RU2702022C1 - Axisymmetric control valve - Google Patents

Abstract

FIELD: valve industry.

SUBSTANCE: proposed invention relates to valve industry, in particular, to direct-flow control valves used in industrial pipeline fittings, and is intended for control and shutdown of liquids and gases working media. Axisymmetric control valve comprising external and internal housings, inlet and outlet flanges, flow divider coaxially with which a turning member is installed with possibility of rotation, to the end parts of the locking member by means of flat annular plates an additional perforated cylinder of smaller diameter is coaxially attached, contacting by its inner surface with the hollow cylindrical stop connected to the expansion bushing, hollow cylindrical thrust has holes with their axes aligned with axes of holes in flow divider. Besides, expansion sleeve has conical hollow with flow swirler in zone of outlet flange.

EFFECT: proposed axial-symmetric control valve provides reliable operation, prevents cavitation effects and is reliably sealed in closed position.

1 cl, 1 dwg

Description

The present invention relates to valve manufacturing, in particular, to axial flow control valves used in industrial pipe fittings, and is intended for regulating and shutting off working fluids of liquids and gases.

Known direct-flow control valve DN 100 - 1800 PN 10 -160 [http://gpvalve.ru/files/images/doc/pdf/31.pdf page 15] comprising a housing, inlet and outlet nozzles with flanges, a flow divider made in in the form of a set of coaxially mounted perforated hollow cylinders, a piston with a drive and a translational rotational motion converter, which is a crank mechanism.

The disadvantages of this valve is the occurrence of cavitation due to the high pressure drop.

Closest to the proposed invention is a direct-flow control valve [RF Patent No. 2657371, IPC F16K 1/12, F16K / 24, F16K 47/14, publ. 06/13/18, BI No. 17] containing external and internal housings, input and output flanges, a flow divider, which is a perforated cylinder coaxially to which a locking member is installed, connected to the rack drive by means of a rod, which is located in the expansion flange in the output flange. The locking member is mounted to be able to rotate around its axis, the end portion of the stem being mounted in the cavity of the inner housing using a bearing, and in the area of the outlet flange, the locking member is supported by a cylindrical stop made in the expansion sleeve, in addition, located on the surface of the stem and the rack drive gear rims are engaged, and the holes in the perforated cylinder and the locking body have the same shape, are arranged in circular rows, and the distance between the rows, the distance to the edge I have the outlet flange from the row of holes nearest to it and the angular pitch between the centers of the holes in the perforated cylinder and the locking body are the same.

The disadvantages of this valve are the occurrence of cavitation and unreliable sealing.

The objective of the invention is to provide an axisymmetric control valve that prevents cavitation effects and is securely sealed in the closed position

The task is achieved in that in the axisymmetric control valve containing the outer and inner bodies, inlet and outlet flanges, a flow divider coaxially to which a locking body is mounted rotatably coaxially with the rack and pinion drive, an expansion sleeve placed in the outlet flange, end section the rod is placed in the cavity of the inner case by means of a bearing, and in the area of the output flange, the locking body is supported by a cylindrical stop made in the expansion sleeve, cut Moreover, on the surface of the stem and the rack and pinion drive gears are engaged gears, and the holes in the flow divider and the locking body have the same shape, are arranged in circular rows, and the distance between the rows, the distance to the edge of the output flange from the closest row of holes and the corner the distance between the centers of the holes in the flow splitter and the locking organ is the same; an additional perforated cylinder of a smaller diameter is coaxially attached to the end parts of the locking organ by means of flat ring plates tra contacting its inner surface of the hollow cylindrical abutment connected to the expansion sleeve, a hollow cylindrical anvil openings whose axes coincide with the axes of the holes in the flow divider, besides the expansion sleeve in the area of the outlet flange has a conical recess with a flow swirler.

In FIG. 1 shows a diagram of an axisymmetric control valve.

The axisymmetric control valve contains external 1 and internal 2 bodies, input 3 and output 4 flanges, a flow divider 5, coaxial to which is installed a locking body 6. On the surface of the flow divider 5 holes 7 are made, and on the surface of the locking body 6 there are openings 8. The locking body 6 is connected to the rack drive 9 by means of the rod 10. An expansion sleeve 11 is installed in the output flange 4. In order to provide the locking body with the possibility of rotation around its axis, the end portion of the rod 10 is installed in the cavity of the inner body CA 2 using a bearing 12, and in the area of the output flange due to the cylindrical stop made in the expansion sleeve 11. To perform the rotation of the locking body on the surface of the rod 10 and the rack drive 9 are made mesh gears 13 and 14.

An additional perforated cylinder 16 of smaller diameter is coaxially attached to the end parts of the locking member 6 by flat ring plates 15, which contacts its inner surface with a hollow cylindrical stop 17 connected to the expansion sleeve 11. Holes 18 are made in the hollow cylindrical stop 17, the axes of which coincide with the axes holes 7 in the flow divider 5. The expansion sleeve 11 in the area of the output flange 4 has a conical cavity 19. In the additional perforated cylinder 16 there are holes 20. In the conical the second cavity 19 posted by the swirl flow 21.

The axisymmetric control valve operates as follows.

The fluid enters through the inlet flange 3 into the cavity between the inner surface of the outer casing 1 and the outer surface of the inner casing 2, flows around the inner casing and is guided through the openings 7 and 8 in the flow divider 5, locking organ 6, and also the openings 20 and 18 in the additional perforated cylinder 16 and cylindrical stop 17 to the output flange 4.

When the valve is fully open, the locking body 6 is rigidly connected to the additional perforated cylinder 16 and rotated relative to the perforated cylinder and the cylindrical stop 17 so that the axes of the holes 7, 8 and 18, 20 coincide, that is, the holes open completely.

To reduce the flow rate, the locking member 6 with an additional perforated cylinder 16 rotates relative to its axes, while the axes of the holes 8 and 20 are displaced and the passage section through which the liquid passes decreases. With the valve fully closed, all openings are completely closed.

To effect rotation of the locking member 6 about its axis on the surface of the rod 10 and the rack drive 9, gear rings 13 and 14 are engaged. This ensures that the locking member 6 rotates when the rack drive 9 is vertically moved. In this case, the end portion of the rod 10 is mounted in the cavity of the inner housing 2 by means of a bearing 12, and in the area of the output flange is attached by a cylindrical stop (abuts against its surface), made in the expansion sleeve 11.

Due to the fact that an additional perforated cylinder of a smaller diameter coaxially attached to the end parts of the locking body by means of flat annular plates is contacted by a hollow cylindrical stop connected to the expansion sleeve, and holes are made in the hollow cylindrical stop, the axes of which coincide with the axes of the holes in the divider flow, a step-by-step (phased) decrease in pressure is organized, which helps to reduce cavitation effects. The first throttling of the flow occurs when the fluid flows through holes 7 and 8, the second when the holes 20 and 18 pass.

The presence of a conical cavity in the expansion sleeve in the area of the outlet flange with a swirl 21 located on its surface at the outlet of the valve makes it possible to form a swirling flow in which the remaining gas bubbles will move to the central part and collapse in it. This will prevent cavitation destruction of valve parts and piping.

The proposed axisymmetric control valve ensures reliable operation, prevents cavitation effects and is tightly sealed in the closed position.

Claims (1)

An axisymmetric control valve containing external and internal housings, inlet and outlet flanges, a flow divider coaxially to which a locking member is mounted rotatably, connected to the rack drive by means of a rod, an expansion sleeve located in the output flange, the end portion of the rod is placed in the cavity of the inner case by means of a bearing, and in the area of the outlet flange, the locking body is supported by a cylindrical stop made in the expansion sleeve, in addition, on the surface of the stem and rack the geared crowns are made, and the holes in the flow splitter and the locking body have the same shape, are arranged in circular rows, and the distances between the rows, the distance to the edge of the outlet flange from the nearest row of holes and the angular pitch between the centers of the holes in the flow splitter and locking bodies identical, characterized in that to the end parts of the locking body using flat ring plates coaxially attached an additional perforated cylinder of a smaller diameter in contact with the entire inner surface of the hollow cylindrical stop connected to the expansion sleeve, holes are made in the hollow cylindrical stop, the axes of which coincide with the axes of the holes in the flow divider, in addition, the expansion sleeve in the area of the output flange has a conical cavity with a flow swirl.

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