RU2527775C1 - Control disk gate (versions) - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: group of the inventions relates to pipeline valves and is intended for gas flow or pressure control in gas supply systems of thermal power stations and boiler-houses. The control disk gate comprises the housing, regulating element, regulating element level, circuit plate and two semi-axes. The circuit plate has through-holes. The named through-holes are located along arc in a quarter of the circuit plate. On two semi-axes the regulating element is rigidly fixed. The circuit plate is rigidly installed on a semi-axis passing outside the housing. The regulating element lever is located on a semi-axis passing outside the housing. The regulating element lever is fixed to the circuit plate using the fixing element located in one of the holes of the circuit plate. There are design versions for implementation of the control disk gate.

EFFECT: group of the inventions is aimed at a possibility of adjustment of the position of the regulating element with reference to the lever in the regulating disk shutter, that will allow to pass through the gate a necessary amount of gas or to maintain constant downstream gas pressure.

10 cl, 6 dwg

Description

A group of inventions related to valve options of a disk regulating shutter relates to pipe fittings designed to control the pressure or gas flow in gas supply systems of thermal power plants (TPPs) and boiler houses.

Regulating disk shutter (hereinafter referred to as the shutter) can be used as a regulating device in gas control points (hydraulic fracturing) or in front of burners of gas-using installations. In this case, the shutter must solve the problem of smoothly changing the gas pressure at the outlet of the hydraulic fracturing or smoothly changing the burner power over the entire range of the angle of rotation of the regulating element (hereinafter referred to as RE).

It is known that the flow characteristics of the gates depend on the diameter of the RE and the degree of its opening (see the flow characteristics of the disk gates - the dependence of the throughput Kv on the diameter D _{N of the} control element and the angle of rotation φ of the control element. TECOFI Butterfly valves catalog of February 13, 2009 ., http://www.tecofi.fr/). From these characteristics it can be seen that even a slight change in the position of the RE leads to a significant change in the throughput of the shutter (in particular this applies to the RE of a large diameter). The greatest steepness in the flow characteristics is observed precisely at small angles of rotation of the RE, where 10 ° <φ <20 °. Therefore, the need to ensure a gentle flow characteristics of the shutter, in particular, is required at small angles of rotation of the RE. In addition, it is known that for tightly closing shutters it is not possible to determine the flow characteristic at 0 ° ≤φ <10 °.

Known butterfly valve regulating (GB, patent 2192226 A, F02D 9/10, F16K 1/22, publ. 01/06/1988), adopted as a prototype for the first and second inventions. Known shutter is designed to control the flow of air supplied to the internal combustion engine (hereinafter ICE) of the car. The shutter comprises a housing, a regulating element (disk) located in the internal cavity of the housing and rigidly fixed to the shaft. The shaft is located in the bearings and has the ability to rotate. One of the ends of the lever is fixed to the shaft. A force is applied to the other end of the lever from the actuator. A feature of the known shutter disk regulating is that in the initial state (φ = 0 °) between the body and the disk formed a significant annular gap. Ring clearance solves two problems. Firstly, it prevents jamming of the disc in the case as a result of thermal expansion. Secondly, the value of the annular gap in the initial position (φ = 0 °) is calculated from the condition that enough air passes through the gap for the internal combustion engine to operate in idle mode.

The shutter, located in front of the burner, faces a similar task, namely, through the shutter in its initial position must pass the necessary amount of gas sufficient to ignite the burner.

A disadvantage of the known shutter disk regulating (GB 2192226A) is that there is no possibility of changing the magnitude of the "significant annular shutter" in the initial position. Therefore, there is no possibility of changing the amount of the working medium, sufficient, for example, to operate the internal combustion engine in idle mode or to ignite the burner. If it were possible to change the initial position of the RE in a known shutter at which φ ≠ 0 °, then it would be possible to change the gap and perform a shutter without a significant annular gap in the closed state when φ = 0 °.

As a first and second embodiment of a shutter, a product is proposed that can be controlled either manually or by an actuator.

As a third and fourth embodiment of the shutter design, a finished product is proposed in which the control of the electronic equipment is performed by an electric actuator fixedly mounted on the shutter body.

From the patent literature known disk regulating shutter (GB patent 2393497, CL F02D 9/10, publ. 31.03.2004), adopted as an analogue for the third and fourth inventions. The shutter is designed to control the gas-air mixture supplied to the internal combustion engine of the car. The shutter contains a housing and a RE located in the housing and mounted on the shaft. There are two RE levers on the shaft (the first and second RE levers), while the first RE lever is rigidly fixed to the shaft, and the second lever is rotatably mounted on the RE shaft. The first and second levers of the RE have longitudinal cutouts at the second ends, in which a bolt is installed, with the help of which the levers of the RE are pivotally connected to one of the ends of the rod. The other end of the rod is connected to the lever of the actuator. To open the shutter, the lever of the actuator is rotated counterclockwise, and the levers of the electric actuator are rotated clockwise by means of a link with the lever of the actuator. When turning the RE, the bolt moves in the longitudinal cutouts of the first and second levers of the RE, and thus it is possible to control the length of the shoulder from the axis of rotation of the RE to the point of connection of the RE levers with the thrust. The length of the shoulder varies depending on the position of the lever of the actuator. The articulation mechanism of the known control shutter, consisting of two levers of RE, traction and the lever of the actuator, provides a slow opening of the shutter at small angles of rotation φ, which allows you to effectively control the operation of the engine at low speeds and low load. At the same time, when the engine switches to power mode, the articulation mechanism increases the shutter opening speed. This mode of rotation of the disk is achieved due to the nonlinearity (concavity) of the characteristics of the articulation mechanism. In this case, the design of the articulation mechanism solves the problem of slow opening of the shutter at small angles of rotation φ and a further increase in the speed of opening the shutter (in contrast to the proposed inventions, which require a smooth opening of the shutter in the entire power range).

Known regulating device (Guiding material "Systems of automation of technological processes. Calculation of electrical actuators during design", RM 4-173-79, State Order of the Red Banner of Labor Design Institute "Project Montazhavtomatika", Section 4 "Articulation of the electric actuator with the regulatory body", The deadline for the introduction of guidance is December 1, 1979, pp. 18-26, http://opengost.ru/). The known regulating device containing a RE in the form of a disk mounted in the housing, an electric actuator and an articulation mechanism consisting of an RE lever, a thrust and an actuator lever, are adopted as an analogue for the third and fourth embodiments of the invention. In the indicated guidance material, examples of constructing kinematic diagrams of articulation mechanisms consisting of an actuator lever and a RE lever connected by a thrust, methods for calculating them, and obtained characteristics of the articulation mechanism (non-linear (concave) or linear) are considered. From the equations and graphs given in the guiding material (Fig. 2a is the flow rate characteristic of the RE, Fig. 2b is the characteristic of the articulation mechanism, Fig. 2c is the characteristic of the regulating device) it follows that the type of the flow characteristic of the regulating device depends on the characteristics of the articulation mechanism. In particular, it is indicated that the nonlinearity (concavity) of the characteristics of the articulation mechanism leads to the linearity of the characteristics of the control device. In turn, the characteristic of the articulation mechanism depends on the relative position of the elements of the articulation mechanism relative to each other.

As a prototype for the third and fourth inventions, a throttle valve (RU 103154 U1, class F16K 1/00, publ. 03/27/2011) is adopted, comprising a housing, a control element located in the housing, a shaft, a lever of the control element, an actuator and traction, one end of which is connected to the lever of the actuator, and the other end is connected to the lever of the regulating element.

A disadvantage of the known control valves, given as analogues for the third and fourth inventions, is the lack of tools that would allow you to change the position of the lever RE relative to the RE. This would allow the articulation elements to be in the desired position, which would ensure a smooth adjustment of gas flow or pressure. In addition, the ability to adjust the position of the RE relative to the lever of the RE would allow the RE to be placed in the desired initial position (φ> 0 °) to create an annular gap between the housing and the RE.

The objective of the invention is the ability to control the position of the RE relative to the lever of the RE in the control disk shutter.

This possibility will allow you to set the RE in the desired initial position (φ> 0 °) and to form a gap of the required size between the housing and the RE. This will allow the required amount of gas to pass through the shutter to ignite the burner or to maintain a constant (p = const) gas pressure at the outlet of the hydraulic fracturing.

In addition, when controlling the actuator, the ability to control the position of the RE relative to the RE lever will make it easy to arrange the elements of the articulation mechanism in the desired position. Which in turn will determine the nature of the RE movement.

In all variants of the structural embodiment of the gates, the possibility of regulating the position of the RE relative to the lever of the RE is achieved using the faceplate.

In addition, the use of the faceplate in the first and second inventions allows you to fix the position of the RE in the housing.

The articulation mechanism in the third and fourth inventions provides for smooth adjustment of gas flow or pressure.

The technical result in the first invention is achieved by the fact that the disk regulating shutter comprises a housing, a regulating element located in the housing, a regulating element lever, a faceplate in which through holes are made located in an arc in a quarter of the faceplate, two half shafts on which the regulating element is rigidly fixed while the faceplate is rigidly mounted on the axle shaft extending beyond the housing, the lever of the regulating element is located on the axle shaft extending outside the housing, the lever of the regulating element is GSI to the faceplate by a fixing element arranged in one of the faceplate orifices.

In the faceplate, in addition to the through holes located along the arc in one of the quarters of the faceplate, a cutout located along the arc can be made in the other quarter of the faceplate. In the cutout is a bolt screwed into the housing and designed to fix the position of the regulatory element in the housing. A hole can be made in the lever of the regulating element for connecting to the rod, the other end of which, in turn, is connected to the actuator.

The technical result in the second invention is achieved in that the disk regulating shutter comprises a housing, a regulating element located in the housing and rigidly fixed to the shaft, a regulating element lever located on the shaft, a faceplate in which through holes are made, located along an arc in a quarter of the faceplate, the faceplate is rigidly fixed to the shaft, the lever of the regulating element is attached to the faceplate with the help of a locking element located in one of the holes of the faceplate.

In the faceplate, in addition to the through holes located along the arc in one of the quarters of the faceplate, a cutout located along the arc can be made in the other quarter of the faceplate. In the cutout is a bolt screwed into the housing and designed to fix the position of the regulatory element in the housing. A hole can be made in the lever of the regulating element for connecting to the rod, the other end of which, in turn, is connected to the actuator.

The technical result in the third invention is achieved by the fact that the butterfly valve comprises a housing, a control element located in the housing and rigidly fixed on two axles, a faceplate in which through holes are made located in an arc in a quarter of the faceplate, the lever of the regulating element located on the axis extending beyond the housing, an electric actuator mounted on the housing, a rod, one end of which is connected to the lever of the actuator, and the other to the lever guide member, wherein the faceplate is rigidly mounted on the half that goes beyond the housing, and a regulating member lever secured to the faceplate by a fixing element arranged in one of the faceplate orifices.

The design of the rod may have such a design that would allow you to change its length.

The technical result in the fourth invention is achieved in that the disk regulating shutter comprises a housing, a regulating element located in the housing and rigidly fixed to the shaft, a faceplate in which through holes are made located in an arc in the quarter of the faceplate, a lever of the regulating element located on the shaft and attached to the faceplate, rigidly fixed to the shaft, using a locking element located in one of the holes of the faceplate, an electric actuator mounted on the housing, rod, one end of which is connected to the arm actuator, and the other arm with the adjusting member.

The design of the rod may have such a design that would allow you to change its length.

The invention is illustrated by drawings, where:

Figure 1 - regulating disk shutter according to the first embodiment (main view).

Figure 2 - regulating disk shutter according to the first embodiment (side view).

Figure 3 is a section aa.

Figure 4 - regulating disk shutter according to the third embodiment (main view).

Figure 5 - regulating disk shutter according to the third embodiment (side view).

6 is a section bB.

In the drawings, the details of the butterfly valves are indicated by the following positions:

1 - housing; 2 - a regulatory element in the form of a disk (hereinafter referred to as RE); 3 - semi-axis; 4 - semi-axis, part of which extends beyond the housing; 5 - support; 6 - a seal (rings); 7 - a cover; 8 - faceplate; 9 - the lever of the regulatory element (hereinafter the lever RE); 10 - a nut; 11 - washer; 12 - fixing element; 13 - a bolt; 14 - washer; 15 - electric actuator (hereinafter referred to as MEO); 16 - actuator lever (hereinafter, the MEO lever); 17 - thrust; 18 - fork; 19 - axis.

The regulation of pressure or flow occurs due to changes in the cross section of the gas pipeline (the degree of shutter opening), which is due to the position of the shutter RE.

In the housing 1 (see Fig. 2 and Fig. 5) of the shutter there is a RE 2 in the form of a disk, rigidly fixed to two half shafts 3 and 4. The shutter is not tightly closed. The gas flow in the closed position of the shutter (φ = 0 °) is not more than 1% of the maximum flow rate. The shutter is made complete with flanges designed for connection to the pipeline. Two axles are installed in bearings 5, which perform the function of sliding bearings. RE can rotate in the housing within 0 ° ≤φ≤90 ° depending on the required pressure or gas flow rate at the outlet of the shutter. The tightness of the shutter provides the packing 6, located in the hole in which the axis 4 is located, which extends beyond the housing. Cover 7 is fixed with screws.

On the axle shaft 4, extending beyond the housing, are located a round faceplate 8 and a lever 9 RE. For a fixed (rigid) installation of the faceplate 8, a square is made at the end of the half shaft (Fig. 3 and Fig. 6). The faceplate is designed to set the RE in the required initial position at which (φ> 0 °), and to adjust the position of the RE lever relative to the RE. The faceplate has through holes located in an arc in one of the quarters of the faceplate.

The lever 9 RE is located on the axis 4, which extends beyond the housing, and is secured from moving along the axis 4 by the nut 10 and the washer 11. The lever 9 RE has a welded fixing element 12, with which it is attached to the faceplate 8 in a predetermined position, due to the location a fixing element in one of the holes of the faceplate.

To change the starting position of RE 2 carry out the following procedure.

Unscrew the nut 10, move the lever 9 RE from the faceplate 8 and thereby remove the locking element 12 from the hole faceplate.

The axle shaft 4 is rotated with the faceplate 8 and the disk 2 rigidly fixed on it by the required angle, while the position of the RE lever 9 remains unchanged.

Re-fasten the lever 9 RE on the faceplate 8 with a fixing element 12 located in the subsequent hole of the faceplate, and tighten the nut 10.

In the shutter, instead of two axis, a shaft can be used (not shown in the figures). In this case, RE 2 is rigidly fixed to the shaft. For a fixed (rigid) fastening of the faceplate 8 on the shaft, a square is made. The lever 9 RE, located on the shaft, is attached to the faceplate 8 using a locking element located in one of the holes of the faceplate.

Changing the position of RE 2 in the first and second variants of the structural embodiment of the shutter is possible both manually and using the actuator.

For manual shutter options in the faceplate, along with holes located in one of the quarters of the faceplate, a through cutout is made in its other quarter (Fig. 1), located along an arc. In the cutout is a bolt 13 with a washer 14, screwed into the housing. For this, part of the body is made in the form of a cylindrical stand, to which the bolt 13 presses the faceplate. This allows you to fix the position of RE 2 in the housing 1.

For shutter options controlled by an electric actuator, a hole for connecting with a rod is made in the lever 9 of the electric actuator, the other end of which is connected to the actuator.

In the finished product, where the change of position of RE 2 is carried out by MEO 15, the MEO is fixed to the housing 1. For this, part of the housing is made in the form of a bracket in which holes are made for mounting the MEO. The MEO lever 16 and the RE lever 9 are interconnected by a thrust 17. The length of the MEO lever 16 and the RE lever 9 are equal. The hinge connection of the rod 17 with the levers RE and MEO is made using forks 18 and axles 19. It is possible to control the length of the rod 17, for example, using a threaded rod, which is part of the fork 18, and a nut. To open the shutter (figure 4), the MEO lever 16 is rotated clockwise. The lever 9 RE, connected to the lever 16 MEO using traction 17, rotates counterclockwise.

Using the faceplate 8 allows you to set the RE 2 in its original position, at which φ> 0 °. For example, when the shutter is located in front of the burner through the gap formed between the housing 1 and RE 2, the amount of gas necessary for igniting the burner is supplied to the burner.

In the initial position, the MEO lever 16 and the thrust 17 are arranged in almost the same line so that the angle between them is 180 °. This is done in order to reduce the speed of rotation of the RE relative to the speed of rotation of the lever MEO at small angles φ. Using the faceplate allows you to position the lever RE in the desired position.

Claims (10)

1. The valve is a disk regulating, comprising a housing, a regulating element located in the housing, a lever of the regulating element, characterized in that it further comprises a faceplate in which through holes are made located in an arc in a quarter of the faceplate, and two half shafts on which are rigidly fixed the regulating element, while the faceplate is rigidly mounted on the axle shaft extending outside the housing, the lever of the regulating element is located on the axle shaft extending outside the housing, the lever of the regulating element is attached to the plate with a fixing element located in one of the holes on the faceplate. 2. The butterfly valve according to claim 1, characterized in that in the faceplate, in addition to through holes located in an arc in one of the quarters of the faceplate, in another quarter of the faceplate there is a cutout located in an arc, in the cutout there is a bolt screwed into the housing and designed for fixing the regulating element in the housing. 3. The butterfly valve according to claim 1, characterized in that a hole is made in the lever of the regulating element for connecting to the rod, the other end of which, in turn, is connected to the actuator. 4. Regulating disk lock containing a housing, a regulating element located in the housing and rigidly fixed to the shaft, a regulating lever of the regulating element located on the shaft, characterized in that it further comprises a faceplate in which through holes are made located in an arc in a quarter of the faceplate , the faceplate is rigidly fixed to the shaft, the lever of the regulating element is attached to the faceplate with the help of a fixing element located in one of the holes of the faceplate. 5. The butterfly valve according to claim 4, characterized in that in the faceplate, in addition to the through holes located in an arc in one of the quarters of the faceplate, in the other quarter of the faceplate there is a cutout located in an arc, in the cutout there is a bolt screwed into the housing and designed for fixing the regulating element in the housing. 6. The butterfly valve according to claim 4, characterized in that a hole is made in the lever of the regulating element for connecting to the rod, the other end of which, in turn, is connected to the actuator. 7. Regulating disk lock containing a housing, a regulating element located in the housing, a regulating element lever, an actuator and a rod, one end of which is connected to an actuator lever and the other with a regulating element lever, characterized in that it contains a faceplate, which has through holes located in an arc in the quarter of the faceplate, and two half shafts on which the regulating element is rigidly fixed, while the faceplate is rigidly mounted on the half shaft outside the housing, ychag regulating member is located on the half that goes beyond the housing, and is secured to the faceplate by a fixing element arranged in one of the openings of the faceplate and the electric actuator is fixed on the housing. 8. The regulating disk lock according to claim 7, characterized in that the draft design is made in such a way that the adjustment of the length of the draft is possible. 9. The regulating disk lock, comprising a housing, a regulating element located in the housing, a shaft, a regulating element lever, an actuator and a rod, one end of which is connected to an actuator lever and the other with a regulating element lever, characterized in that it contains a faceplate in which through holes are made located in an arc in a quarter of the faceplate, while the regulating element and the faceplate are rigidly fixed to the shaft, the lever of the regulating element is located on the shaft and is attached to the faceplate with the help of a fixing element located in one of the holes of the faceplate, and the electric actuator is mounted on the housing. 10. The regulating disk lock according to claim 9, characterized in that the draft design is made in such a way that it is possible to adjust the length of the draft.

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