RU2742678C1 - Ram single preventer - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: single ram preventer refers to the equipment designed for sealing the wellhead of oil and gas wells in order to ensure the safe conduct of work to prevent and eliminate oil and gas water showings and open fountains, to protect the subsoil and the environment. The blowout preventer contains a one-piece alloy steel casing with upper and lower flanges, having a through axial channel for passing pipes down the well, a through side channel located perpendicular to the axial channel and closed with side covers. Inside the body, in the side channel, there is a ram valve containing two oppositely located dies, tubular for sealing pipes along the outer diameter or blind to block the through axial channel in the absence of pipes in the well. On the outer lateral sides of the preventer case, in the areas between the side covers, cavities are made, interconnected by through channels, located in pairs under the side channels and above the side channels, closed with removable covers and forming a sealed heating chamber, with each removable cover for supplying and removing the coolant fitting.

EFFECT: improved performance of the preventer at low temperatures.

1 cl, 5 dwg

Description

Single ram blowout preventer refers to the equipment designed to seal the wellhead of oil and gas wells in order to ensure the safe conduct of work to prevent and eliminate oil and gas water showings and open fountains, to protect the subsoil and the environment.

Known preventer (RU 39640 U1; [1]), containing a body with flanges for connection to wellhead equipment and an axial hole for lowering pipe assemblies into the well, movable rams for sealing pipes, located in horizontal cavities of the body, closed with side covers, each of which equipped with a two-stage drive screw, one stage of which has a threaded surface with right-hand winding, and the other stage with left-hand winding, horizontal cavities for accommodating movable dies are made partly in the body and partly in the side covers.

The disadvantage of the preventer [1] is the lack of heating and protection of the drive thread from contamination, which contributes to premature wear, creates a risk of jamming the screw drive of the ram and can lead to an emergency situation - depressurization of the preventer.

Known preventer (RU 2239694 C2; [2]), which contains a cylindrical body with upper and lower flanges, a vertical through hole and a cylindrical horizontal cavity perpendicularly intersecting with it, in which a locking element is installed with the possibility of rotation, including a seal made of elastic material and an annular cylinder. Dies and covers with seals are installed in the bore of the annular cylinder without the possibility of rotation. The mechanism for manual movement of the rams includes a threaded rod, a nut, a cover with seals and a steering wheel. The nut is installed in the cover with the possibility of rotation and is fixedly connected to the steering wheel.

The disadvantages of the preventer [2] include the lack of heating and the complex design of the drive, which complicates its maintenance and operation.

Known preventer (RU 53359 U1; [3]), the body of which is made with upper and lower flanges and has a through axial channel for the passage of pipes down the well and two opposite side channels oriented perpendicular to the axial channel. A ram shutter is located inside the body, consisting of two oppositely located dies. The dies are installed in the side channels of the body and when moving towards the vertical axis of the body to the extreme closed position, pipes are sealed along the outer diameter. The side channels of the body are closed by side covers, each of which has an axial channel, which is a continuation of the side channel in the body. Through radial holes are made in the upper flange, each of which contains a means for fixing the sealing insert.

The disadvantage of the preventer [3] is the drive thread not protected from contamination and the lack of heating.

The lack of heating is a common disadvantage of known BOPs [1, 2, 3], which reduces the service life and reliability of their operation at low air temperatures.

The closest to the claimed invention in technical essence is the preventer selected as a prototype [3].

Disclosure of the essence of a technical solution

The problem to which the invention is directed is to improve the performance of the preventer at low temperatures.

The technical result is achieved by introducing a heating chamber into the design of the preventer, which provides heating of important parts of the preventer at low temperatures: prevents the accumulation of ice, wear of the seal and leakage; increases the reliability and safety of the preventer.

To achieve the specified technical result, a preventer is proposed containing a one-piece alloy steel casing with upper and lower flanges, having a through axial channel for the passage of pipes running into the well, a through side channel located perpendicular to the axial channel and closed with side covers. Inside the body, in the side channel, there is a ram valve containing two oppositely located dies, tubular to seal pipes along the outer diameter or blind to block the through axial channel in the absence of pipes in the well. The dies are installed in the side channel of the housing with the ability to move in a direction perpendicular to the axial channel. The preventer has one autonomous screw drive for each ram, installed in the corresponding side cover.

On the sides of the preventer body, there are tides with holes in which lifting loops are installed, through which a hoisting rope or slings can be passed for reliable transportation and installation of the preventer at the wellhead.

The through axial channel in the body is made either all cylindrical, or the part of this channel located above the side channels is made conical, with the large base of the cone facing outward, while when the part of the axial channel is conical, at least two lateral radial through holes are made in the upper flange , each of which is intended for sealed placement of the means for fixing the sealing inserts, while the working shank of the fixing means is made with a longitudinal flat. An annular groove is made on the end parts of the upper and lower flanges, which serves to accommodate the sealing ring.

The screw drive of the die is installed hermetically and is made with a two-stage screw located in the drive glass with a right-hand wound thread on one of its stages, interacting with the drive glass, and a left-hand threading on the other stage, interacting with the die pusher located with the ability to move in the drive glass. The end of the shoulder on the screw serves as a stop for the screw movement when closing the dies. To protect the screw threads from contamination, a cover is installed on the square shank of the two-stage screw. To control the position of the movable ram in the preventer case, a groove is made on the drive glass, and the distance between the edge of the casing and the hexagonal part of the cup is correlated with the movement of the movable ram from one extreme position to another. A steering wheel is installed on the square shank of the drive screw.

The upper flange design with at least two through lateral radial holes, predominantly located relative to each other at the same angle, in each of which a means for fixing the sealing insert is located, allows the insert to be securely fixed in the preventer and to safely carry out repair work on the well. The presence of a longitudinal flat on the working shank ensures reliable pressing of the sealing insert to the axial channel, which creates additional conditions for preventing emissions and open fountains.

According to the claimed invention, cavities are made on the outer side sides of the preventer housing in the areas between the side covers, which are interconnected by through channels located in pairs under the side channels and above the side channels, closed with removable covers and forming a sealed heating chamber, with each removable cover for supplying and the coolant outlet is equipped with a union. Heating of the BOP body and ram sealing elements increases the service life of ram sealing elements and ensures reliable wellhead sealing at low temperatures.

The invention is illustrated by the present description and the figures:

figure 1 is a general view of the preventer;

Fig. 2 is a disassembled preventer;

Fig. 3 is a sectional preventer, side view;

Fig. 4 is a sectional preventer, front view;

Fig. 5 is a cross-sectional view of the blower plate drive;

The preventer contains a casing 1 with an upper flange 2 and a lower flange 3. The casing 1 is made of one-piece alloy steel and has lugs with holes with rigging loops installed in them 5. The casing 1 has a through axial channel 4 for the passage of pipes lowered into the well and a through lateral channel 6. The part of the through axial channel 4 located above the lateral channel 6 can be made in the form of a truncated cone 7 made in the upper part of the preventer housing 1 and a cylindrical section 8 constituting the rest of the channel 4. The conical section 7 faces with its large base 9 to the outside of the upper flange 2. The side channel 6 is located perpendicular to the axial channel 4. Outside the housing 1, the side channel 6 is closed by the side covers 10 and 11.

Inside the body 1, in the side channel 6, there is a ram valve, which consists of two oppositely located dies 12, designed to seal pipes along their outer diameter or to block the through axial channel 4 of the body 1 in the absence of pipes in the well. The dies 12 are installed in the side channel 6 of the body 1 and can move in this channel in a direction perpendicular to the axial channel 4 of the body 1.

Each ram 12 has an autonomous screw drive 13, which is installed in the side covers 10, 11. The screw drive 13 of the ram 12 contains a two-stage screw 15 located in the glass 14 of this drive. The two-stage screw 15 has a section 16 with a right-hand wound thread on one of its stages, interacting with the nozzle 14, and a section 17 with a left-side winding thread at its other stage, interacting with the pusher 18 of the corresponding die 12.

On the square shank 19 of the two-stage screw 15, a casing 20 is installed. Thanks to the edge of the casing 20 and the groove 21 of the cup 14, it is possible to check the position of the die 12 inside the casing 1. The distance between the edge of the casing 20 and the hexagonal part of the cup 14 is correlated with the travel of the movable die 12 from one extreme position to another. Each two-stage screw 15 has a shank 19 for mounting the helm 22 of the screw drive 13. The limiter for the helm 22 is the end of the annular projection 23. The other end of the projection 23 serves to limit the movement of the screw 15 when the rams 12 are closed.

When the upper part of the axial channel is tapered, the upper flange 2 has at least two through lateral radial holes 24, which can be located both at the same angle relative to each other, and at different angles. Each hole 24 is intended to accommodate a means for fixing 25 sealing inserts, the working shank 26 of which is made with a longitudinal tapered flat, interacting with the tapered surface of the sealing insert. On the end part of the flanges 2, 3, annular grooves 27 are made to accommodate sealing rings.

On the outer sides of the housing 1, in the areas between the side covers 10, 11, covering the side channel 6, there are sealed heating cavities 28 and 29, closed by removable covers 30 with fittings 31, 32 for supplying and removing the coolant under pressure. The heating cavities 28 and 29 are interconnected by means of through channels 33, located in pairs in the housing 1 under the side channel 6 and above the side channel 6. Between the housing 1 and the covers 30 there are spacers 34 for sealing the heating cavities 28 and 29. The covers 30 are fixed on body 1 with screws 35. The holes in the fittings 31 and 32 are closed with transport plugs 36.

The preventer works as follows.

When using a preventer, its lower flange 3 is installed on the wellhead flange and secured. In the initial state, the dies 12 are located in the extreme open position. To ensure the sealing of pipes placed in the well and preliminarily fixed by means of fixation 25 placed in the radial holes 24. By rotating the steering wheels 22, autonomous screw drives 13 are actuated. The screw 15 moves along the thread of section 16 in the nozzle 14, moving the pusher along the thread of section 17 18, which moves the rams 12. As a result, the rams 12 move towards the center of the axial channel 4 from their extreme open position to the extreme closed position, in which they come into contact with the pipe to be sealed and press it tightly. Depressurization of pipes is carried out by moving the dies 12 to the extreme open positions in the reverse order. When the screw 15 moves, the edge of the casing 20 installed on it, moving above the surface of the cup 14, by its position relative to the groove 21 and the hexagonal part of the cup 14, performs indication, indirectly indicating the position of the die 12 in the casing 1. In the open position of the drive 13, the casing 20 closes the thread screw 15 and protects against contamination. In the absence of pipes in the well, the axial channel 4 is blocked with blind dies, which can be installed instead of the pipe rams 12 in the side channel 6, which for this move by an autonomous screw drive 13 towards the center of the axial vertical channel 4 of the housing 1.

At negative temperatures, to prevent freezing of the dies 12 to the housing 1, the preventer is heated. When the dies 12 are in the closed position and are in contact with the housing 1, the supply of the heat carrier (liquid or gaseous) to the heating cavity 28 is carried out through the fitting 31 of the heating cover 30, and the outlet through the fitting 32 on the other heating cover 30 on the opposite side of the housing 1. For this the fittings 31 and 32 are connected to the corresponding lines (not shown) of the heating system, having previously removed the plugs 36. The coolant passes through the fitting 31 into the heating cavity 28, passes through the through channels 33 into the heating cavity 29 while heating the housing 1, and exits through the fitting 32 Heat from body 1 is transferred to dies 12. Heating of body 1 and dies 12 leads to defrosting of the frozen fluid and condensate preventing the movement of dies 12 in the side channel 6 of housing 1. The coolant circulates from the nozzle 31 through the heating cavity 28, through channels 33, the heating cavity 29 and is discharged through the fitting 32. The coolant supply eliminates freezing (sticking) of the dies 12 to the body 1 and side covers 10, 11 of drives 13 at negative temperatures.

The preventer ensures safe work at the well, prevention of blowouts and open gushers, protection of subsoil and the environment in accordance with the requirements of regulatory documents.

The proposed design of the heating chamber allows heating each plate from four sides (bottom, top, two side). The use of a heating chamber expands the operational capabilities and ensures reliable operation of the preventer at low temperatures. In addition, using the proposed design of the heating chamber, it is possible to eliminate the disadvantages of these analogues and prototype. Thus, the claimed solution meets the criterion of the invention "novelty". The implementation of this invention does not require large expenditures and promotes rapid industrial development. The preventer is easy to maintain and allows to prevent blowouts and open gushers of oil and gas wells during repair work, which preserves the ecological balance of the environment. The blowout preventer is manufactured in accordance with TU and GOST.

Claims (1)

A blowout preventer containing a one-piece alloy steel casing with upper and lower flanges, the upper flange has at least two through lateral radial holes for installing sealing inserts fixing means in them, a through axial channel for the pipes running down the well, a side channel located perpendicular to the axial channel , a ram valve, consisting of two oppositely located rams and two autonomous screw drives of rams with protective covers, characterized in that the sealed heating chamber is formed by two cavities that are made on the outer lateral sides of the preventer case in the areas between the side covers, these cavities are interconnected through channels, located in pairs under the side channel and above the side channel and closed with removable covers, while each removable cover for supplying and removing the coolant is equipped with a fitting.

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