RU12715U1 - REVERSE LOCK WITH ACTUATOR - Google Patents

Abstract

1. A check valve with a drive device, comprising a housing, a rotary disk mounted on the shaft on the shaft, dividing the housing flow path into the input and output cavities, rotary hydraulic actuator and hydraulic damper kinematically connected with the shaft, characterized in that the hydraulic actuator and hydraulic damper are located in one cylinder, have a common stator, a rotor and check valves rigidly connected to the rotary shaft of the disk, the rotor is equipped with at least a pair of radial blades forming in the common cylinder along with the stator of the cavity an alternating lifts communicated with the inlet and outlet cavities of the housing by pipelines and pairwise communicated with each other by throttle openings made in the blades, check valves are installed to isolate at least one of the cavities of the cylinder from adjacent cavities while reducing it in volume when the shutter disk moves to close. 2. The check valve according to claim 1, characterized in that the cylinder of the hydraulic actuator and hydraulic damper is partially filled with air. The backstop according to claims 1 and 2, characterized in that one of the blades is equipped with a rigid body filled with metal with a high specific gravity, for example, lead.

Description

REVERSE LOCK WITH ACTUATOR

The utility model relates to valve engineering and can be used to block the return flow of a liquid medium in pipelines.

A one-way shutter is known, comprising a housing, a rotary disk and a single-acting hydraulic actuator kinematically connected to the rotary disk, the working cavity of which is connected by a pipeline to the valve body (AS USSR N1767264, M.cl.PbK 15/03).

The working medium, entering the cavity of the hydraulic actuator, acts on the piston, which moves and rotates the lever connected to the rotary disk. In this case, the opening angle of the disk increases, and the hydraulic resistance of the open shutter to the working flow decreases.

The disadvantage of the described back-lock is the relatively high hydraulic resistance of the back-lock to the flow of the working medium in the open position due to the inefficient use of the flow energy to open the shutter.

The prototype of the claimed utility model is a back-lock protected by RF patent N2116541 for the invention, M.cl. F16K 15/03.

The prototype contains a housing, a rotary disk mounted in the housing on the shaft, dividing the flowing part of the housing into the inlet and outlet cavities, kinematically connected with the rotary shaft. PbK 15/03

two hydraulic actuators and two hydraulic dampers located symmetrically with respect to the check valve body. One of the cavities of each hydraulic actuator is connected by a pipeline with the inlet cavity of the housing, the other cavity - with the outlet cavity of the housing. The pipelines connecting the working cavities of the hydraulic actuators with the flowing part of the housing are equipped with ejector nozzles that increase the pressure difference (difference) on the pistons of the hydraulic actuators and thereby contribute to an increase in the rotational force (torque) on the back-lock disk.

The disadvantages of the prototype are the cumbersome layout of the check valve with piston hydraulic actuators and hydraulic dampers on pipelines of medium and small diameters (less than 10СУ mm), as well as the inability to operate the described check valve on underground and underwater pipelines due to the presence of external moving parts of the piston mechanisms.

The inventive utility model solves the problem of improving the manufacturability and reliability of the back-lock by creating a compact universal drive device, including an efficient hydraulic drive and hydraulic damper, devoid of external moving parts.

The problem is solved in the reverse shutter with a drive device containing a housing mounted on the shaft of the rotary disk separating the flow part of the housing into the input and output cavities, and a drive device made in the form of kinematically connected with the shaft and placed in the same cylinder rotary hydraulic actuator and hydraulic damper having a common stator, a rotor and check valves rigidly connected to the rotary shaft of the disk. The rotor is equipped with at least the radial vanes forming in the common cylinder, along with the stator, cavities of variable volume, connected to the inlet and outlet cavities of the housing by pipelines and in pairs communicated with each other by throttle openings made in the blades. Check valves are installed to isolate at least one of the cavities of the cylinder from adjacent cavities while reducing it in volume when the shutter disk moves to close. One of the blades is equipped with a rigid body filled with metal with a high specific gravity, for example, lead. The cylinder of the hydraulic actuator and hydraulic damper is partially filled with air.

The essence of the utility model is illustrated by a drawing, in Fig. 1 of which a backward shutter is shown in section, Fig. 2 is a view A of the backstop with two symmetrical actuating devices, Fig. 3 is a section along BB, Fig. 4 is a section along BB drive devices, FIGS. 5 and 6 are sectional check valves.

The check valve with a drive device comprises a housing 1 with a seat 2, a rotary disk 4 mounted in the housing on the shaft 3, dividing the flowing part of the housing 1 into the input 5 and output cavity 6. The blade rotor 7 is rigidly connected to the shaft 3. The rotor 7 and the stator 8 form cavities 10,11,12 in the cylinder 9 and

13 variable volume. Cavities 10 and 12 are connected by a pipeline

14 with the input cavity 5 of the housing 1, the cavities 11 and 13 are communicated by a pipe 15 with the output cavity 6 of the housing 1. End

part of the pipeline 14 is bent towards the forward flow, and the end part of the pipeline 15 is bent towards the reverse flow. On the bent sections of the pipelines 14 and 15, nozzles 16 and 17 are installed with channels in the form of a confoor turning into a diffuser. The rotor 7 is provided with at least a pair of radial blades 18 and 19, in which the throttle holes 20 and 21 are made. The blade 18 has a rigid body 22 filled with metal 23 with a high specific gravity, for example, lead. A check valve 24 is installed in the blade 19. A check valve 25 is installed in the pipe 14. The cylinder 9 is partially filled with air 26.

To increase the efficiency of the check valve at the opposite ends of the rotary shaft 3 can be installed symmetrically at least two of the inventive drive device operating synchronously (see figure 2 of the drawing).

The inventive backstop operates as follows.

After starting the pump, the direct flow of the working medium, entering the inlet cavity 5 of the valve body 1, turns the disk 4 on the shaft 3 and opens the passage in the valve body. At the same time, the liquid working medium through the pipe 14 enters the cavities 10 and 12 of the cylinder 9 of the hydraulic actuator, in which the pressure is set close to the hydrodynamic pressure of the direct flow of the working medium. The cavities 11 and 13 of the hydraulic actuator are filled with liquid working medium through a pipe 15 provided with a nozzle 17. The pressure difference on the blades 18 and 19 of the rotor 7 is approximately equal to the pressure loss of the working medium on the rotary

disk 4 and nozzle 17, working on a direct stream as an ejector. Under the action of the differential pressure on the blades 18 and 19, the rotary rotor 7 begins to transmit additional rotational force to open the rigidly connected shaft 3 and the rotary disk 4. The check valves 24 and 25 are open. When the check valve 24 is open, the blades 18 and 19 do not show significant resistance to the rotation of the disk 4. At the end of the rotation of the rotor 7 and the disk 4 to open the shutter, the weight of the blade 18 contributes to the braking of the rotor 7 and the rotary disk 4. As a result of opening the shutter, the disk 4 takes the position indicated figure 1 of the drawing by a dotted line. During the opening of the shutter, balancing of the rotary disk 4 is simultaneously carried out, since in this case the massive blade 18 acts as a counterweight.

8 increased in the volume of the cavity 12 increases the air chamber 26, into which air flows from the neighboring cavity 13.

When the pump stops, the working flow in the system stops and the pressure in the cavities of the cylinder 9 of the hydraulic actuator is equalized. Under the action of the weight of the blade 18 and the rotary disk 4 rigidly connected to the rotor 7, the shutter closes and the rotor 7 rotates in the opposite direction.

When a backflow occurs in the system, the pressure in the inlet cavity 5 of the shutter is less important than the pressure in the outlet cavity 6. In the cavities 11 and 13 of the cylinder

9 establishes a pressure greater than in the cavities 10 and 12, and close to the hydrodynamic pressure of the return flow. The cavities 10 and 12 of the cylinder 9 are filled with liquid working medium along

the pipeline 14, equipped with a nozzle 16, operating on the reverse flow as an ejector. The pressure difference on the working blades 18 and 19 of the rotor 7 is approximately equal to the pressure loss of the working medium on the rotary disk 4 and the ejector 16. Under the action of the pressure difference on the blades 18 and 19 and the weight of the blade 18, the rotor 7 is rotated rapidly in the opposite direction, compressing cavity 12 air 26. At the same time check valves

24 and 25 are closed, isolating the cavity 10 and 12 of the cylinder 9 from the adjacent cavities 5 and 11. With the closed check valves 24 and

25, air 26 is compressed and it absorbs part of the energy of the accelerated rotor 7 — soft damping of the rotation of the rotor 7 and the disk 4 connected to it occurs. After 3, this starts the throttling of the liquid working medium through the hole 21, the gaps between the blades 18, 19 and the inner surface of the cylinder 9 in the cavity 11 and 13. There is a rigid damping of the rotation of the rotor 7, the disk 4 and the smooth landing of the disk 4 on the saddle 2 of the shutter. Massive blade 18 contributes to the damping of vibrations of the disk 4 arising from exposure to a pulsating flow of the working medium.

The selection of the volume of air 26 injected into the cavity 12 of the cylinder 9, the weight of the blade 18 and the diameters of the throttle openings 20 and 21 ensures the optimal closing speed of the check valve when the disk 4 is mounted on the seat 2.

The compactness of the shutter actuator, including the hydraulic actuator and hydraulic damper, the absence of moving parts, allows it to be used in underground pipelines.

Claims (3)

1. A check valve with a drive device, comprising a housing, a rotary disk mounted on the shaft on the shaft, dividing the housing flow path into the input and output cavities, rotary hydraulic actuator and hydraulic damper kinematically connected with the shaft, characterized in that the hydraulic actuator and hydraulic damper are located in one cylinder, have a common stator, a rotor and check valves rigidly connected to the rotary shaft of the disk, the rotor is equipped with at least a pair of radial blades forming in the common cylinder along with the stator of the cavity an alternating lifts communicated with the inlet and outlet cavities of the housing by pipelines and pairwise communicated with each other by throttle holes made in the blades, check valves are installed to isolate at least one of the cavities of the cylinder from adjacent cavities while reducing it in volume when the shutter disk moves to close.  2. The check valve according to claim 1, characterized in that the cylinder of the hydraulic actuator and hydraulic damper is partially filled with air. 3. The backstop according to claims 1 and 2, characterized in that one of the blades is equipped with a rigid body filled with metal with a high specific gravity, for example, lead.