RU2238464C2 - Universal wedge valve - Google Patents

Abstract

FIELD: valving.

SUBSTANCE: universal wedge valve has hermetically sealed housing with a seat, lid, rotatable plate made of a wedge, and drive. The drive is made of a link-lever mechanism. The rotatable plate is suspended on the unmovable rotation axle and made integral with the link frame of the link-lever mechanism. One of the sides of the link frame is beveled at an angle providing the valve to be wedged.

EFFECT: enhanced reliability.

2 dwg

Description

The invention relates to the field of mechanical engineering and industrial valve engineering, in particular to structures and devices of pipeline valves designed to move liquid, gaseous and bulk materials.

Industrial pipe fittings are widely used in a wide variety of piping systems, assemblies, installations operating under the influence of a conducted medium and under the influence of pressure and temperature. The main purpose of pipeline valves is to control the flow of the medium and the parameters characterizing these flows: speed, pressure, flow, etc., by blocking the flow or opening it.

A large number of pipeline valve designs are known, which are subdivided depending on the functional purpose and method of shutting off the medium flow into various types, for example, a valve, a valve, a valve, a valve, a valve, etc. In essence, all known types of valves are valves that change the area and configuration the cross section of the flow passage in the process of opening and closing, while the movement of the shut-off element of the valves of the above types with respect to the medium flow and the passage section from ichayutsya path, e.g., valves reciprocating movement parallel to the flow direction and perpendicular to the plane of the flow cross section, while the valves in the fluid flow valve disc overlaps the motion perpendicular to the flow direction.

To control the valve (opening - closing), it is very important that the shutter (valve, spool, damper, plug, etc.) is moved from the “closed” position to the “open” position and vice versa with a minimum path length and with minimal effort drive. At the same time, in the “open” position, the flow area must be maximum to ensure maximum throughput of the pipeline system and its minimum hydraulic resistance.

According to the control method, the valve can be controlled and automatically acting. Controlled valves can be either manual or automatic. Hand-operated fittings are equipped with a flywheel or handle. As an automatic drive, electromechanical, electromagnetic, membrane, piston, bellows, etc. can be used.

Various types of wedge gate valves are widely known in valve industry, see fig. 2.656; fig. 2.66; fig. 2.67; fig. 2.68 [Pipeline Valve Designer Handbook - Leningrad, Mechanical Engineering, 1987]. A common characteristic feature of gate valves from this series is that the sealing element for them is a double-sided wedge with corresponding contact surfaces of the seats (two seats) and a wedge movement mechanism with a sliding spindle.

Wedge gate valves allow both to block the flow of the medium, forming a tight connection of the wedge with the seats, and to fully open the bore in the valve body integrated into the pipeline system.

A positive property of the valves is a low hydraulic resistance when the wedge is fully open (rising). However, the traditional design of wedge gate valves predetermines a number of serious drawbacks, such as

- the impossibility of finding the wedge in an intermediate position, because it is subject to destructive dynamic loads from the medium flow, i.e. the wedge must be either in the “closed” position or in the fully open position, which requires a large working stroke (> DN);

- transfer of working force during sealing and opening directly through the sealing working surfaces of the wedge;

- jamming in the closed position under the influence of thermocyclic and other stresses and deformations;

- leakage due to the natural destruction of the sealing surfaces of the wedge and seats at the time of maximum loads during closing and opening (contact stresses);

- the inability to use valves as a regulatory device;

- relatively low resource and maintainability.

The design of the check valve is known, see fig. 2.115 [Reference designer of pipe fittings. - L.: Mechanical Engineering, 1987], in which the axis of rotation of the disk (flaps) is taken out of the passage section. Such rotary valves are not sensitive to contamination of the medium, they can control the position of the flap and use damping properties to prevent water hammer when the valve closes abruptly. However, this design, when the valve is open, constantly vibrates due to hydrodynamic disturbances arising in the flow. When this happens, the oscillatory movement of the shutter valve gate and, as a result, intense wear of the axis and eyes of the shutter.

A rotary valve is also known, see ibid., Fig. 2.118, which by design is non-return-locking and equipped with an electric drive. It implements the principle of a rotary disk shutter operating in the mode when the flow of the working medium is directed under the shutter plate. However, a valve of this design requires a large force to block the flow, as well as a large stroke.

Also known is a technical solution implemented in US patent No. 3623696 and manufactured under the brand name ″ Camflex ″ ^R. This solution is a shutter in the form of a disk of a special design, the axis of rotation of which is eccentrically offset relative to the axis of the input (output) section of the nozzles. In this solution, the shutter disk moves along a very complex curved path to ensure tightness and requires the application of powerful forces from the drive mechanism, which significantly complicates the manufacture of this valve.

There is also a technical solution according to RF patent No. 02117845 “Check valve”, the design of which allows you to combine the functions of the control and check valve. However, to perform these functions, it is necessary to readjust it each time. In this solution, the role of the regulating mechanism is played by a spindle mounted in the housing cover, in which a removable rod can be located, abutting against a stop mounted on the shutter. The use of the design of such a technical solution is very limited due to the need for special readjustment for its use as a check valve or for regulating the flow rate. Moreover, to switch from one mode of use to another each time, additional adjustment of the valve and shutdown of the pipeline system are required, since This valve is not airtight.

In general, many modern valve designs available fully meet their purpose and work reliably enough in various types of pipeline transport. However, it should be noted that most of the considered types of reinforcement have, as a rule, monofunctional application. Provided that it is necessary to saturate the pipeline with valves of various purposes with a rather high cost, calculated in the tens of thousands of dollars per unit, this inevitably leads to a rise in the cost of products or systems that comprise such valves. Therefore, the most urgent issue in this industry today is the development of universal valves, combining multifunctional capabilities and reducing the range of valves used in pipelines.

The technical solution of the reinforcement device according to the German patent DE 888489 was chosen for the prototype, the design of which allows it to be used as a direct-flow shut-off valve for shutting off and opening the flow of the working medium. This valve allows you to open a fully bore due to the combination of translational and rotational movements of the locking element - wedge plates with reverse taper. However, this device has a number of significant drawbacks that limit its industrial use, namely:

- a wedge swivel plate, made at the same time with the gripping mechanism (hook) associated with the spindles that control the movement of the plate from the valve actuator, in the process of opening and closing does not have a strictly fixed position at each moment of movement, because surfaces of the valve are not provided for in the valve design, limiting the position of the wedge plate itself during linear (translational) and rotational motion relative to the seat (sealing) surface of the seat. This makes it impossible to exclude spontaneous deviation or displacement of the position of the plate relative to the sealing surface of the saddle both at the time of landing during closing and at the time of lifting when opening. In addition, under the influence of the dynamic forces of the working medium, vibrations, high-speed pulses and other disturbing factors caused by the instability of unsteady processes that occur during the operation of valves, damage and deformation of the sealing surfaces of the valve assembly can occur, which may result in valves and piping systems in which it is installed in an inoperative state;

- the pins with which the wedge plate in the prototype is installed in the guides are loose and, therefore, the axis of rotation of the plate changes its position. For this reason, it cannot occupy a fixed position at some angle of rotation in the area of the flowing part of the valve, i.e. cannot perform the functions of regulating the parameters of the working environment.

- another disadvantage of the prototype is the large amount of the working stroke (movement) of the locking member (plate), which it performs from the "closed" to the "open" position, despite the combined (double) linear and rotational movement. To fully open the cross-section of the flowing part of the plate, it is necessary to make a stroke approximately equal to the diameter of the nominal passage of the valve (DN). This primarily affects the excessively large dimensions and weight of the reinforcement.

- the device of the reinforcement according to the prototype has an overly complex, multi-link drive mechanism, including various helical and gear drives, which is also its disadvantage.

- Among the shortcomings, one can also mention the insufficient rigidity of the design of the locking power mechanism of the drive, when the reactive component of the load at the moment of valve closure, which occurs when the wedge bearing surface of the plate comes in contact with the lead screws, is directed at a large angle to the longitudinal axis of the lead screws and facilitates their pressing and bending, which can lead to depressurization of valves even at low environmental pressures and loads.

The problem solved by the present invention is to create such a valve design that combines the capabilities and advantages of different types of valves, namely, it is a butterfly valve that has minimal hydraulic resistance to the flow of the medium, has a shorter trajectory of movement of the shut-off element to fully open the passage section , does not require much effort to control the flow of the working medium when creating tightness in the shutter and does not require the transfer of working control efforts through the sealing surfaces of the plates and seats.

The main technical result, which provides a solution to this problem, is to reduce the working stroke of the spindle due to the ratio of the lever arms, as well as reducing the force when closing and opening the shutter. This is achieved due to the fact that the wedge swivel plate is suspended on a fixed axis and the principle of its jamming during translational movement of the drive mechanism is used. At the same time, as the drive rotating the plate, the linkage mechanism is used, which has a crank link.

The solution to this problem can be implemented by a combination of essential features available in an independent claim, i.e. when creating a universal multi-purpose valve, which can operate both a shut-off and a shut-off and regulating body in a wide range of operating parameters, including pressure and temperature, for a wide variety of working environments.

To explain the essence of the invention, a schematic representation of the universal wedge shutter shown in figures 1 and 2 is attached.

The design of the universal wedge lock consists of a housing 1, in which a seat 2 is mounted, which is blocked by a rotary disk 3 suspended on the axis 17. The plate 3 is made integral with the link 4, in the groove of which there is an articulated roller 16 belonging to the rotary lever 5, which can rotate around the stationary axis 15. The lever 5 through the hinge 14 is connected to the link 6, which in turn is pivotally connected through the axis 13 to a sealed slide, in the form of a bellows 8, a spindle 9 of a manual screw drive with a threaded sleeve is integrated inside the latter 10 and the second flywheel 11. The free end of the bellows 8 via a slide hinge 12 is coupled with the spindle 9.

In the presented design, the axes 17 and 15, around which the wings 4, with the plate 3 and the lever 5, respectively rotate, are motionless. The remaining axes 16, 14, 13 and 12, belonging to the rocker-link mechanism system, interacting with the drive through the crank mechanism, are movable.

The trajectory of rotation of the lever 5 and the plate 3 with the wings 4 are shown by arrows A and B, respectively. The lower surface of the linear groove of the backstage 4, which coincides with the plane 1-1, is at the same time the working surface of the return wedge with an angle φ ° locked by the hinged end 16 of the lever 5.

The hinged end 16 of the pivoting lever 5 moves along a circular path indicated by arrow A. Moreover, when the shutter is closed, the hinge 16 acts on the surface of the rocker groove in the plane 1-1, and when opened, on the other surface of the groove parallel to the plane 1-1.

As shown in figure 1, the movement of the working medium under pressure Ru is directed under the plate 3. In figure 1 shows the closed position of the shutter, and figure 2 corresponds to the moment of full opening of the passage section of the flow part of the shutter body.

The working force at the moment the shutter closes from the reactive component of the load transmitted upon contact of the wedge surface with the movable end of the lever is directed along the longitudinal axis of the lever 5, passing through the centers of the hinges 16 and 15, at an angle α ° to the central axis of the flow part of the valve body. This creates the condition for reliable sealing of valves not only at low, but also at high pressures and loads.

The universal wedge gate is opened in the following sequence: by rotating the screw drive 9-10 through the flywheel 11, the hinged end 12 of the spindle 9 is driven by a hermetic bellows slider 8, which translates upward along the vertical axis of the shutter, through the hinge link 6, which converts the translational movement of the slider into rotational movement of the lever 5, lifting along the trajectory indicated by arrow A, the link 4 and the plate 3. When moving the spindle 9 by the magnitude of the stroke, plate 3 in place with the wings 4 make a rotation about the axis 17 along a path coinciding with arrow B by the value of the full opening of the shutter, as can be seen in figure 2.

To close the shutter, turn the handwheel 11 clockwise to apply a torque and, moving the spindle 9 along the shutter axis downwards, through the crank mechanism pos. 10-9-12-13-6-14-4, then through the rocker mechanism pos. 5-16-4-3 along the paths indicated by arrows A and B, put the plate 3 in the saddle 2 in the position indicated in figure 1.

Claims (1)

A universal wedge lock containing a sealed housing with a saddle, a cover, a rotary plate made in the form of a wedge, and a drive, characterized in that the actuator is made in the form of a rocker-lever mechanism, the rotary plate is suspended on a fixed axis of rotation and is integral with the rocker frame -lever mechanism, and one of the surfaces of the rocker frame has an inclined surface with an angle providing jamming of the shutter when it is locked.

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