RU21095U1 - FLOW REGULATOR - Google Patents

Abstract

A flow regulator comprising a housing comprising a cylindrical perforated portion serving as a guide during movement of a slide valve with a multi-bucket sail, o-rings, return spring, adjusting nuts, clamps, characterized in that the cylindrical perforated guide is fixedly connected to the housing, and the o-rings are mounted on the piston part spool with the ability to tighten to the body with a stream of contained fluid in the closed position of the flow regulator.

Description

The utility model relates to means for regulating the pressure flow of a liquid (water, oil, oil products) passing through measuring instruments in systems and pipelines.

Known membrane flow regulator / 1 /, comprising a valve body, a membrane body and a membrane cover interconnected, a valve associated with the membrane and the stem. A latch is mounted on the membrane cover, inside of which there is a movable sleeve having annular grooves for balls.

The balls are pressed against the sleeve using a spring and rods. The pressure force of the balls is regulated by compression of the spring using nuts. A plate is supported on the sleeve, through which a spring presses the sleeve against the stem. The rod serves to transfer the force of the membrane to the sleeve.

The increased pressure acts under the membrane, as a result of which the force is transmitted through the rod and plug to the sleeve, which is held in its original position due to the force of the spring and the balls of the upper clamps. When the pressure drop between the inlet and outlet cavity reaches 0.08-0.12 MPa, the pressure drop exceeds the force of the spring and clamps, as a result of which the balls are squeezed out and the system - valve - stem - membrane - rod - sleeve - moves up to landing the lower ball in the lower annular groove of the sleeve, the valve opens.

When the pressure drop decreases, the force exerted on the membrane from below decreases, therefore, the spring force exceeds the total force created by the pressure drop and the holding force of the clamps, as a result of which the balls are squeezed and the valve closes due to the spring force, and the upper clamp balls fall into the upper annular sleeve groove.

A disadvantage of the known device is that with a sharp increase in pressure, a rupture of the membrane occurs.

The closest technical solution to the claimed solution is a flow regulator 121, comprising a housing, a perforated guide, a spool with o-rings and a multi-bucket sail, inside the spool there is a control spring, clamps

open and closed position mounted on the housing. The balls of the clamps are pressed against the cylindrical surface of the piston using springs through the rod. The pressure force of the balls is regulated by compression of the springs using nuts. Six sails mounted coaxially inside the spring are designed to hold the piston open due to the energy of the fluid flow through the regulator. In the initial, closed, position, the piston is held by the force of the spring and the balls of the lock of the closed position. When the pressure difference at the inlet and outlet of the regulator reaches the value specified by the spring and the balls of the latches of the closed position, the piston moves and opens the regulator valve, while the energy of the fluid flow through the windows of the cylindrical piston moves the piston to the open position by means of sails and sets it on the open lock provisions. The regulator valve in this position is fully open. As the pressure drop at the inlet and outlet decreases, the total force acting on the piston and sails decreases from the fluid flow and from the open position lock to values less than the return spring force, the piston moves to the closed position and is installed on the closed position lock. The adjustment of the differential pressure for opening and closing the regulator valve is carried out with the help of nuts by loosening or pulling the retainer springs.

The disadvantage of this regulator is the lack of reliability of the seal between the housing and the piston, which leads to its rapid wear, and replacement of the seal is possible only when the device is completely disassembled.

The objective of the proposed technical solution is to increase the reliability and durability of the regulator.

A flow regulator is proposed comprising a housing comprising a cylindrical perforated portion serving as a guide during movement of a slide valve with a multi-bucket sail, o-rings, return spring, adjusting nuts, clamps, characterized in that the cylindrical perforated guide is fixedly connected to the housing, and the o-rings are mounted on the piston parts of the spool with the ability to be pressed against the body by the flow of the possessed fluid in the closed position of the flow regulator.

The proposed design of the flow regulator can improve reliability and durability due to the fixed connection of the perforated guide with the housing and the installation of o-rings on the piston part of the spool with the ability to be pressed against the housing by the flow of restrained fluid in the closed position.

Figure 1 shows the proposed flow controller in the context. Figure 2 shows the sealing rings in cross section.

The flow regulator (Figure 1) contains a housing 1, a perforated guide 2, a spool 3, multi-bucket sail 4, O-rings 5 and 6, a return spring 7, adjusting nuts 8, latches 9.

The flow controller operates as follows.

The flow regulator is installed in the system to create a uniform pressure flow of the liquid while ensuring the correct operation of the measuring instruments. Increasing the pressure at the inlet ensures that the liquid acts on the piston part of the spool 3 with an force exceeding the force of the clamps 9 and the return spring 7. The spool 3 moves to the “open” position and intensive fluid flow begins until the pressure between the inlet and the outlet is equalized. At the moment when the force of the return spring 7 and the clamps 9 exceeds the force of the fluid pressure on the piston part of the spool 3, the controller closes. The perforated guide 2, fixedly connected to the housing 1, allows the O-rings 5 and 6 to be held in their seats in the open position of the regulator, and through the holes on the end of the spool 3, connected with the groove of the O-ring 5, the O-ring 5 is additionally pressed to the housing 1 in the closed position of the regulator.

The proposed flow controller allows you to increase the overhaul period by increasing reliability and durability.

Utility Model Formula

A flow regulator comprising a housing comprising a cylindrical perforated portion serving as a guide during movement of a slide valve with a multi-bucket sail, o-rings, return spring, adjusting nuts, clamps, characterized in that the cylindrical perforated guide is fixedly connected to the housing, and the o-rings are mounted on the piston part spool with the ability to tighten to the body with a stream of contained fluid in the closed position of the flow regulator.

Bibliographic data

1Pasport “Flow regulator Xa2.573.006 PS (attached).

2Pasport “MPK flow regulator 10.00.00.OOOPS (attached); RU patent No. 2032885, IPC G01F11 / 00, 15/00, Е02В15 / 04; Application RU No. 94044430, IPC® F17D3 / 18, 3/03, G05G15 / 00, G01F15 / 08, Е02В15 / 00 (prototype).

Claims (1)

A flow regulator comprising a housing comprising a cylindrical perforated portion serving as a guide when moving a slide valve with a multi-bucket sail, o-rings, return spring, adjusting nuts, latches, characterized in that the cylindrical perforated guide is fixedly connected to the housing, and the o-rings are mounted on the piston part spool with the ability to tighten to the body with a stream of contained fluid in the closed position of the flow regulator.