages compared with the prototype consist in increasing the sensitivity of adjustment and increasing the reliability of piping networks.

Claims (1)

Formula of the invention A fluid pressure regulator comprising a cylindrical housing with inlet and outlet nozzles in which a regulating member is mounted in the form of a disk mounted on an axis perpendicular to the axis housing, actuator and pressure sensor, characterized in that, in order to increase the sensitivity and reliability of the regulator, the axis of the disk is offset from the axis of the housing, the mechanism and pressure regulator are made in the form of a sealed vessel with a piston and an elastic sleeve, the piston is connected by a rod passing through the gland in the sealed vessel, with a rotary handle of the disk, the cavity between the sealed vessel and the piston is connected by a bypass tube to the outlet pipe, and the cavity of the elastic sleeve is a pressure setting cavity, FIG. I