UA60459A - Hydro-blow dampener - Google Patents

Abstract

A hydro-blow dampener has placed in sequence on the side of the pump a node of a back gate, with a shutoff element as a disk, a housing for placing on it at least one differential valve-controller of automated action, this is made as installed in vertical position cylindrical housing with placed in its lower hart saddle and side opening for the working being worked out medium passing, coupling rod with closing element of the valve-controller. The over-plunger of the cylindrical housing is connected by pulse pipe with the back gate in the area before the place of installation of the disc for back gate. The node of the back gate is made as an insertion in horizontal part of the pipeline, with placed on rotary shaft disc shutoff element, with installed throttle for passage of working medium, and is equipped at the part of the shaft going outside by movable element of the sensor for disc position control. The housing is made tubular, horizontal, with support plate at the down part and flange at the upper part to connect the prescribed number of differential valves – controllers of automated action. The rod with shutoff element of the valve-controller is made as a plunger with not compensated areas of the upper and the lower sides, is provided I the lower part with shutoff element, as an insertion with spherical surface in the place of contact with the edge of the saddle. At the axis of the plunger there is provided an opening with installed in it throttle of prescribed cross-section. At the upper end of the plunger there is installed shockproof dampener of springy material. Openings of the valve-controller feeding working medium are uniformly arranged in circle and connected by means of branch pipes with the cavity of the housing. At that, the differential valves-controllers are placed to common removable receiving chamber, this is fixed to the flange of the housing with possibility of angular replacement with respect to the feeding openings, for orientation of the discharge pipe of receiving chamber in the needed direction. The plunger of the valve-controller is made composed, with possibility of angular motion of the spherical surface with respect to the axis of the side guide part that installs itself with respect to the edge of the saddle of the lower shutoff element. The outer surface of the shockproof dampener of the plunger is equipped with support separation element, this prevents its close contact at impact with the cover of the valve-controller. The over-plunger cavities of all the plunger valves-controllers are connected with one collector equipped with the valve for air discharge and connected to the pulse pipe.

Description

Description of the invention

The invention relates to devices for the protection of pressure pipelines against hydraulic shocks, in particular for 2 applications in mine drainage.

It is known that in order to fully ensure the trouble-free and reliable operation of hydraulic transport systems, they must be equipped with all the necessary means of shock protection. Examples of placement of anti-shock protection with different profiles of pressure hydraulic transport systems of various technological purposes, as well as structural schemes of various used compensators, are given in section 5.4 "Evaluation of hydraulic 70 shock with applied anti-shock measures"; A.M. Kurganov, A.F. Fedorov "Hydraulic calculation of water supply and drainage systems" Leningrad, Stroyizdat, 1986, pp. 122-135.

Hydraulic shock in water pipes is caused by a rapid change in the speed of fluid movement, which is accompanied by a large change in pressure.

As a rule, a non-return valve or gate is installed on the pressure pipeline immediately after the pump, 12 directly behind which devices for extinguishing hydraulic shocks are placed.

The purpose of non-return valves and shutters is to prevent the possibility of reverse flow in pipelines. Valves and shutters operate automatically under the influence of the energy of the working medium transported through the pipeline.

Normative documents for the design of mine water discharges stipulate that special devices must be provided for the protection of pipelines against possible hydraulic shock when the height of water rise is 40 Ohm and more. In the conditions of modern mine drainage, as a rule, steel pipelines are used for a single-stage rise of water to the surface to a geometric height of 1,200 m or more at an assumed water movement speed of 2-3 m per second". The actual length of the pipeline is usually assumed to be 100 m more than the geometric length. 29 In general in this case, sudden changes in the speed of movement of water in the mine pipeline can occur in pumping "installations during start-up, stop and adjustment. Particularly dangerous pressure fluctuations in mine drainage installations are observed when the electric motors of the pump drives are suddenly turned off. In this case, in the absence of special devices to protect against hydraulic shock, the pump is destroyed, because in such an emergency mode, the usual control valve cannot be used instantly (see F. 30 V.G. Geyer, H.M. Tymoshenko "Shachtnye ventilatornye i vodotlyvnye utstaliya" M., Nedra, 1987 , ch. 4.9, p. IC o) 218-227).

The pressure change in the process of hydraulic shock in the pipeline has the form of an oscillatory process decaying over time, caused by the propagation of first a forward shock wave and then a reverse shock wave. "in 35 Assuming the speed of propagation of a pressure wave in a pipeline filled with water equal to 1300 ms", the frequency c of pressure fluctuations can be estimated by the formula: t-- 4 where: " 40 C is the speed of propagation of a pressure wave, me"; шщ с Г - the length of the pipeline, m. y With regard to mine conditions, the specified formula for the frequency of oscillations looks like: я т- 35,

Naoyu -100 45 where:

Me, Ngyeom - height of water rise. aw! Therefore, the frequency of pressure fluctuations decreases with the increase in the height of the ascent from 0.65s7 for 400m to 0.25s7 for 1200m. e This value is close to the natural frequency of pipeline oscillations, therefore, there is a danger of resonance, c 20 as a result of which the pipeline can be destroyed.

In the conditions of the mining industry, the method of protection of injection pipelines is successfully applied in mines by installing non-return valves on intermediate horizons or in the middle of the pipeline, which at the same time is sectioned into two shorter pipelines. As a result, the static pressure decreases and the duration of the hydraulic shock phase is shortened. Experimental studies made it possible to establish the selectivity of the operation of non-return valves during the operation of water discharge units, while in shorter pipelines have a faster attenuation of wave processes and the pressure in the pipelines decreases. However, pipeline sectioning is not used in mine conditions. because it significantly complicates the water discharge system (V.M. Popov "Rudnychnye vodootlyvnye utsany", M. Nedra, 1983, pp. 271-280). 60 Oscillography of the operating modes of water discharge units showed that hydraulic shock is most dangerous in injection pipelines of a large diameter and at great geodesic depth of mines.

The use of only non-return valves for extinguishing hydraulic shock in these conditions is ineffective due to the low reliability of the pipeline and the need to completely eliminate the occurrence of a shock wave. The assessment of known methods of protection against hydraulic shock shows that the use of automatic shock absorbers is promising, because they work on the principle of resetting part of the working medium transported from the injection pipeline.

Direct and indirect action hydraulic shock absorbers are known. In extinguishers of the first type (with safety valves or regulator valves), the movement of the executive element is carried out by the energy of the working

The environment is controlled by a pressure drop measuring device that occurs in the initial stage of hydraulic shock, and in indirect action extinguishers this operation is implemented by an auxiliary drive that uses the energy of a special amplifier. For a number of years, modifications of the indirect action hydraulic shock absorber designed by the Donetsk Polytechnic Institute (DPI) have been developed, protected by copyright

USSR for inventions: a.s. USSR Mo 464751, E16K 47/00, blvd. May 11, 1975; assistant USSR Mo 773367, E 16K 47/10, Bul. 7/0 Mo. 39, 1980; and. with. USSR Mo 992883, R16K47/10, bull. May 4, 1983; a.s. USSR Mo 1681107, R16K 47/10, R16!- 55/02, Bul. Mo 36, 1991.

The known disadvantages of the above structures of hydraulic shock absorbers include: firstly, the need to use an auxiliary fluid, such as, for example, in USSR Mo 464751 and assistant. USSR Mo 773367, and in the last solution, the hermetic elastic chamber must be filled with an anti-corrosion liquid and 7/5 compressed gas; secondly, the difficulty of adjusting and plugging holes with mechanical impurities, which are abundant in mine waters. To protect chokes, it is necessary to insert special filters into the structure of the extinguishers.

Also known are the automatic valves-suppressors of hydraulic shocks of the "Ukrvodgeo" system, the action of which is based on the hydraulic principle: they open when the pressure increases or decreases against normal and discharge part of the water from the pipeline, thereby reducing the pressure. The extinguisher is designed for pumping equipment, when the hydraulic shock begins with the phase of reduced pressure near the check valve. The absence of springs increases the reliability of the construction, which is facilitated by the movement of executive devices directly by the energy of the working environment of the injection pipeline.

Here and further in the text, the terms are used in accordance with DSTU 2611-94 "Pipeline fittings of general industrial purpose. Terms and definitions", and not as in the sources of information.

In the conditions of operation of the water discharge equipment, two schemes for using automatic extinguishers are recommended: « 1) installation of an extinguisher behind the non-return valve and discharge of water into the sump and use of the extinguisher as a shock-free non-return valve (V.M. Popov "Rudnychnye vodootlyvnse utsanyi", M., Nadra, 1972 , p. 261). 2) using almost the same scheme for discharging water through the pump. In mine conditions, the second BZ scheme is practically unacceptable, because it leads to the inevitable breakdown of centrifugal multi-section pumps, which are most often used in water discharge equipment. i am

Both schemes of using the hydraulic shock absorber provide for its installation together with the "E" check valve, which is an integral element of the hydraulic shock extinguishing system, and therefore the design and operation of the damper must be considered only together with the check valve. at

In the first scheme, the cylinder of the damper body, in which the regulator valve is located, is connected with impulse tubes through the pressure distributor to the pipeline in such a way that the regulator valve of the damper is in the closed state. At a certain ratio of pressure in the pipeline before and after the non-return valve, the damper regulator valve opens, resets the working medium and reduces the pressure in the pipeline to the specified value. To return the valve-regulator of the damper to its initial position and to stop the reset of the working medium, the distributor connects the above-piston space of the cylinder with the pressure pipeline to the /-- s check valve. During the start-up of the pumping unit, the distributor connects the extinguisher cylinder with the discharge pipeline to the non-return valve and prepares it for operation. ;" The disadvantages of the known device include the fact that the movement of the covering element of the regulator valve during its opening and closing is carried out not only directly by the pressure drop of the working medium, but with the use of a special oil brake. Duration of operation

Ge» of the regulator valve is -.. 40-50 sec., as a result of which there is a shock pressure drop during the hydraulic shock, as well as a significant amount of water discharge during its closure. o For mine drainage conditions, this creates significant additional difficulties for re-starting the pump in operation.

In the vast majority of cases, during the operation of mine drainage facilities, a direct hydraulic shock occurs when the duration of closing the check valve is less than the duration of the hydraulic shock phase.

Ge) It was experimentally established that the duration of operation of non-return valves and shutters of different diameters for closing is within 0.6-1.5 seconds. Hence, as a result of significant dynamic loads, there are requirements for high strength parameters of the specified devices.

The disadvantages of the known device include the complexity of the design due to the presence of auxiliary mechanisms, such as an oil brake and its lever drive system; distributor and its hydraulic system

P" control, as well as the difficulty of maintaining strict alignment of the mating surfaces of the moving parts of the valve-regulator of the overlapping element, rod, piston, rod with the surfaces of the fixed parts: the seat, flange, cylinder body, cover. The well-known hydraulic shock absorber according to the authors' application for the issuance of a patent of Ukraine for the invention No. 2001031525 dated 03.06.2001, intended for extinguishing the direct shock of the first phase of hydraulic shock. When the pump unit is turned off, the shock wave, reflecting from the end of the pipeline, near the non-return valve, communicates through the openings of the flow passage of the working medium of the valve-regulator with the atmosphere, and the hydraulic shock is practically absent. The following phases of the shock wave (harmonics) after the valve is activated and the part 65 of the working medium is reset will be small in amplitude. At the same time, the regulator valve quickly reacts to pressure drops: it opens when the pressure increases and closes when the pressure decreases, preventing the discharge of a large volume of the working medium from the injection pipeline. The presence of a hole with a throttle in the disk of the check valve ensures a gradual and smooth equalization of the pressure of the working medium on both sides of the check valve after extinguishing the hydraulic shock, the duration reduces the delay in the increase of pressure in the impulse pipeline and in the space above the plunger, and also smoothes the front of the shock wave and softens the effect hydraulic shock in the area after the disc, which increases the quality of hydraulic protection.

In accordance with this decision, several hydraulic shock absorbers were manufactured, which showed satisfactory performance and the possibility of bringing them to the stage of production of an adjustable series.

However, in the process of their experimental operation, some structural defects were discovered. It turned out that 7/0 Relatively large dimensions of the extinguisher, especially in height, significantly complicate or make impossible its installation even in limited conditions, for example, in pipe tunnels, which is characteristic of many deep mines of Donbas.

Another disadvantage of the prototype is cases of the regulator valve plunger hanging in the upper position during hydraulic shock, since the shock absorber made of elastic material placed on its upper end is usually "sucked" to the upper cover of the regulator valve, thereby reducing its working area in 7/5 Comparison with an unchanged area of the lower end, as a result of which the plunger hangs in the upper position. Only after the pressure pipeline is emptied and the pressure under the plunger drops, it can return to the working position under the influence of its own weight, that is, it will fall back onto the seat.

The inspection in mine conditions also showed that to ensure the tightness of the regulator valve, high precision in the manufacture and installation of all elements is required, and above all, the alignment of the overlapping 2o elements and the exclusion of any water leaks through the sealing elements.

In addition, in limited installation conditions, it is difficult to obtain information about the position of the non-return valve (open" or "closed") both during maintenance and when automating the processes of managing the operation of the mine drainage.

The specified earlier decision of the authors according to the Ukrainian application No. 2001031525 was selected as a prototype, which coincides with the claimed invention in terms of purpose and a number of essential features.

Common essential features of the prototype and the claimed invention are the following: "consecutively placed on the pipeline behind the pump - a non-return valve assembly with a disc-shaped covering element in which a throttle for the passage of the working medium is installed; housing for placing several or at least one differential valve-regulator of automatic Ge!

From Action, made in the form of a vertically installed cylindrical body of the regulator valve with a high-strength seat located in its lower part and side holes for the passage of the working medium that is discharged, which is placed in a receiving chamber with a pipe for discharging the working medium, a rod with an overlapping element -(" f of the indicated regulator valve is made in the form of a plunger made of porous anti-friction material with pores and its contact surface filled with grease with uncompensated areas of the upper and lower ends, o provided in the lower part with an overlapping element in the form of a high-strength insert with a spherical "o surface at the point of contact with the sharp the edge of the specified high-strength saddle, a hole is made along the axis of the plunger with a throttle of a given diameter placed in it, an anti-shock shock absorber made of elastic material is installed on the upper end of the plunger, and its upper part is connected by an impulse tube to the pipeline to the place of installation of the non-return valve disk and. "

The basis of the invention is the task of such improvement of the hydraulic shock absorber in order to reduce its dimensions due to the features of the design of its individual elements, to improve the tightness and reliability of the operation of the overlapping elements and, due to this, to guarantee the stability of the technical characteristics in conditions of long-term operation in difficult mine conditions.

The problem is solved by the fact that in the hydraulic shock absorber, which includes a non-return valve assembly with a disc-shaped covering element in series placed on the pump side, in which a throttle for the passage of the working medium would be installed, a housing for placing on it at least one differential valve-regulator of automatic action of a vertically installed flanged o cylindrical body with a seat placed in its lower part and a side opening for the passage of the working medium that is triggered, placed in a receiving chamber with a discharge pipe, a stem with an overlapping element of the indicated regulator valve is made in the form of plunger with uncompensated areas on the upper and lower ends, provided in the lower part with a covering element in the form of an insert with

Ge) with a spherical surface in the place of contact with the edge of the specified seat, a hole is made along the axis of the plunger with a throttle of a given cross-section installed in it, an anti-shock shock absorber made of elastic material is installed on the upper end of the plunger, and the above-plunger part of the cylindrical body is connected by an impulse tube with a non-return valve in the zone to the place of installation of the non-return valve disk, according to the invention, the non-return valve unit is made in the form of an insert in a horizontal section of the pipeline with a

P" rotating shaft with a disc covering element, equipped with an outwardly moving element of the disc position control sensor, the body is made of tubular horizontal with a support platform from below and with a flange from above for connecting a given number of differential valves-regulators of automatic action, holes, because what fails the working environment, which evenly spaced around the circumference and connected with the help of nozzles to the body cavity, while the specified differential control valves are placed in a common removable receiving chamber, which is attached to the body flange with the possibility of its angular rearrangement relative to the inlet holes for the orientation of the chamber discharge pipe receiver in the required position, the plunger of the regulator valve is made of a component with angular mobility of the spherical surface relative to the axis of the lateral 65 guide part, which itself is installed relative to the edge of the seat of its lower overlapping element, the outer surface of the shock absorber of the specified plunger is secured baked with a resistive separating element, which prevents its tight contact when hitting the cover of the regulator valve, and the over-plunger cavities of all over-plunger valves-regulators are united by a single collector equipped with an air release valve and connected to an impulse tube.

The above features constitute the essence of the invention, because they are necessary in any variant of the invention and sufficient to achieve the set task.

A specific difference of the claimed extinguisher is that the side guide part of the composite plunger is made in the form of a cup, in the cavity of which there is a support insert with an inner hemisphere, in which the upper spherical part of the overlapping element is installed with the possibility of angular mobility rotation, and on 7/0 the specified spherical surface is installed on its opposite end, separated by a distance equal to the turning arm, while the covering element is fixed from axial movement relative to the cup.

A specific difference is that the fixation from the axial movement of the overlapping element is made in the form of a split ring, installed in a groove inside the glass and pressed to the upper spherical part of the overlapping element with pressure screws.

Another specific difference is that the thrust separating element on the upper end of the shock absorber of the plunger is made in the form of a ring or a polygon of different cross-section, provided with a cut across the creation for the passage of the working medium. A specific difference is also that the indicated thrust separation element is made in the form of a ring or a polygon of different cross-section and is provided with local notches in the places of contact with the cover.

An additional difference is that in order to ensure self-installation in the closed position, the shutter is equipped with a counterweight placed on the rotary shaft of the disc shutter element.

The causal relationship between distinctive features and the technical result achieved is as follows.

The horizontal design of the shock absorber housing with the vertical connection of several regulator valves, which are placed in one common receiving chamber, significantly reduces the overall dimensions of the dampers and allows them to be mounted in the immediate vicinity of the pumps in limited mine conditions, for example, in pipe tunnels. "

The location of several regulator valves with a uniform step around the circle in the receiving chamber allows you to change the position of the discharge pipe in the desired place by repositioning it together with the receiving chamber in the assembly with the regulator valves relative to the flange inlets. Placement on anti-shock Ge! with shock absorbers of regulator valves of thrust separating elements, made in the form of rings or polygons of triangular, semicircular or circular cross-section with a cross-section and/or notches, o ensures constant flow of the working medium between the covers of the regulator valves and the plungers with a slight reduction of the upper working area of the plungers, thereby preventing them from hanging in the upper position and ensuring accelerated closing of the regulator valves after extinguishing the pressure peak of the shock wave with a slight draining of the working medium. co

The execution of the plunger of the regulator valve as a component with the separation of its side guide cylindrical part from the lower part with the overlapping spherical element and their connection through a lever with a spherical joint allows the overlapping spherical element to self-install relative to the sharp edge of the seat and thereby ensure the tightness of the regulator valve. "

The execution of the non-return valve in the form of an insert with a rotating single-disc blocking element, in c, if necessary, with a counterweight, and with a moving element of the sensor for monitoring the position of the blocking element on the shaft, allows you to increase the reliability of the non-return valve and obtain reliable information about;" the position of its overlapping element at any time.

Combining the above-plunger cavities of all regulator valves with a single annular or herringbone collector, which is connected to the air release valve and through an impulse tube of increased cross-section with a non-return valve, allows you not to put valves on each regulator valve, but to get by with one, as well as reduce hydraulic losses in the pipelines, which affects the quality of the hydraulic shock absorber. o Fig. 1 - a general view of the hydraulic shock absorber. Fig. 2 - differential valve-regulator. І5» Hydraulic shock absorber - a safety valve for automatic protection of the system against an increase in pressure 5o above the working medium by discharging the excess of the working medium, as well as for stopping the discharge when the working pressure is restored.

Depending on the cross-section of the pipeline, working pressure and contamination of the working environment, the hydraulic shock absorber can consist of a non-return valve and several regulator valves, the number of which is determined by the flow rate and pressure of the working medium, as well as the required degree of reliability in the work of the damper.

Fig. 1 shows a hydraulic shock absorber with a return disc shutter 1 and four

P" by valves-regulators 2 of the medium being transported, placed in the common receiving chamber 3, fixed on the flange 4 of the extinguisher body 5.

The non-return valve is made in the form of an insert and consists of a housing 6, inside which together with the shaft 7. shifted relative to the diametrical section of the housing, the overlapping element - disc 8, in which the replaceable throttle 9 is installed, is turned inside. and disk, while it can be made both at an angle to the axis of the inlet opening, as shown in Fig. 1, and along its axis. In the first case, the force of the disk's own weight is enough to cover the opening, and in the second case, it is necessary to apply additional force to the shaft 7 from the load 65 Through the lever located both inside the case and outside it. For the second case, when the shaft 7 is moved outside the housing, in addition to the lever with the load, a movable element of the sensor for monitoring the position of the overlapping element - a disc in the return valve - is installed on it. Shaft 7 can be extended outside the body in both directions to install the lever and the moving element of the sensor in a position convenient for maintenance.

The receiving chamber C is made in the form of a cylindrical capacity with a lateral tube 10 for discharging the working medium and with the housings of 11 regulator valves 2 mounted in the covers with a uniform pitch around the circle. With a large number of regulator valves (more than six), the housing of one of them is located in the center of the circle .

The position of the discharge pipe 10 can be changed in space by repositioning the receiving chamber C on the flange 4 relative to its openings 15, which are connected through the nozzles 12 to the cavity of the damper housing 5. 70 The differential regulator valve 2 is shown in Fig. 2 and consists of a housing 11, a plunger 13 , covers 14 with a fitting, saddles 15.

The body is cylindrical with side holes 16 evenly spaced around the circle for the passage of the flow of the working medium, which is thrown out, with belts on the outer surface for pressing or welding to the covers of the receiving chamber and a seat in the lower part for pressing in the saddle 15.

The plunger 13 of the differential valve is assembled, consisting of a cylindrical body 17, a variable throttle 18, an anti-shock absorber 19 with a stop element 20 and a cover element 21 hinged inside the body.

The body of the plunger 17 is made in the form of a cylindrical cup with grooves on the outer surface for lubrication, with a threaded hole on the upper end for mounting and dismounting the plunger in the body and for installing the 2o Replaceable throttle 18, as well as with a groove for mounting the shock absorber 19.

A thrust element 20 is installed on the shock absorber, which prevents tight contact and suspension of the shock absorber 19 to the cover 14 of the regulator valve in the event of hydraulic shock. The retaining element can be made in the form of a ring or a polygon of triangular, circular or semicircular cross-section with cuts 22 and/or notches 23 in the places of contact with the covers, which ensures the same pressure of the working fluid on both sides of the ring, that is, over the entire upper area of the plunger 13.

The covering element 21 of the plunger is made in the form of a rod, the lower part of which is provided with an insert or surfacing with a spherical surface 24 in the place of contact with the sharp edge of the saddle 15, the upper part is made in the form of a sphere 25, and there is a through hole in the center. The center of the sphere 25 and the center of the lower spherical surface 24 of the insert or surfacing are separated by some distance, which is the rocking shoulder of the lower sphere 24. Gee! z The upper sphere 25 rests on an insert 26 of antifriction material with an inner hemisphere and a threaded hole in its center. The covering element 21 in the housing 17 is fixed with screws 27 through a split elastic o-ring 28. "g

The above-plunger cavities 29 of the regulator valves are connected to each other by a collector through the cover fittings 14

ZO, which in turn is connected by a pulse tube 31 with a return gate 1 to its disc 8. Collector о zv It can be made annular or in the form of a herringbone. An air release valve 32 is installed on the collector from the upper zone of the extinguisher after it is filled with the working fluid.

The body 5 of the extinguisher is made tubular with flanges and movable rings at the ends, as well as with a support platform and a leading flange 4, connected through the nozzles 12 to the body.

The hydraulic shock absorber is mounted on the horizontal section of the pipeline between the pump and the valve, in close proximity to the pump. in c The hydraulic shock absorber works as follows: . Under the influence of the energy of the working medium transported through the pipeline, the return valve 1 and? opens automatically - the disc 8 turns and the inlet opening 6 opens. Simultaneously with the opening of the return valve, the working medium is supplied through the impulse tube 31 and the ring collector 30 in

Above-plunger cavities 29 Its on nozzles 12 in under-plunger cavities 33 regulator valves 2, which are

Ge" are differential, since the area of the cavities 29 is greater than the area of the cavities 33. Under the action of its own weight and the force arising due to the difference in the areas of the above- and below-plunger cavities 29 and 33, the plunger 13 is pressed against the sharp edge of the saddle 15 by the spherical surface 24 of the insert, closing the passage of the working of the medium through the 5" valve-regulator 2 to the drain. The plunger is made of components with a oscillating spherical surface 24, which ensures a tight overlap of the regulator valve, even if the opening of the body 11 and the sharp edge are not aligned with the seat 15. The seat and insert are made of a high-strength material of the hard alloy type, which ensures reliable

It improves the operation of the valve during closing, breaking up particles contaminating the working environment, for example, particles of coal and rock.

In emergency situations, for example, when the electric motor of the pump is suddenly turned off, the pressure in the pipeline to the back valve 1 drops and the latter closes - disc 8 blocks the inlet. The pressure also drops in the above-plunger cavities 29. The pressure after the disc 8 in the post-disc cavity in the damper housing first drops,

P" and then, as a result of the hydraulic shock, begins to rise. When the pressure increases by a certain amount, sufficient to create a force to lift the plungers 13, they rise. The upward movement of the plungers 13 is hydraulically resisted by the working medium located in the superplunger cavities 29. To overcome this resistance, part of the energy of the shock wave movement is spent. The speed of movement of the plungers in both directions depends on the cross-sectional area of the throttle openings 18, as well as the shape of the cross-section along the length.

The volume of the working medium displaced by the plunger from the cavity 29 is equal to the volume flowing through the throttle opening 18, since the working medium is practically incompressible. In the superplunger cavity 29, the speed of movement of the working medium reaches hundreds of meters per second, which consumes a large amount of energy. 65 Plunger 13 upon receiving a shock wave, causing the working medium to be throttled through the throttle opening 18, expends the energy of its movement, loses speed and gradually stops. To reduce the volume of the above-plunger cavity 29, the movement of the plunger 13 is stopped by the thrust element 20 and the shock absorber 19 at a certain low speed of the plunger.

The energy of the first harmonic of the hydraulic shock wave is transferred to the energy of the movement of the plungers 13 and the working medium in the above-plunger cavities 29, throttling the working medium through the holes in the throttles 18, as well as through the impulse tube Ziv subdisc cavity of the return valve.

When lifting the plungers 13, the passage of the working medium is released through the holes 16 in the housings 11 into the receiving chamber 3, and from it, through the discharge pipe 10, to drain into the atmosphere or into the drain pipeline.

As a result of the above, the pressure cannot rise above the set value, and the hydraulic shock is eliminated. 7/0 After a slight draining of the working medium, the pressure in the pipeline and in the under-plunger cavities 33 drops to the working pressure, the differential plunger under the action of its own weight and the force arising due to the difference in the areas of the above- and under-plunger cavities moves to its initial position, blocking the drain. The hole in the disc 8 with the throttle 9 acts as a bypass, equalizing the pressure on both sides of the disc 8. After closing the regulator valve, the hydraulic shock absorber is ready for action.

Claims (6)

The formula of the invention 1. Hydraulic shock absorber, containing a non-return valve unit with a disk-shaped covering element placed in sequence on the pump side, a housing for placing on it at least one differential valve-regulator of automatic action, made in the form of a vertically installed cylindrical housing with a located in its lower part with a seat and a side hole for the passage of the working medium that is activated, a rod with an overlapping element of the indicated regulator valve, and the above-plunger part of the cylindrical body is connected by an impulse tube with a non-return valve in the area to the place of installation of the disc of the non-return valve, which is distinguished by the fact that the non-return valve assembly is made in the form of an insert in the horizontal section of the pipeline, with a disk "blocking element" placed on the rotary shaft, with an installed throttle for the passage of the working medium and equipped with a moving element of the sensor for monitoring the position of the disk on the external part of the shaft, the housing is made tubular horizontal with a support platform from below and with a flange from above for connecting a given number of Fo zo differential valves-regulators of automatic action, a stem with an overlapping element of the indicated valve-regulator is made in the form of a plunger with uncompensated areas of the upper and lower ends, and) provided in the lower part with an overlapping element in the form of an insert with a spherical surface in the place "t of contact with the edge of the specified saddle, a hole is made along the axis of the plunger with a throttle of a given cross-section installed in it, an anti-shock shock absorber made of elastic material is installed on the upper end of the plunger, holes "2 Regulator valves that supply the working medium, uniformly placed around the circle and connected with the help of nozzles to the cavity of the housing, while the indicated differential valves-regulators are placed in a common removable receiving chamber, which is fixed to the flange of the housing with the possibility of its angular rearrangement relative to the supply holes for the orientation of the discharge pipe i of the receiving chamber in the required position, the plunger of the regulator valve is made folded with angular mobility of the spherical surface relative to the axis of the lateral "20 guide part, which itself is installed relative to the edge of the saddle of its lower overlapping element, the outer surface of the shock absorber of the specified plunger is equipped with a resisting separating an element that prevents its tight contact when hitting the cover of the regulator valve, and the super-plunger cavities of all "z" super-plunger valves-regulators are united by a single collector equipped with an air release valve and connected to an impulse tube. 2. Extinguisher according to claim 1, which differs in that the side guide of the folded plunger is made in the form of a FO glass, in the cavity of which there is a support insert with an inner hemisphere, in which the upper spherical part of the overlapping element is installed with the possibility of angular mobility, and on its opposite end , the specified spherical surface is installed at a certain distance, which is the arm of the swing, while the overlapping element is fixed from axial movement relative to the glass. 3. Hydraulic shock absorber according to claims 1, 2, which differs in that the fixation from axial movement about the overlapping element is made in the form of an elastic split ring, installed in a groove inside the He glass and pressed to the upper spherical part of the overlapping element with pressure screws. 4. Hydraulic shock absorber according to claims 1-3, which is characterized by the fact that the resisting separation element on the upper end of the shock absorber is made in the form of a ring or a polygon of different cross-section, equipped with a cross-section of the generator for the passage of the working medium. 5. Hydraulic shock absorber according to claims 1-3, which is characterized by the fact that the resisting separating element » is made in the form of a ring or a polygon of different cross-section and is equipped with local notches in the places of contact with the cover. 6. Hydraulic shock absorber according to claim 1, which differs in that, to ensure self-installation in the closed position, the return shutter is equipped with a counterweight placed on the rotary shaft of the disc shutter element. b5