RU2240462C1 - Sliding shutter - Google Patents

Abstract

FIELD: oil-extracting industry; pipelines control sliding shutters.

SUBSTANCE: the invention is dealt with the field of a pipeline control sliding shutters and is intended for use as shutters in the oil-extracting industry. The sliding shutter contains a body, mounted in it saddles, a sliding shutter, a cover, a non-retractable spindle, a threaded bush interacting with the latter, a package of cup-type seals of the spindle with a claw nut and a run indicator. The package of the cup-type seals of a spindle is additionally supplied with a petalled cup, a supporting ring, a spacing washer, a spacing washer. Lobes of the additional petalled cup are directed to the claw nut side and oppositely to direction of the lobes of three other petalled cups. The internal and external diameters of the spacing rings are supplied with hollows. In the package of the cup-type seals of the spindle there is a separator with a central stepwise hole. This hole is located between two pairs of the petalled cups. In the cover there is a channel located coaxially to the horizontal hole of the separator, which has a threaded valve. The valve is made in the form of a hollow cylinder, the inner surface of which has a threading, using which a plunger is inserted. The channel is filled in with a semisolid lubricant. The purpose of the invention is to increase duration of service life of the sliding shutter at the expense of repeated rehabilitation of serviceability of the package of cup-type seals of the spindle without a stop in operation of the sliding shutter.

EFFECT: the invention allows to increase duration of service life of the sliding shutter.

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Description

The invention relates to the field of mechanics, namely to pipe fittings, in particular to gate valves, and can be used in the oil industry.

A known design of a slide gate valve in which a non-retractable spindle is sealed relative to the cover by one sealing ring with a coil spring. Sealing the connection is achieved due to the elasticity of the coil spring and the integrity of the petals of the sealing ring installed in the bore of the cover with a gap, without axial compression (Catalog “Gate valves for fountain valves”. Firm DKG-EAST, Hungary. P. 13).

A slide gate valve is known, comprising a housing, a gate, a cover, a non-extendable spindle with a travel indicator mounted behind a flywheel seat on a threaded surface, with a latch that interacts with a stopper mounted on the lid, equipped with a threaded sleeve and an adjustable stop, in the grooves of which a travel indicator latch is inserted. The seal between the cover and the spindle is achieved by three cuffs installed in the bore of the cover with a gap, without axial compression. Sealing of the compound is achieved due to the elasticity of the cuffs and their integrity (patent 2111399, RF, publ. 05.20.98).

However, the seal designs of these slide gate valves do not have a mechanism for restoring the seal performance without replacing it. The operation of gas well fittings in the Far North indicates the need to develop a design that ensures the elimination of gas leaks through elastic or worn cuffs without moving the gate relative to the set position.

The objective of the invention is the creation of a slide gate valve, allowing the repeated restoration of the spindle seal without stopping the slide gate.

The problem is solved in that in a slide gate valve comprising a housing, seats installed therein, a slide, a cover, a non-extendable spindle interacting with the last threaded sleeve, a spindle lip seal package with a tension nut equipped with a travel indicator, an additional spindle lip seal package cuff, support, spacer and intermediate rings, while the petals of the additional petal cuff are directed towards the tension nut and opposite to the direction of the petals of the three other of the petal cuffs, while the inner and outer diameters of the spacer rings are provided with fillets; in addition, a spacer with a central stepped hole is installed in the spindle lip seal package located between two pairs of flange cuffs, and a channel is made in the lid coaxially to the horizontal opening of the spacer, in which a valve is installed in the form of a hollow cylinder, the inner surface of which is threaded, with the help of the latter a plunger is installed in the cylinder, at m plastic channel filled with grease.

The gate valve is explained with a detailed description, a specific example and drawings, in which:

figure 1 depicts a General view of the slide gate valve in longitudinal section;

figure 2 depicts on an enlarged scale the contact point of the surfaces of the gate and seats, in the position of the gate “Closed”;

figure 3 depicts on an enlarged scale a package of lip seal spindle;

FIG. 4 is an enlarged view of a spindle with a lip seal package in cross section AA.

The gate valve comprises a housing 1 provided with a channel 2, saddles 3 and 4 installed in the housing 1 (Fig. 1). The gate 5 installed in the housing 1 is provided with a channel 6. A bore 7 is made in the upper part of the gate 5, in which a threaded sleeve is installed 8. The input and output turns of the sleeve 8 are equipped with wipers 9 and 10. A cover 11 is installed on the housing 1. Between the housing 1 and a cover 11 has a sealing gasket 12. The threaded end of the non-extendable spindle 13 is installed in the sleeve 8 and is located in the channel of the gate 5. On the spindle 13 there is a shoulder 14, which is located with a gap B in the socket of the cover 11. The surfaces of the shoulder 14 and the socket of the cover 11 are conical and n iterty together.

Saddles 3 and 4 (figure 2) are installed in the bores of the housing 1 and have two o-rings of elastomeric material. Rings 15 and 16 are installed between the gate 5 and the saddles 3 and 4, respectively. Rings 17 and 18 are installed between the housing 1 and the saddles 3 and 4, respectively. The outer diameter of the rings 17, 18 is made larger than the outer diameter of the rings 15, 16. In the channels of the seats 3 and 4, recesses are made. On the outer diameters of the seats 3 and 4, shields 19 and 20 are fixed, covering the shoulders with the width of the gates (Fig. 1). On the central axes of the flaps 19 and 20, below the seats there are holes 21 and 22 of small diameter, for example 5 mm.

A bore is made in the cover 11 (Fig. 3), in the latter a spindle lip seal package is installed. The spindle lip seal package consists of support rings 23, 24, 25 and 26, flange cups 27, 28, 29, 30, the upper intermediate ring 31, the middle intermediate ring 32, the lower intermediate ring 33, the spacer 34 and the spacer rings 35, 36, 37, 38. The inner and outer diameters of the spacer rings 35, 36, 37, 38 are provided with fillets B, C, D, E. The width of the spacer rings 35, 36, 37, 38 (Fig. 4) is slightly larger than the inner size of the petal cuffs 27 , 28, 29, 30 between the petals. The rings 23, 24, 25, 26 and the separator 34 are made of durable material, such as metal, the cuffs 27, 28, 29, 30 are made of an elastomeric material, for example a metal-fluoroplastic composition, the spacer rings 35, 36, 37, 38 are made of elastic material, for example rubber.

A tension nut 39 is installed on the spindle 13 (Fig. 1). A channel 40 is made in the cover 11 opposite the spacer 34. The channel 40 is cylindrical and filled with plastic mass. A valve 41 is installed in the channel 40. A plunger 42 is installed by means of a thread in the valve 41. A cup 43 is fixed on the cover 11. A thrust bearing 44, support rings 45 and 46, a fusible insert 47 and a cracker 48 are mounted on the cap 43. A spindle 13 is mounted via a pin a threaded sleeve 49, a threaded plate 50 with a screw 51 is fixed to the last. A ring 52 is mounted between the threaded sleeve 49 and the glass 43 above the fusible insert 47. A cover 53 is mounted on the glass 43. The cover 53, the sleeve 49, the bar 50 and the screw 51 are a mechanism direction indicator showing polo The gate is open-closed. Helm 54 is mounted on spindle 13.

Gate valve works as follows.

The valve assembly and installation of the spindle lip seal package are as follows.

In the housing 1, saddles 3 and 4 are installed (Fig. 1), while the rings 17 and 18 are installed in the grooves of the seats 3 and 4 with little effort, so that they protrude 0.1-0.2 mm above the surface of the saddles. Rings 15 and 16 before zealousing have the shape of a truncated cone; after installation with zealing, they protrude 0.4-0.5 mm above the surface of the saddles. Then the gate 5 is installed with the non-retractable spindle 13 screwed into it and the housing cover 11. A spindle lip seal package is installed in the bore of the cover 11. Using the tension nut 39, a small preload is applied to the spindle lip seal package. Then, a cracker 48, a thrust bearing 44 with support rings 45 and 46, a fusible insert 47 are installed. Then a glass 43 is installed. Then, a threaded sleeve 49 is rigidly fixed on the non-extendable spindle 13. The travel indicator mechanism is mounted and the helm 54 is mounted.

The valve is controlled by the helm 54 (figure 1). The position of the gate 5 is controlled by a non-extendable spindle 13. When the steering wheel 54 is rotated clockwise, the non-extendable spindle 13 feeds the gate 5 to the bottom of the housing 1. The valve is closed. In this case, the travel indicator shows the position of the gate “Closed”.

Under the influence of the medium, the gate 5 (figure 2) presses the output seat 3 to the housing 1, creating a stressed state in the sealing rings 15, 17 due to their compression, sufficient to seal the connection of the output seat 3 - gate 5 - case 1. Rings 15, 16 the gate connection 5 is sealed - the seats 3, 4, and the rings 17, 18 are sealed the body 1 - the seats 3, 4 connection. At high pressure of the medium, the rings are compressed to metal, the sealing rings 15, 16, 17, 18 are completely buried in the grooves. At low pressures, the compression to the metal does not occur, the o-rings 15, 16, 17, 18 protrude from the seats 3, 4, and the sealing is ensured by the interference between the housing 1 and the package consisting of seats 3 and 4, the gate 5 and the sealing rings 15, 16, 17, 18. The interference fit is provided when assembling the slide gate valve and is calculated. In rings 17 and 18, the stress state is always maintained, not only from the linear interference, but also from the stress state of the material, when its shape tends to take its original state. Rings 17 and 18 are made of material less rigid than rings 15 and 16, but more elastic, able to maintain their properties during deformation until the seats 3, 4 and the housing 1 come into contact.

When the steering wheel 54 is rotated counterclockwise (Fig. 1), the spindle 13 feeds the gate 5 upward until the channel 2 of the housing 1 coincides with the channel 6 of the gate 5, while the threaded sleeve 8 acts as a leash. Wipers 9 and 10 mounted on the input and output turns of the threaded sleeve 8 are made of elastomeric material. The direction indicator shows the position of the gate “Open”. The valve is open.

In the event of a fire, the fusible insert 47, made of fusible material, burns out, and since its height is greater than the gap B, then under the pressure of the medium the non-extendable spindle 13 rises up and seals the connection body 1 - cover 11. The conical surfaces of the shoulder rubbed together 14 and the cover slots 11 guarantee the tightness of the slide gate valve when the lip seal package burns out.

The spindle lip seal operates as follows.

A pack of lip seal during assembly with a tension nut 39 give a small preload (figure 3).

The medium is held by petal cuffs 27, 28, 29, 30, since under the pressure of the medium and spacer rings 35, 36, 37, 38 their petals are unclenched.

Filings B, C, D, E, made on the inner and outer diameters of the spacer rings 35, 36, 37, 38 (Fig. 4), allow the medium to enter the inner cavity of the petal cuffs 27, 28, 29, 30, since the width of the spacers rings 35, 36, 37, 38 are larger than the inner size of the petal cuffs between the petals.

The wear of the cuff petals from the rotation of the non-extendable spindle 13 to a certain point is compensated by spacer rings 35, 36, 37, 38, which, when axially tightened, constantly press the petals of the cuffs 27, 28, 29, 30 to the radially sealed surfaces and compensate for the wear of the cuff petal from rotating non-extendable spindle 13.

In the case of leaks resulting from wear of the flap cuffs 27, 28, 29, 30, the restoration of tightness is achieved by injection of plastic mass. Through the valve 41 (FIG. 1), a portion of the plastic mass is placed in the channel 40. Then, a plunger 42 is screwed in, which pushes the mass into the lip seal of the spindle (Fig. 2). The plastic mass flows through the channels of the separator 34 and diverges up and down. It goes up through the gaps between the ring 32, the spindle 13 and the cover 11, reaches the spacer ring 36 and through the fillets B, C, D, E fills the inner cavity of the cuff 28. Under the action of the mass, the petals of the cuff 28 diverge, and the cuff is pushed up, acting through the upper intermediate ring 31 to the spacer ring 35, which in turn unclenches the petals of the cuff 27. Down the mass goes through the gaps between the support ring 25 and the spindle, reaches the cuff 29, bends its petals and passes into the cavity to the cuff 30, completely filling it and air ystvuya in cuff 29 as previously described. The injection of plastic mass can be done in several stages, but with the last cycle, the specific pressure in the injected mass should be greater than the pressure of the medium.

Thus, the tightness of the flap cuffs 27, 28, 29, 30 is restored. The injected mass is under pressure and fills the volume from the cuff 28 to the cuff 30, thereby creating an additional tight cavity. The mass located between the cuffs 29 and 30 also seals the cuff 30, since it acts on its petals and on the petals of the cuff 29. If due to any reason the pressure in the cavity between the cuffs 27 and 29 drops and the medium passes, then there remains another working cavity filled with plastic mass between the cuffs 29 and 30.

Thus, two petal cuffs, which are installed symmetrically with respect to the axis of the lower intermediate ring, create an additional sealing cavity, the latter provides reliable sealing of the non-sliding spindle of the slide gate valve.

The proposed design of the slide gate valve allows, through simple and non-laborious operations to restore the tightness of the spindle lip seal, to significantly increase the duration of the gate valve operating cycle.

Claims (1)

A gate valve comprising a housing, seats installed therein, a gate, a cover, a non-extendable spindle interacting with the last threaded sleeve, a spindle lip seal package with a tension nut, equipped with a travel indicator, characterized in that the spindle lip seal package is equipped with an additional spindle lip seal, supporting , spacer and intermediate rings, while the petals of the additional petal cuff are directed towards the tension nut and opposite to the direction of the petals of the other three petal m the jaws, while the inner and outer diameters of the spacer rings are provided with fillets, in addition, a spacer with a central stepped hole is installed in the spindle lip seal package located between two pairs of flange cuffs, and a channel is made in the lid coaxially to the horizontal hole of the spacer, in which a valve is installed, made in the form of a hollow cylinder, the inner surface of which is threaded, using the latter a plunger is installed in the cylinder, while the channel is filled grease.

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