RU2373447C1 - Control leaf-type valve by zorin (versions) - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: group of inventions refers to accessories engineering and is designed to control over consumption of liquid or gaseous medium transported via pipeline. The control leaf-type valve consists of a cylinder case with diametre exceeding diametre of a pipeline. Swivelling kinematically connected with electro-magnetic drive leafs of a shut off element are installed in a case on axes parallel to axis of a pipeline. Each leaf has a sector working zone, a driven part with tooth surface and slots on surface of the sector zone and on surface of the driven part. The said slots are made on opposite planes; they are designed so, that the sector zone or driven part of conjugated leaves enter the slots. A guiding groove is made at least on one side radial plane of the sector zone of each leaf. The guiding groove has a shape of a paddle with a recess of alternate depth, one of ribs of the sector zone from the side of incoming flow of controlled medium and an indent to periphery of the sector zone of the leaf. There is a structure modification of a control leaf-type valve.

EFFECT: increased reliability of valve operation due to elimination of turbulent flow effect to walls of pipeline by generating a centralised flow and decreasing its turbulence in zone of control.

2 cl, 7 dwg

Description

The group of proposed inventions relates to valve engineering, in particular to pipeline valves designed to control the flow of liquid or gas medium transported through the pipeline.

Known shut-off and control valve designed to control the flow of dust and gas mixture containing a housing with a cylindrical bore in which the petals are mounted with the ability to rotate each of them around an axis directed along the corresponding radius of the cross-section of the bore of the valve body (SU 11764 A, class F16K September 30, 1929).

The disadvantage of the valve is the uneven flow and heterogeneity of the dust-gas mixture behind the valve, due to the tangential acceleration of the flow passing through the valve with partially open petals, turned around the radius of the cross section. The flow of dust and gas mixture swirls around the longitudinal axis of the pipeline and pushed to its inner surface.

Also known is a shut-off and control flap valve containing a body with a cylindrical bore, in which at least three petals are mounted with the possibility of turning each of them around an axis directed along the corresponding chord of the bore of the casing, and the petals are made in the form of plates, shaped sectors of the cross section of the valve body (RU No. 2145684, class F16K 1/20, F16K 15/03, 02/20/2000).

The disadvantage of the valve is the location of the axes of the locking flap elements in the passage section of the valve, which determines the occurrence of turbulence in the flow of the medium transported through the pipeline even with the valve fully open. In addition, when regulating the flow rate of the medium by partially overlapping the passage section of the valve with closing petals in the form of sectors, the flow accelerates behind the petals with the tangential components of turbulence.

The closest technical solution to the purpose, technical nature and the achieved result to the claimed control flap valve is a control valve having a cylindrical body with a diameter greater than the diameter of the pipeline, and in the body, on axes parallel to the axis of the pipeline, plate rotary lobes of the shut-off element are installed, kinematically associated with an electromagnetic drive (SU 1663297 A1, class F16K 31/02, July 15, 1991 - prototype). In each of the lamellar petals of the locking body having a sector working zone with a radius equal to or greater than the radius of the pipeline, and a drive part with a serrated surface, grooves are made on opposing planes to allow them to enter the sector zone or the drive part of the mating petals.

The disadvantage of the valve is the creation of additional turbulence in the flow of the controlled medium behind the partially open lobes, which complicates the regulation process. In addition, when the section of the pipeline is overlapped, the closing sector zones of the petals create an obstacle behind which cavitation processes can occur that cause erosion of the surface of the petals and the surface of the pipeline behind the valve.

The objective of the proposed technical solution is to prevent exposure to the walls of the pipeline turbulent flow, by forming a centered flow, while reducing its turbulence in the regulation zone.

The problem is solved in that in the control flap valve having a cylindrical, with a diameter greater than the diameter of the pipeline, a housing in which on the axes parallel to the axis of the pipeline are installed rotary, kinematically connected with an electromagnetic drive, lamellar lobes of the shut-off member, each of which has sector working area with a radius equal to or greater than the radius of the pipeline, and the drive part with a gear surface, and grooves on the surface of the sector zone and the surface of the drive part, made according to the invention, at least one of the lateral radial planes of the sector zone of each petal has a guiding boring having the shape of a blade with a variable depth sampling along one of the edges of the sector zone the incoming stream and with a recess to the periphery of the sector zone of the petal.

According to an embodiment of the control flap valve according to the invention, a sphere sector sample is made on the surface of the sector working zone of each lobe from the inlet stream, while the center of the total sphere on the surface of the lobes of the shut-off element in the closed position of the valve is located on the axis of the pipeline, and the top of the sphere - in the center of the working area of the petals.

The execution of the petals of the locking body with a guiding bore at least on one of the lateral radial planes of the scapular sector working area, with a variable depth sampling along one of the ribs and with a recess to the periphery of the sector working area of the petal, creates guiding grooves on the surface of the petals of the locking body to the center of the valve, which ensures the implementation by the locking body of the functions of the guide apparatus. An extended sample on one of its ribs on the peripheral part of the petal sector of the working zone of the lobe captures the flow of the controlled medium and, by performing the indicated samples with a decrease in depth to the center of the valve, directs it, compressing the peripheral layers of the controlled medium, to the center of the valve cross-section, which reduces tangential flow components. In a centered flow, turbulence is reduced, cavitation phenomena and erosion consequences caused by them are eliminated, which increases the service life of the valve and pipeline.

An alternative implementation of the lobes of the locking organ with a sample on the surface of the sector zone of the lobe has a similar effect on the flow of the controlled environment. The total spherical sampling, formed on the petals of the locking organ, formed by the samples on the surface of the sector working zone of each petal from the inlet flow, made in the form of a sector of the sphere, directs it along the sampling surface on each petal to the center of the passage section of the valve and pipeline, centers the flow, preventing impact on the walls of the latter.

The centering of the flow of the controlled medium provided by alternative sampling options on the petals of the control valve makes it possible to reduce the hydrodynamic resistance of the valve and reduce the energy costs of transporting the medium.

Examples of options for regulating the flap valve Zorin are shown in the drawings.

Figure 1 presents a General view of the control valve according to option 1 with the position of the locking element "open".

In Fig.2 is a General view of the control valve according to option 2 with the position of the locking element "open".

Figure 3 shows a section aa in figure 1 in the "closed" position.

In figure 4. shows a general view of the petal.

Figure 5 - petal with a boring in the form of a scapula on one of the radial planes of the sector work area.

Figure 6 - petal with a boring in the form of a scapula on two radial planes of the sector work area.

Figure 7 shows a side view of a petal with a sample in the form of a sector of a sphere on the surface of a sector work area.

The control flap valve installed in the pipeline 1 contains a cylindrical tight, made of magnetically permeable material, a housing 2, in which a rotor 3 of ferromagnetic material is placed, on the inner annular surface of which teeth 4 are made, which mesh with the teeth 5 on the drive part 6 of the petals 7, forming a locking body and mounted with rotation on the axes 8, fixed in the end planes 9 of the cylindrical valve body parallel to the axis of the pipeline. Petals 7 made of durable material (for example, alloy steel) have a sector work area 10 with a radius equal to or greater than the radius of the pipeline bounded by the lateral radial planes 11 and 12. On the plane of the petals 7, from the inlet side, a groove 13 is made for the entry into it of the sector working zone 10 of the adjacent petal in the closed position of the locking element, and on the opposite plane 14 of the petal 7 in the drive part, a groove 15 is made so as not to interfere with the free rotation of the adjacent petal. Outside the housing 2 is an electromagnet 16.

In the manufacture of the valve according to the first embodiment (Fig. 5) on one radial plane 11 or on both radial planes 11 and 12 (Fig. 6) of the sector working zone 10 of the petal 7, boring 17 is made in the form of a blade, with a variable depth sample along one of the ribs between the radial plane 11 or 12 and the plane of the lobe from the incoming stream. Each of the bores 17, due to a sample of variable depth, has an expanded part on the peripheral part of the sector working area of the petal and tapers to the opposite edge between the radial plane 11 or 12 and plane 13 of the sector working area of the petal and to the center of the locking element.

In the manufacture of the valve according to the second embodiment (Fig. 7), samples 18 are made in the form of sectors of a sphere on the sector working zone of the petal 7, with the center of the total sphere, with the shut-off element closed, located on the axis of the pipeline, and the top of the sphere in the center of the working zone petals.

The valve operates as follows.

Electromagnet 16 creates a rotating magnetic field, which drives the rotor 3, which transmits rotation to the kinematically connected petals 7. The teeth 4, which engage with the teeth 5 on the drive part 6, the petals of the locking member rotate around the axis 8 in the "open" position or "Closed", reducing or increasing the area of the valve passage area. When moving the petals of the locking member to the “closed” position, sectoral working zones 10 of the adjacent petals enter the grooves 13 made on the planes of the petals from the incoming stream. When the petals are moved to the “open” position, the valve’s flow area increases, the flow of the controlled medium is centered due to the bores 17 on one radial plane 11, or on both radial planes 11 and 12 of the sectoral working area 10, or when the valve is made according to the second embodiment due to samples 18 made in the form of sectors of a sphere on the plane of the lobe from the side of the incoming stream.

The proposed valve embodiments provide a reduction in the effects of the turbulent flow of a controlled medium on the pipe walls due to the formation of a centered flow and a decrease in its turbulence in the control zone.

Claims (2)

1. The control flap valve, having a cylindrical, with a diameter greater than the diameter of the pipeline, a housing in which on the axes parallel to the axis of the pipeline mounted rotary, kinematically connected with an electromagnetic actuator petals of the locking member, each of which has a sector working area and a drive part with serrated surface and grooves on the surface of the sector zone and the surface of the drive part, made on opposite planes with the possibility of entering the sector zone or drive part in them x petals, characterized in that at least one of the lateral radial planes of the sector zone of each petal has a guiding boring having the shape of a scapula with variable depth sampling along one of the ribs of the sector zone from the side of the incoming flow of the controlled medium and with a recess to the periphery of the sector zone of the petal . 2. A control flap valve having a cylindrical one with a diameter greater than the diameter of the pipeline, a housing in which, on axes parallel to the axis of the pipeline, rotary, kinematically connected with an electromagnetic drive, shutter body petals are installed, each of which has a sector working area and a drive part with serrated surface and grooves on the surface of the sector zone and the surface of the drive part, made on opposite planes with the possibility of entering the sector zone or drive part in them x petals, characterized in that on the surface of the sector working zone of each petal from the inlet stream, a sample was made in the form of a sector of a sphere, the center of which in the closed position is located on the axis of the pipeline, and the top of the sphere is in the center of the working zone of the petals.

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