RU76096U1 - FLOW REGULATOR - Google Patents

Abstract

The invention relates to pneumohydraulic valves, in particular to shut-off and shut-off valves for oil and gas pipelines, through which fluids are pumped under pressure. The technical result consists in increasing the functional reliability of the flow controller. Figure 1 shows the design of the flow controller, figure 2 shows the design of the valve, figure 3 shows the flow controller in closed and open states in the socket of the pipeline. Tight fixation of the flow regulator in the pipe socket is carried out using a clamp. The flow regulator (figure 1) contains a housing 1, a sleeve 2, a rod 3, a rod 4, a limiter 5 of the stroke of the rod with a nut 6, a valve 7, a spring 8, levers 9, 10 of interaction with the rod, levers 11, 12 of interaction with the springs 13 , 14, interacting with pistons 15, 16, interacting with bolts 17, 18 installed in fittings 19, 20, sleeve 21, valve 7 (FIG. 2) includes a cover 22, a bearing ring 23, a retaining ring 24, a restrictive ring 25, O-ring 26, shock-absorbing ring 27, stuffing box 28, nut 29, holes 30 are provided in retaining ring 24, stop Noe ring 25 formed with a ledge 6 for channel 31. ZP 3 ill.

Description

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

A known flow regulator (RF patent No. 41826, class F 16 K 17/04, publ. 2004), comprising a housing with a rod installed in it, interacting with a lever system at the end of the rod has a valve. A disadvantage of the known device is insufficient tightness and resistance to aggressive environments, insufficiently reliable fixation of the rod in the open and closed position.

The objective of this utility model is to develop a device devoid of these disadvantages.

The technical result consists in increasing the functional reliability of the flow controller.

The result is achieved by the fact that in the flow regulator containing the housing with the stem installed in it, which interacts with the lever system, a valve is installed at the end of the stem, a spring is installed between the housing and the valve, the stroke limiter is installed in the housing, and the lever system is designed as two pairs of interconnected levers, with one end of each pair fixed, the second end of each pair connected to the rod, the connections of the levers of each pair are spring-loaded, and the valve is made in the form of coaxial bearing, retaining and faceting considerably rings pressed against the lid, between the lid and the carrier ring mounted gland rings and damping between

the bearing and retaining rings installed a sealing ring, and the fact that the housing is hermetically connected to the pipe clamp, and the fact that the retaining ring is made with holes made around the perimeter of the ring, and the fact that the sealing ring is made with a protrusion around the perimeter, and the fact that the restrictive ring is made with a ledge.

Figure 1 shows the design of the flow controller, figure 2 shows the design of the valve, figure 3 shows the flow controller in closed and open states in the socket of the pipeline. Tight fixation of the flow regulator in the pipe socket is carried out using a clamp.

The flow regulator (figure 1) contains a housing 1, a sleeve 2, a rod 3, a rod 4, a limiter 5 of the rod stroke with a nut 6, a valve 7, a spring 8, levers 9, 10 of interaction with the rod, levers 11, 12 of interaction with the springs 13 , 14, interacting with the pistons 15, 16, interacting with the bolts 17, 18 installed in the fittings 19, 20, the sleeve 21, the valve 7 (figure 2) contains a cover 22, a bearing ring 23, a retaining ring 24, a restrictive ring 25, O-ring 26, shock-absorbing ring 27, stuffing box 28, nut 29, holes 30 are provided in retaining ring 24, stop Noe ring 25 formed with a ledge 31.

The flow controller operates as follows. The levers 9-12 draw the rod 4 by means of springs 13, 14. The force of action of the springs 13,14 is regulated by their compression by means of bolts 17, 18. In the initial, closed, position, the “bolt part is held by the force of the spring 8 and the lever-spring mechanism consisting of levers 11, 12 interacting with springs 13, 14, interacting with pistons 15, 16, interacting with bolts 17, 18 installed in fittings 19, 20. When the pressure difference at the inlet and at the outlet of the regulator reaches a predetermined spring 8 and springs 13, 14 value of 0.08 ... 0.12 MPa (0.8 ... 1.2 kgf / cm ²⁾ current 4 (together with the "gate portion")

it is shifted, lifts the regulator valve 7 and opens the channel of the pipe socket, while the energy of the fluid flow flowing through the channel of the pipe socket moves the controller rod 4 to the open position and fixes it in the open position using the lever-spring mechanism and the stroke limiter 5. The regulator in this position is fully open. As the fluid is discharged from the satellite separator AGZU "Sputnik, the differential pressure decreases and when the total force acting on the piston from the fluid flow and from the lever-spring mechanism decreases, to values less than the force of the return spring 8, the valve 7 of the regulator moves in the closed position and is fixed using the lever-spring mechanism. The pressure drop difference for opening and closing the valve 7 of the regulator is adjusted using bolts 17, 18 by loosening or tightening the springs 13, 14, and also using the rod stroke limiter 5 (which changes the conditional passage when adjusting when the regulator is open). low-rate wells, it is recommended to reduce the conditional passage using the limiter 5 stroke, and to work with high-rate wells to increase. To ensure the cyclic operation of high-yield wells, it is recommended to set the maximum nominal pass. The valve 7 of the controller, comprising a cover 22, a bearing ring 23, a retaining ring 24, a restrictive ring 25, an o-ring 26, a shock absorber ring 27, an packing ring 28, a nut 29, is mounted on the stem 6. The tightness between the inner surfaces of the valve and the stem is ensured by rings 28.

Tightness between the outer surfaces of the valve and the saddle of the pipe “A” socket is provided by ring 26. Ring 27 serves to mitigate shock loads when closing the regulator.

The valve of the regulator provides a snug fit ring 26 to the saddle of the socket of the pipe “A”. The larger the pressure drop between the regulator cavities, the denser the fit of the ring 26 to the saddle "A", due to the fact that the pressure through the ledge

31 rings 25 and holes 30 of the ring 24 (see arrow) enters the cavity "G" bursting ring 26, which ensures absolute tightness not even allowing micro-leaks.

In the proposed regulator, a stroke limiter is installed, the valve is made in such a way that with an increase in the pressure drop, the shutter tightness becomes denser, a barrel-shaped return spring is installed, this ensures high reliability of the product.

Thus, the utility model provides sufficient tightness and resistance to aggressive media in the regulator, reliable fixation of the regulator valve in the open or closed position. All this increases the functional reliability of the flow controller.

Claims (7)

1. A flow regulator comprising a housing with a rod installed in it, interacting with a system of levers at the end of the stem a valve is installed, characterized in that a spring is installed between the housing and the valve, and a stroke limiter is installed in the housing. 2. The flow regulator according to claim 1, characterized in that the lever system is made in the form of two pairs of interconnected levers, with one end of each pair fixed, the second end of each pair connected to the rod, the lever connections of each pair are spring-loaded. 3. The flow regulator according to claim 1, characterized in that the valve is made in the form of coaxial bearing, retaining and restrictive rings pressed by the cover, between the cover and the bearing ring are installed stuffing rings and shock absorbing rings, a sealing ring is installed between the bearing and retaining rings. 4. The flow regulator according to claim 1, characterized in that the housing is hermetically connected to the pipeline with a hose clamp. 5. The flow regulator according to claim 3, characterized in that the retaining ring is made with holes made around the perimeter of the ring. 6. The flow regulator according to claim 3, characterized in that the sealing ring is made with a protrusion around the perimeter. 7. The flow regulator according to claim 3, characterized in that the restrictive ring is made with a step.