RU2727278C1 - Axial control valve - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: present invention relates to valve industry. Axial control valve comprises external and internal housings, inlet and outlet flanges, flow divider, which is a perforated cylinder, coaxial to which there is a locking member, connected to the rack-type drive by means of a rod, an expansion bushing placed in the outlet flange. Locking element is installed with possibility of rotation around its axis. End section of the rod is installed in the cavity of the internal housing by means of a bearing. Holes in the perforated cylinder are rectangular openings, smaller sides of which have the same size and are parallel to the longitudinal axis of the perforated cylinder, length of larger sides decreases in rows from outlet branch pipe to inner housing, at that smaller sides at one end are located along one line. Holes in the locking element have the shape of isosceles triangles, the bases of which are equal in length and are arranged parallel to the smaller sides of the rectangular windows in the respective rows.EFFECT: proposed design of axial control valve allows providing high accuracy of flow rate control in wide range.1 cl, 4 dwg

Description

The proposed invention relates to valve engineering, in particular, to axial flow control valves used in industrial pipeline valves, and is intended to regulate and shut off working media of liquids and gases.

Known straight-through control valve DN 100 - 1800 PN 10 - 160 [http://gpvalve.ru/files/images/doc/pdf/31.pdf page 15] containing a housing, inlet and outlet pipes 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 rotary-to-translational converter, which is a crank mechanism.

The disadvantage of this valve is the low accuracy of flow control.

Closest to the proposed invention is a straight-through control valve [RF Patent No. 2657371, IPC F16K 1/12, F16K 3/24, F16K 47/14,] containing an external and internal body, inlet and outlet flanges, a flow divider, which is a perforated cylinder , coaxially to which a locking element is installed, connected to the rack drive by means of a rod, an expansion sleeve located in the outlet flange. The locking body is installed with the possibility of rotation around its axis, and the end section of the rod is installed in the cavity of the inner housing with the help of a bearing, and in the area of the output flange, the locking body rests on a cylindrical protrusion made in the expansion sleeve, in addition, on the surface of the rod and the rack drive gear rims in engagement, and the holes in the perforated cylinder and the locking organ have the same shape, are arranged in annular 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 perforated cylinder and the locking organ the same.

The disadvantages of this valve are a small range and low accuracy of flow control, caused by a small amount of rotation of the locking body, limited by the size of the holes in the rows.

The objective of this invention is to create an axial control valve that provides high accuracy of flow control in a wide range by increasing the angle of rotation of the shut-off element during regulation and a special shape of the holes.

The task is achieved by the fact that in the axial control valve, containing the outer and inner bodies, inlet and outlet flanges, a flow divider, which is a perforated cylinder, coaxially to which a locking element is installed, connected to a rack drive by means of a rod, an expansion sleeve located in the outlet flange , the locking body is installed with the possibility of rotation around its axis, and the end section of the rod is installed in the cavity of the inner housing with the help of a bearing, and in the area of the outlet flange, the locking body rests on a cylindrical protrusion made in the expansion sleeve, in addition, on the surface of the rod and the rack drive gear rims are made in engagement, and the holes in the perforated cylinder and the locking body are arranged in annular rows, and the distances between the rows, the distance to the edge of the outlet flange from the nearest row of holes in the perforated cylinder and the locking body are the same, the holes in the perforated perforated cylinder are rectangular windows, the smaller sides of which have the same size and are parallel to the longitudinal axis of the perforated cylinder, the length of the large sides decreases in rows from the outlet to the inner body, and the smaller sides at one end are located along one line, and the holes in the locking body have the shape of isosceles triangles, the bases of which are equal in length and located parallel to the smaller sides of rectangular windows in the corresponding rows.

FIG. 1 is a schematic diagram of an axial control valve.

FIG. 2 shows the position of the holes in the perforated cylinder and the locking member when the valve is fully open.

FIG. 3 shows the position of the holes in the perforated cylinder and the closing member with the valve partially open.

FIG. 4 shows the position of the holes in the perforated cylinder and the locking member when the valve is fully closed.

FIG. 2, 3, 4 diagrams are shown on an enlarged scale.

The axial control valve contains an external 1 and an internal 2 housing, inlet 3 and outlet 4 flanges, a flow divider, which is a perforated cylinder 5, coaxially to which a locking body is installed 6. On the surface of the perforated cylinder 5, holes 7 are made, and on the surface of the locking body 6 - holes 8. The locking body 6 is connected to the rack drive 9 by means of a rod 10. An expansion sleeve 11 is installed in the outlet flange 4. In order to provide the locking body with the possibility of rotation around its axis, the end section of the rod 10 is installed in the cavity of the inner body 2 by means of a bearing 12 , and in the area of the outlet flange due to the cylindrical protrusion made in the expansion sleeve 11. To rotate the locking body on the surface of the rod 10 and the rack drive 9, meshing gears 13 and 14 are made.

Axial control valve works as follows.

The liquid enters through the inlet flange 3 into the cavity between the inner surface of the outer body 1 and the outer surface of the inner body 2, flows around the inner body and is directed through the holes 7 and 8 in the perforated cylinder 5 and the locking organ 6 to the outlet flange 4.

When the valve is fully open, the locking member 6 is turned relative to the perforated cylinder in such a way that the flow area formed by the holes 8 and 7 has a maximum area.

When the valve is fully closed, the holes 7 are completely covered by the surface of the locking body 6.

To rotate the locking body 6 relative to its axis, on the surface of the rod 10 and the rack drive 9, gear rims 13 and 14 are made in engagement. This ensures the rotation of the locking body 6 during the vertical movement of the rack drive 9. In this case, the end section of the rod 10 is installed in the cavity of the internal housing 2 with the help of bearing 12, and in the area of the outlet flange it is fastened by means of a cylindrical protrusion (abuts against its surface), made in the expansion sleeve 11.

High accuracy of flow control and an increase in the control range in the proposed valve is achieved by increasing the angle of rotation of the locking body 6 and the special shape of the holes 7 in the perforated cylinder 5 and holes' 8 in the locking body 6. For this, the holes 7 in the perforated cylinder 5 are made in the form of rectangular windows, the smaller sides of which have the same size and are parallel to the longitudinal axis of the perforated cylinder 5, and the holes 8 in the locking body 6 have the shape of isosceles triangles, the bases of which are equal in length and are located parallel to the smaller sides of the holes 7 (rectangular windows) in the corresponding rows.

Due to the fact that the length of the large sides of the holes 7 decreases in rows from the outlet flange 4 to the inner body 2, and the smaller sides at one end are located along one line, at the beginning of the opening, only holes 7 closest to the outlet flange 4 and holes 8 in the locking body 6, having the shape of isosceles triangles, that is, the liquid passes only through the flow sections when overlapping the holes 7 closest to the outlet flange 4 and the holes 8 in the locking body 6. The holes 8 in the locking body 6 are made in the form of isosceles triangles whose bases are equal in length and are located parallel to the smaller sides of the holes 7 in the respective rows allows for a smooth opening of the flow area from the minimum to the maximum value, which makes it possible to increase the control range.

Due to the fact that the length of the large sides of the holes 7 decreases in rows from the outlet flange 4 to the inner body 2, and the smaller sides at one end are located along one line, it is possible to ensure a consistent opening of the flow sections from the row closest to the outlet flange 4 to subsequent ones. This also allows you to expand the control range.

The proposed design of the axial control valve ensures high accuracy of flow control over a wide range.

Claims (1)

An axial control valve containing an outer and an inner body, inlet and outlet flanges, a flow divider, which is a perforated cylinder, coaxially to which a locking body is installed, connected to a rack drive by means of a rod, an expansion sleeve located in the outlet flange, the locking body is rotatably mounted around its axis, and the end section of the rod is installed in the cavity of the inner housing with the help of a bearing, and in the area of the outlet flange the locking body rests on a cylindrical protrusion made in the expansion sleeve, in addition, on the surface of the rod and the rack drive there are gear rims in engagement, and the holes in the perforated cylinder and the locking body 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 in the perforated cylinder and the locking body are the same, characterized in that the holes in the perforated cylinder are are rectangular windows, the smaller sides of which have the same size and are parallel to the longitudinal axis of the perforated cylinder, the length of the larger sides decreases in rows from the outlet to the inner body, with the smaller sides at one end located along one line, and the holes in the locking organ are isosceles triangles, the bases of which are equal in length and located parallel to the smaller sides of rectangular windows in the corresponding rows.

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