RU69954U1 - FLOW REGULATOR - Google Patents

Abstract

The flow regulator relates to pneumohydraulic metering valves, in particular to shut-off and shut-off valves for oil and gas pipelines, through which fluids are pumped under pressure. The flow regulator comprises a housing with inlet and outlet channels with through holes, a spring-loaded piston with a rod installed in it, and a retainer housing mounted vertically, a clamp tightly connected to the housing. Two fixing assemblies are installed in the housing of the clamps; a sealing assembly is installed at the end of the piston. A gas cavity is made in the base of the retainer housing, a movable sleeve is installed in the body of the retainer body coaxially connected through the rod to the piston, the sleeve has annular grooves interacting with two ball locking assemblies. Two locking nodes are located diametrically opposite and are in perpendicular planes, while they are offset along the axis of the housing of the clamps. The outer surface of the sleeve partially contacts the inner surface of the housing of the clamps on the contact surface. On each side of the contact surface of the sleeve there are cavities communicating with each other by channels. The cavity in contact with the lid is connected by a U-shaped pipe through check valves installed in parallel and opposite to the gas cavity. U-shaped piping and cavities are filled with lubricating oil. In the housing between the inlet and outlet channels, a piston seat coaxial with the housing of the clamps and the piston rod is installed. At the base of the seat is a seat for the rod guide rod. 3 s.p. f-ly, 4 ill.

Description

The utility model relates to pneumohydraulic metering valves, in particular, to shut-off and shut-off valves for gas and oil pipelines through which fluids are pumped under pressure.

The utility model is based on the problem of creating a flow controller with a high frequency of operation up to 6-7 cycles per minute, operating under pressure, at high temperatures and in an aggressive environment where high functional reliability is required.

A known analogue flow controller (RF patent No. 2002127312/20 class. F16K 17/04 publ. 2002) containing a housing with a spring-loaded piston installed in it and a locking groove for interaction with two pairs of locking nodes. The fixing units of each pair are located in perpendicular planes and are displaced along the axis of the regulator; a sealing unit is installed on the end face of the piston. A turbine is installed in the piston cavity.

The disadvantages of the known device is the large weight and large diameter of the piston moving in the liquid - this forces the installation of a strong return piston spring and, accordingly, strong retainer springs. In addition, the turbine does not provide rotation of the piston around the axis. Another disadvantage is the wear and tear of the PTFE piston ring, which occurs with a slight play on the contact surface, the outer surface of the piston and the inner surface of the housing. The next disadvantage is the lack of lubrication of the moving parts of the regulator. These shortcomings lead to rolling on the surface of the piston of unauthorized grooves, premature wear of the balls and the violation of the tightness of the sealing assembly of the piston.

A known prototype flow controller (RF patent No. 2004122814/22 class. F16K 17/04 publ. 2004) containing a housing with installed in

a spring-loaded piston with a rod and a glass (hereinafter referred to as the retainer body) mounted vertically, hermetically connected to the housing by a clamp. In the housing of the clamps, two locking assemblies are installed that interact with the piston rod. A sealing assembly is installed at the end of the piston.

The disadvantage of the prototype is the large compressive force of the springs of the clamps, since the design of the clamps, made in the form of two pairs of interconnected levers, does not allow you to install weak springs. This forces a strong piston return spring to be installed. In this case, the retainer springs operate in a complex mechanical load (compression, bending, friction against the retainer walls), which leads to premature failure. The next disadvantage is the wear and tear of the fluoroplastic ring of the piston sealing assembly, which occur for the same reasons as in the analogue. An important disadvantage is the lack of lubrication of the moving parts of the regulator operating in the gas "pillow" zone. All of the above disadvantages reduce the reliability of the regulator.

The objective of the utility model is to create a flow controller that can significantly increase its reliability, to control the operation of the flow controller in the telemechanics system.

The problem is solved in that in the flow regulator, comprising a housing with a spring-loaded piston with a rod installed therein and a retainer housing mounted vertically, a clamp tightly connected to the housing, in which two fixing assemblies are installed, a sealing assembly is installed at the end of the piston, according to a utility model in the base of the clamp housing is made of a gas cavity, in the body of the clamp housing is a movable sleeve coaxially connected with the piston rod, the sleeve has two annular grooves, interacting connecting with two ball locking knots, while two locking knots are diametrically opposed and are in perpendicular planes and are displaced along the axis of the clamp housing, the outer surface of the sleeve partially contacts the inner

the surface of the body of the housing of the clamps on the contact surface, in the housing of the clamps on each side of the contact surface of the sleeve are made cavities communicating with each other by channels, while the cavity in contact with the cover of the housing of the clamps is connected by a U-shaped pipe through check valves installed in parallel and opposite to the gas cavity , U-shaped pipe and cavities are filled with lubricating oil, in the housing between the inlet and outlet channels a piston seat coaxial with the housing of the clamps and pcs eye of the piston, a seat for the guide rod of the rod is made into the base of the saddle.

On the contact surface of the outer surface of the rod with the inner surface of the housing of the clamps in the body of the housing of the locking nodes can be installed seal.

In the flow regulator, the piston may have a restrictive cover with a pressed rubber ring, and the piston sealing assembly may be made in the form of a rubber ring pressed by a steel ring.

An electromagnetic sensor can be installed in the cover of the housing of the clamps, the effect of which is carried out by moving a permanent magnet mounted on the free end of the rod.

The gas cavity, made in the base of the housing of the clamps, allows the piston to move freely in the housing, which is impossible with the analogue, where the piston moves in the fluid. In this case, the gas cavity allows several times to reduce the compression force of the power return piston spring in comparison with the analogue.

In the body of the housing of the clamps there is a movable sleeve coaxially connected with the piston rod, this design allowed to reduce the weight of this node several times, which is not done with the analogue and prototype. The reduction in weight made it possible to reduce the compression force of the power piston return spring.

The movable sleeve, having two annular grooves, interacting with two ball locking nodes, also allowed to reduce the compression force of the power return spring of the piston and the compression force of the springs of the two clamps, which cannot be performed with the prototype, since the locking nodes are made in the form of two pairs of interconnected levers.

In the inventive design of the controller does not require accurate alignment of the locking nodes, as in the well-known analogue.

Cavities made between the movable sleeve and communicating with each other by channels allow the sleeve to move freely in the fluid and the movable elements of the regulator to work in lubricating oil, which is not the case with the known analogue and prototype.

An oil-filled U-shaped pipe creates an oil seal that prevents the vapors of the flowing fluid from entering the lubricant through the regulator.

Two non-return valves installed in parallel and opposite direction create a pressure differential, provided for by the technical characteristics of the regulator, between the cavities filled with oil and the gas cavity.

Firstly, two non-return valves reduce the pressure force on the seal installed in the body of the clamps separating the cavities filled with oil from the gas cavity, which significantly reduces the wear of the seal.

Secondly, the two check valves in the operating state of the flow regulator are closed, therefore, the access of the vapors flowing through the regulator is closed.

The opening of one of the check valves is due to a decrease or increase in pressure in the gas cavity.

A piston seat coaxial with the retainer body and the stem is installed in the flow regulator body, and a seat for the rod guide rod is made in the base of the saddle. With such a structural connection of the seat, piston and rod, there is practically no damage and quick wear of the piston sealing assembly, in contrast to the analogue and prototype.

On the contact surface, the outer surface of the rod with the inner surface of the housing of the clamps in the body of the housing of the clamps, a seal is installed. The seal allowed to separate the gas cavity from the cavities filled with oil and prevents oil leakage.

The piston is made with a restrictive cover and pressed against the restrictive rubber ring, limit the stroke and soften the landing of the regulator piston. The rubber ring of the piston seal assembly with this design is not subject to rapid wear and tear.

An electromagnetic sensor installed in the cover of the housing of the clamps allows you to control the operation of the controller according to the telemechanics system, which is not provided for the analogue and prototype.

This design of the regulator allows the movable elements to work in lubricating oil, which will significantly reduce the wear of the moving elements of the regulator in comparison with the known analogue and prototype. The inventive design of the flow controller allowed to reduce the compression force of the piston return spring, while the compression forces of the fixing unit springs decreased several times, which is not possible with the analogue and prototype.

Due to all of the above factors, this utility model allows you to achieve the required operating modes of the flow controller and obtain the claimed technical result, while significantly improving reliability.

Figure 1 shows a section of the flow controller in the closed position of the piston.

Figure 2 shows an additional view of the piston seat.

Figure 3 shows a section of the flow controller in the open position of the piston.

Figure 4 shows the remote element of the piston assembly.

The flow regulator (Figs. 1-4) comprises a housing 1 with a movable piston 10 installed therein. A housing of clamps 2 is installed vertically in the housing 1 and are tightly interconnected by a clamp 25. A piston 10 mounted in the housing 1 is fixed to the stem 9 by a nut and spring-loaded spring 13 relative to the housing of the latches 2.

In the housing of the clips 2, cavities 19, 20 are made, communicating with each other by channels (holes) 18. At the points of installation of the clips, channels (holes) are made for lubricating the movable elements of the clips (not shown).

The sleeve 4 is fixed with a nut on the rod 9, while the outer surface of the sleeve 4 and the inner surface of the housing of the latches 2 partially

contacts each other along the contact surface. The sleeve 4 has two annular grooves interacting with the balls 21 of the clips 3, 16. The clips 3 and 16 are structurally identical. The balls 21 are spring-loaded through the pusher 22 with a spring 23 relative to the piston screw 24. The pistons of the screws 24 of the clamps 3, 16 are hermetically sealed with rubber rings. The latches 3 and 16 are installed diametrically opposite and are located in perpendicular planes, offset along the axis of the housing of the latches 2. On the contact surface, the outer surface of the rod 9 with the inner surface of the housing of the latches 2 in the body of the housing of the latches installed radial seal 5, which provides a tight separation of the gas cavity 8 from cavities 19.

The cavity 20 of the U-shaped pipe 6 through the check valves 14 and 15 is hermetically connected to the gas cavity 8.

In the housing 1, a saddle 11 is installed between the input and output channels. A seat for the guide rod 17 of the rod 9 is made in the base of the saddle 11.

In the lid housing cover there is a glass made of non-magnetic steel (not shown in the drawing), in which an electromagnetic sensor 7 is installed. Sensor 7 is connected to a controlled point of the telemechanics system (not shown in the drawing).

The piston 10 comprises a restriction cover 26, a rubber ring 27, and a sealing assembly. The piston sealing assembly 10 comprises a rubber ring 29. Rubber rings 27 and 29 are pressed by a nut between the restriction cover 26 and the steel rings 28 and 30.

At the free end of the rod 9 is installed a permanent magnet 12.

The operation of the flow controller is as follows.

When starting a gas pipeline with a regulator installed, the pressure at the inlet and outlet of the housing 1 rises, and the check valve 14 opens, which sets the cavities filled with oil under the pressure provided by the technical regime. In the process of starting the operation of the regulator, the latches 3, 16 are adjusted, i.e. the pressure forces of the balls 21 through the pushers 22 are regulated by springs 23

using piston screws 24.

In the initial closed state of the regulator, the piston sealing assembly 10 is adjacent to the seat 15 and the interaction of the rubber ring 29 with the inner diameter of the seat 15 allows for reliable tightness of the regulator piston. The retention of the regulator piston in the closed state is ensured by the interaction of the ball 21 of the retainer 3 with the edge of the annular groove of the sleeve 4.

When the pressure drop at the inlet and outlet of the regulator reaches 0.07-0.1 MPa, the piston 10, interacting through the rod 9 and the sleeve 4, will press the ball 21, the pusher 22, the spring 23 inside the retainer 3. The energy of the fluid flow through the seat 11 will move the piston 10 to the open position by compressing the power return spring 13. The sleeve 4 and the magnet 12 will also move to the open position. Sensor 7 will give a signal to the telemechanics system to open the regulator. The ball 21 of the latch 16, interacting with the other side of the grooves of the sleeve 4, will hold the regulator piston in the open position.

At the moment the piston 10 is moved to the open position, the liquid located above the piston restriction cap 27 will freely move into the gas cavity of the retainer housing 2. The sleeve 4 and rod 9 will move freely to the open state due to the lubricant moving freely through the channels 18 from one oil cavity to another.

As the fluid is discharged, the pressure drop decreases, and the energy of the fluid flow acting on the piston 10 also decreases and when the pressure reaches 0.01-0.03 MPa, the force of the compressed power return spring 13 will increase and return the piston 10 to the closed state. The ball 21, the pusher 22, the spring 23 will be pressed inside the latch 16 by the sleeve 4, and the latch 3 will fix the piston 10 in the closed position.

Moving the sleeve 4 and the rod 9 to the closed position will cause free movement of the lubricating oil in the opposite direction.

It should be noted that the movement of the rod 9 in the cavity 19 will decrease or increase the volume of the cavity 19 which is compensated by the volume of the U-shaped pipe 6. In the U-shaped pipe 6, the level of the lubricating oil will fluctuate.

During normal operation of the regulator, the check valves 14, 15 are in the closed position. An increase or decrease in pressure in the gas pipeline will open the check valves 14 or 15, equalizing the pressure drop between the cavities 19, 20 and the gas cavity 8.

Claims (4)

1. A flow regulator comprising a housing with inlet and outlet channels with through holes, a spring-loaded piston with a rod installed in it, and a retainer housing mounted vertically, hermetically connected to the housing by a clamp in which two fixing assemblies are installed, a sealing assembly is installed at the end of the piston, characterized in that a gas cavity is made in the base of the retainer body, a movable sleeve is installed in the body of the retainer body coaxially connected with the piston rod, the sleeve has annular grooves interconnected acting with two ball locking knots, while the two locking knots are diametrically opposed and are in perpendicular planes and are displaced along the axis of the clamp body, the outer surface of the sleeve partially contacts the inner surface of the housing of the clamps on the contact surface, cavities are made on each side of the contact surface of the sleeve , interconnected by channels, while the cavity in contact with the cover is connected by a U-shaped pipe through check valves, installing nye parallel and oppositely directed from the gas cavity, U-shaped conduit and the cavity filled with lubricating oil in the housing between the inlet and outlet channels established saddle piston coaxial with the housing and locks the piston rod, a seat base configured to seat the guide shaft rod. 2. The regulator according to claim 1, characterized in that a seal is installed on the contact surface, the outer surface of the stem with the inner surface of the retainer body, in the body of the retainer body. 3. The regulator according to claim 1, characterized in that the piston has a restrictive cover with a pressed rubber ring, and the piston sealing assembly is made in the form of a rubber ring pressed by a steel ring. 4. The controller according to claim 1, characterized in that an electromagnetic sensor is installed in the lid body cover, the effect of which is carried out by moving a permanent magnet mounted on the free end of the rod.