RU2568256C1 - X-mas tree for operation of wells in conditions of active ingress of water and sand and its mode of operation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention is referred to oil and gas producing industry, and namely to design of X-mas tree used at gas wells, in particular, in conditions of active ingress of water and sand. The X-mas tree intended for wells operated in conditions of active ingress of water and sand includes locking devices, T-piece or cross-piece and throttle valve with upstream downhole wellhead baffle for liquids and mechanical impurities, which includes a case with a unit intended for separation of gas-liquid flow into phases installed in its upper part, while its lower part represents a holding tank for liquids and mechanical impurities. In the upper case part there is an inlet tube for gas-liquid flow and in the lower part of the shell there is an outlet tube for gas.

EFFECT: suggested invention allows improving reliability and efficiency of X-mas tree by preventing abrasive wear of the throttle valve and pipeline installed downstream at simultaneous reducing probability of hydrates and ice formation in drain pipelines of liquid and sand removal system without usage of heating elements.

17 cl, 2 dwg

Description

The invention relates to the oil and gas industry, in particular to the design of fountain fittings used in gas wells, in particular, in conditions of active water and sand development.

A well-known scheme of fountain valves for gas wells, containing the body of the pipe head, sub, root valve, root valve, cross or tee, as well as a buffer valve. There are side bends from the cross or tee, on which the valves and the throttle are installed. The throttle is used to limit and control the operation of the well in a mode in which the reservoir does not collapse and the sand is not carried out by the gas flow from the well (see GOST 13846-89. Fountain and pressure fittings. Typical schemes, basic parameters and technical design requirements). The disadvantages of this reinforcement include the fast abrasive wear of the throttle and the pipe after the throttle in the case of using fountain valves at the mouth of wells operating in conditions of active water and sand development.

A well construction is known (patent for PM RU 129551, 06/27/2013), including casing concentrically installed in it, with an elevator placed in them and wellhead equipment, which consists of sequentially placed column head, pipe head, Christmas tree. On the trunk of the Christmas tree there are root and root valves, as well as a gas vertical separator. In this case, the separator is placed parallel to the trunk of the Christmas tree by means of the upper and lower branches, which communicate with the trunk of the Christmas tree of the fountain below the root and above the root valves.

This design has several disadvantages. When the separator is turned off, a gas-liquid stream with small dispersion particles enters the throttle, resulting in rapid abrasive wear of the throttle and pipe after the throttle. When the separator is connected, there is a possibility of disruption of its operation and breakdown in climatic conditions with a negative ambient temperature. Thus, for example, hydrate or ice formation may occur in the separator catchment basin or in the channel for draining the liquid and sand from the separator catchment.

The technical result achieved is to increase the reliability and efficiency of the fountain valves by preventing abrasive wear of the throttle and the pipe installed after it while reducing the likelihood of hydrate and ice formation in the pipelines of the liquid drain and sand removal system without using special heating elements.

The inventive fountain fittings can be assembled at the factory and delivered to the well in assembled (block) form, namely as a single module.

Fountain fittings for wells operating in conditions of active water and sand development include shut-off devices, a tee or crosspiece and a throttle, in front of which a wellhead wellhead chipper for liquids and mechanical impurities is installed, which includes a housing in the upper part of which there is a device for separating gas-liquid flow into phase, and the lower part is a storage tank for liquid and solids. In the upper part of the casing there is a pipe for gas-liquid flow inlet, and in the lower part of the shell there is a pipe for gas outlet.

The bottom of the body can be made both conical and ellipsoidal. The housing or storage tank can be made vertical or horizontal, or spherical. The horizontal storage capacity is set in the case of a very large flow of warm gas-liquid sand mixture from the well. It was experimentally proved that the execution of the bottom is conical or ellipsoidal, and the case or storage tank vertical or spherical is the most preferable. Warm gas does not stagnate anywhere, therefore it does not have time to cool down and, therefore, it enters the shell warm, heating the body and bottom, which in turn reduces the energy consumption for heating the body, increases the reliability and efficiency of the process by reducing the likelihood of hydrate and ice formation.

It is possible to make the body of the chipper of an elastic material, for example, rubber.

The shell can be made of a transparent material, such as, for example, glass, plastic or plexiglass. The installation of a transparent shell reduces the use of additional measuring instruments, leaving only optical sensors, while increasing the efficiency of the fountain.

The apparatus for separating the gas-liquid flow into phases is made removable.

Between the shell and the housing, it is possible to install a gas-liquid flow swirl. Swirlers can intensify the process of passage of warm gas to the exit.

In the upper part of the storage tank there is an overflow fitting connected to the overflow pipe, which is located between the body and the shell and enters the pipe for gas outlet.

The casing has a vertical pipe for pumping liquid and sand that are separated from the gas-liquid flow and accumulate in the storage tank. A vertical pipe passes through the housing cover, on which a locking device with a manual, pneumatic or electric drive is fixed. In the pipe in its upper part there is a drainage hole.

In addition, the housing may contain one or more additional pipes for draining the liquid exiting on the side of the shell. Additional pipes can be located in different transverse and longitudinal sections along the height of the body, their lower ends can be placed at different distances from the bottom of the body, and drainage holes can be located in the upper sections of the pipes located inside the body.

A technological hole is made in the bottom of the housing for the extraction of mechanical impurities, for example, sand.

A technological hole can also be made in the lower part of the shell.

Conical fairings are installed in the upper part of the apparatus for dividing the flow into phases; fairings can also be installed in the shell lid. Fairings are installed to reduce the reduction of aerodynamic hydraulic pressure losses associated with a sharp change in speeds, as well as to help guide the movement of the separated gas.

In the upper part of the shell, between the cover and the apparatus for separating the flow into phases, an additional nozzle can be located for the output of the separated gas.

The invention is illustrated by drawings.

In FIG. 1 schematically shows a fountain with a chipper of liquids and solids.

In FIG. 2 schematically shows a General view of the wellhead wellhead chipper liquids and mechanical impurities (one of the special cases of the chipper).

Fountain fittings 1 for wells operating in conditions of active water and sand development include a sub 2 to the pipe head, locking devices 3, 4 and 5, a tee 6 or a cross (not shown in the drawing), a pressure gauge 7 and a throttle 8 with a pipe 9. In front of the throttle 9, a wellhead mouth chimney 10 for liquids and solids is installed, which consists of a vertical housing 11 with a conical bottom 13. In the upper part of the housing 11 there is an apparatus 15 for phase separation of the gas-liquid flow, and the lower part is storage tank 16 for liquid and solids. Around the housing 11 is a shell 17 with a cover 12. In the lower part of the shell 17 a pipe 18 is installed for the exit of the dried gas. In the upper part of the body 11 of the chipper is located pipe 14 for the entry of wet gas. In the upper part of the shell 17, between the cover 12 and the apparatus 15 for dividing the flow into phases, an additional nozzle 30 with a plug for separating gas can be arranged. An additional pipe 30 is installed to reduce unnecessary hydraulic losses of the device.

The housing 11 may be made of an elastic material, for example, rubber. This helps to prevent tearing of the case in case of expansion of the volume in case of unexpected freezing of the liquid.

The apparatus 15 for separating the flow into phases can be made removable (removable) to replace it in case of changes in the technological characteristics of the working medium: flow, pressure and composition of the shared medium. In addition, due to abrasive wear, changes in the flow rate of the gas-liquid mixture, flow rate, gas-liquid-solid phase ratio, the efficiency of the device for separating the flow into phases changes. The device 15 may have a special coating against abrasion, for example, polyurethane. In the upper part of the apparatus 15 there is a cone shaped fairing 29.

Between the shell 17 and the housing 11, a gas flow swirler 19 is sometimes installed, made in the form of profile blades or inclined plates attached to the housing, for example, by welding.

In the upper part of the storage tank 16 there is an overflow fitting 20 connected to the overflow pipe 21, which is located between the housing 11 and the casing 17 and enters the pipe 18.

The casing 11 has a vertical pipe 22 for draining the fluid, passing through the cover 12 of the casing 11, on which a manual, pneumatic, or electric actuator 23 is fixed. At the same time, a drainage hole 25 is located on the pipe 22 at its upper point inside the casing 11.

Also in the housing 11 there is at least one additional pipe 24 for draining the liquid, extending on the side of the shell 17, while on the additional pipe 24 at its upper point inside the housing 11 there is a drainage hole 25.

A fairing 28 is installed in the lid.

Fountain fittings for wells operated in conditions of active water and sand development works as follows.

The warm flow of the gas-liquid sand mixture from the well is directed through a sub 2 to the pipe head, then to a tee 6 or a cross (not shown in the drawing) and then through the inlet pipe 14 to the vertical casing 11 of the chipper 10, where the flow enters the apparatus 15 for phase separation (gas, liquid, solid), in which, due to gas-dynamic effects (rotation), all types of mechanical impurities and liquid are separated from the gas. So, for example, the apparatus 15 for phase separation may consist of a deflector and a separation bag. When gas strikes the deflector, a significant part of the liquid and solids flows down the deflector. The flow begins to spiral in a spiral and go down the inner wall. Part of the flow enters the drip pocket. Drops of liquid, along with sand, enter a pocket-droplet eliminator, hit its walls and flow down. Sand contained in the liquid settles to the bottom of the storage tank 16, and the water is above the sand.

In addition, gas flows into the separation bag, during which the gas temperature and pressure decrease. Inside, external and internal flows form. Due to the fact that the pressure in the lower part of the internal stream is less than in the external one, the external stream rushes down and mixes with the internal one, while the speed of the internal one decreases, the temperature increases, and the pressure and density also increase. The gas rises and exits the apparatus 15 for separating the flow into phases along the conical fairing 29, hits the housing cover 12, passes along the fairing 28 and is forced to enter the annular space between the outer wall of the housing 11 and the inner wall of the shell 17, dropping to the outlet pipe 18 in the lower part of the shell 17, while heating the entire surface of the housing 11, including the bottom 13 of the housing. The gas flow passing through the annular space is twisted due to the guide vanes of the swirler 19, which can improve heat transfer and additional separation of the liquid from the stream separated in the apparatus 15. Thus, the liquid that accumulates in the storage tank 16 will not freeze at negative ambient temperatures .

Since the gas enters the chipper moist and with mechanical impurities, wear of the apparatus is possible, which divides the gas-liquid flow into phases. For ease of replacement, the apparatus 15 is made removable and resistant to abrasion.

In the case of filling the storage tank 16 with liquid, there are several options for draining it. So, for example, a fluid (without sand) by gravity can drain from the overflow fitting 20 into the overflow pipe 21 and then through the throttle to the flow line from the well without destroying the throttle.

It is also possible to drain the liquid and remove part of the sand through a vertical drain pipe 22 through a locking device that can be opened using a manual drive, an air or electric motor 23, or drain through an additional drain pipe 24, which extends from the side of the shell 17. Moreover, a drain hole 25 is provided in the additional pipe 24 to eliminate stagnation of water in the additional pipe 24 after a cycle of draining the liquid. The liquid levels in the pipe and in the housing are aligned due to the flow of gas through the drain hole 25.

Accumulated solids (e.g. sand) can be removed through process hole 26.

Since it is possible that a small part of mechanical impurities can enter between the body 11 of the shell 17, a technological hole 27 is also provided in the lower part of the shell 17.

The present invention improves the reliability and efficiency of the fountain valves by preventing abrasion of the throttle and the pipe installed after it while reducing the likelihood of hydrate and ice formation in the pipelines of the liquid drain and sand removal system without using special heating elements.

Claims (17)

1. Fountain fittings for wells operating in conditions of active water and sand development, including shut-off devices, a tee or crosspiece, and a throttle, in front of which a wellhead wellhead chipper for liquids and mechanical impurities is installed, comprising a casing in the upper part of which a device for separating gas-liquid flow is installed into phases, and the lower part is a storage tank for liquid and mechanical impurities, in addition, a shell with a lid is located around the housing, and in the upper part the housing is pipe for gas-liquid flow input, and in the lower part of the sleeve tube is mounted to the gas outlet. 2. Fountain fittings according to claim 1, characterized in that the bottom is made conical or ellipsoidal. 3. Fountain fittings according to claim 1, characterized in that the housing or storage tank is made vertical or horizontal, or spherical. 4. Fountain fittings according to claim 1, characterized in that the housing is made of an elastic material, for example, rubber. 5. Fountain valves according to claim 1, characterized in that the apparatus for dividing the flow into phases is removable. 6. Fountain fittings according to claim 1, characterized in that a gas flow swirl is installed between the shell and the body. 7. Fountain fittings according to claim 1, characterized in that in the upper part of the storage tank there is an overflow fitting connected to the overflow pipe, which is located between the housing and the shell and exits into the pipe for gas outlet. 8. Fountain fittings according to claim 1, characterized in that the housing has a vertical pipe for pumping liquid through the housing cover, on which a locking device with a manual, pneumatic or electric actuator is fixed. 9. Fountain fittings according to claim 1, characterized in that the housing has at least one additional pipe for draining the liquid, extending on the side of the shell. 10. Fountain fittings according to claim 8 or 9, characterized in that a drainage hole is located on a vertical or additional pipe in its upper part inside the housing. 11. Fountain fittings according to claim 1, characterized in that a technological hole is made in the bottom of the housing. 12. Fountain fittings according to claim 1, characterized in that a technological hole is made in the lower part of the shell. 13. Fountain fittings according to claim 1, characterized in that a conical fairing is installed in the upper part of the apparatus for phase separation. 14. Fountain fittings according to claim 1, characterized in that a fairing is installed in the lid. 15. Fountain fittings according to claim 1, characterized in that in the upper part of the shell, between the cover and the apparatus for dividing the flow into phases, there is an additional nozzle for exiting the separated gas. 16. Fountain fittings according to claim 1, characterized in that the shell is made of transparent material. 17. The method of operation of the fountain according to paragraphs. 1-16, characterized in that the warm flow of the gas-liquid mixture from the well is directed through the sub to the pipe head, then into the tee or cross and then through the inlet to the vertical body of the chipper, where the flow enters the apparatus for phase separation, to separate all mechanical impurities and liquids that fall into the lower storage part of the housing, and the gas rises up, leaves the apparatus for separation into phases, hits the housing cover and is forced to enter the space between the outer wall to rpusa and the inner wall of the mantle, dropping to the outlet conduit, which is at the bottom of the shell, after which the purified gas is passed from the impurities through the throttle and into the conduit.

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