RU2247827C2 - Method for extraction of gas-hydrate deposits by drilling - Google Patents

Abstract

FIELD: gas extractive industry.

SUBSTANCE: method includes extraction of resource by mechanical drilling and extraction of slurry and rock pieces through well. Gas extraction is performed by horizontal drilling with washing and back expansion, with concurrent cleaning and separation of fresh extracted mixture and accumulation of gas. Delivery of expander of ultra-large working size to expansion place is performed through well subjected for backward expansion. Pressure, temperature and composition of washing liquid is adjusted in such a way, that free natural gas, freed during mechanical drilling, was dissolved in drilling mud and separated from it only after passing of separator through rotating preventer. Expander in form of rocker with cutters is used, expanding well diameter up to ten meters and more.

EFFECT: higher efficiency.

2 cl, 1 ex

Description

The invention relates to the gas industry, in particular to methods for developing gas hydrate deposits by drilling. Note: in this case, the gas hydrate deposit (GGZ) is destroyed mechanically (by drilling), and the resulting gas hydrate slurry enters the well and is transported to the surface by the current of the flushing liquid. Moreover, the decomposition of gas hydrate sludge into gas and water can occur both in the well itself and on the surface, in special separators.

There are known cases of gas hydrate production from GGZ through vertical rotational drilling, in which gas hydrate was extracted to the surface in the form of core columns or in the form of sludge [1]. But gas production methods based on this principle are not used in industry due to significant shortcomings: in vertical drilling, the volume of gas produced is limited by the diameter of the well and the thickness of the GGZ. Therefore, the volume of gas produced does not cover the costs. True, the volume of the wellbore in the GGZ can be increased by drilling its horizontal section to several kilometers. But at the same time, as the length of the well increases, its walls are periodically fixed with casing pipes. As a result of this, the diameter of the wellbore periodically decreases during drilling, which accordingly reduces the volume of gas produced and makes increasing the length of the well unprofitable. And the cost of casing can exceed the cost of produced gas from the fixed volume of the well.

Gas production by such horizontal drilling can be greatly increased by limiting the length of the horizontal section of the wellbore and applying its expansion to the largest possible size. But such an expansion in the oil and gas industry is not used for traditional reasons.

In addition, in the mining industry, effective technologies for expanding horizontal wells by reverse expansion are known. Here, the load on the expander is created due to the pulling force of the drilling rig, for example, [2], which is not traditional for the oil and gas industry. And in the proposed invention, this principle is redone for the conditions of the oil and gas industry, which solves the problem of cost-effective development of GGZ by drilling.

Closest to the technical nature of the claimed method is the selected as a prototype method for underwater extraction of gas hydrate [3]. The method of underwater production of gas hydrate includes drilling and lifting along a string of pipes of products to the surface and is characterized in that, in order to increase the efficiency and safety of production and transportation of gas hydrate after grinding the gas hydrate, underwater three-stage heating is performed to obtain the final decomposition products: gas and water, while primary heating is carried out while overlapping annular space with a dome-shaped element that opens under the influence of gas pressure obtained as a result those of the primary decomposition of gas hydrate. The method involves vertical drilling with a screw head and the opening of a dome-shaped element inside the well to block the exit from the well and to direct the drilled gas hydrate “under internal pressure” into the process chain. Inside the dome-shaped element there are heating elements that with their heat destroy not only the gas hydrate drilled by the screw, but also somewhat destroy the gas hydrate located on the walls of the well. This domed element can be considered as a thermal expander. Moreover, judging by the prototype scheme, the diameter of the opened dome-shaped element is five times greater than the diameter of the screw. That is, the prototype provides for the production of gas hydrate mechanically from the well and the expansion of the well, and these are signs similar to those in the claimed method.

However, the prototype has the following disadvantages:

- the volume of gas produced is limited by the diameter of the well, expandable up to five times and the thickness of the GGZ,

- the destruction of gas hydrate is carried out mechanically only along the thickness of the well, and the rest of the volume is destroyed by heat,

- there is no circulation of flushing fluid, which casts doubt on the possibility of extraction “under internal pressure”, since if solid particles are pumped into the inlet windows of the pipe with the help of a screw, they will clog them with the first blocks that come across and are compressed,

- if the compressed masses of gas hydrate are heated from above and crushed by electric heating elements of the dome-shaped element, then surface gas will be released up to one hundred and eighty volumes and a gas-water mixture will go upward into the pipe, and the denser “crushed ice” will remain below under the action of gravity and, apparently pressed, which will lead to cyclical clogging of the inlet windows of the pipe as the gas-water mixture goes upstairs,

- the method does not provide for the possibility of horizontal drilling to increase production volumes,

- blowout control equipment is not provided,

- reverse expansion is not provided, moreover, direct expansion by the thermal method will definitely lead to depressurization of the well and griffin,

- expansion to an extra-large diameter is not provided for increasing production volumes.

The objective of the invention is to obtain a cost-effective industrial gas production by extracting minerals from a gas hydrate deposit by drilling horizontal sections of wells with reverse expansion.

The problem is solved through the use of horizontal drilling with flushing and back expansion, with simultaneous cleaning and separation of the crude produced mixture and the accumulation of gas, and the super-large working diameter expander is delivered to the expansion site through a well to be back-expanded, while the pressure, temperature and composition of the flushing fluids are controlled in such a way that free natural gas released during mechanical drilling dissolves in the drilling fluid and is released of it only when it passes into the separator through a rotating preventer. Moreover, an expander is used in the form of a rocker with cones, expanding the diameter of the well to ten meters or more. The beam of this expander for its middle is pivotally connected to the end of the drill string, forming an unbalanced swing. If, at the same time, the bottom of the drill string is suspended vertically, the heavier side of this swing will fall down, and the other will rise up and be pressed against the pressure side of the weighted drill string. In this position, the expander penetrates the well and is delivered to the expansion site. After that, the fastest rotation of the tool begins with the greatest possible axial load towards the bottom. In this case, the rocker of the expander, under the action of deflecting forces, for the most part begins to crash into the borehole walls and, destroying the surrounding walls, gradually occupies the working position perpendicular to the axis of the bottom of the drill string. After that, mining is carried out by means of reverse expansion with simultaneous purification and separation of the crude extracted mixture and the accumulation of gas. At the same time, the density of the flushing fluid is selected so that the gas hydrate slurry tends to collect towards the axis of the expanded section and enter the unexpanded well channel with a flushing current. And the sand and sludge of clastic rocks would partially settle on the bottom wall of the well under the action of centrifugal forces (with stirring by the rocker) and under the influence of gravity. In this case, the pressure, temperature and composition of the flushing fluid are controlled so that the free natural gas released during mechanical drilling dissolves in the drilling fluid and is released from it only when it passes into the separator through a rotating preventer.

After the development of the previous horizontal section, drilling and development of the subsequent horizontal section of the multilateral well or cluster of horizontal wells or a series of horizontal wells is carried out.

Distinctive features of the claimed invention are:

1. Gas production from a gas hydrate reservoir through horizontal drilling with flushing and back expansion, while cleaning and separating the crude produced mixture and accumulating gas.

2. The delivery of the extender ultra-large working diameter to the place of expansion is carried out through the well, subject to reverse expansion.

3. The pressure, temperature and composition of the flushing fluid are controlled in such a way that the free natural gas released during mechanical drilling dissolves in the drilling fluid and is released from it only when it passes into the separator through a rotating preventer.

4. The use of an expander in the form of a rocker with cones expanding the diameter of the well to ten meters or more.

Distinctive features were not known to us from patent and scientific and technical information. In this regard, we believe that the solution we have announced is new.

The claimed combination of essential distinguishing features is unknown, which allows us to conclude that the technical solution has an inventive step.

The claimed method can be carried out by a specialized enterprise or organization, which meets the criterion of industrial applicability.

Example:

1. Perform preparatory and construction works for drilling bushes or rows of horizontal wells.

2. Drill each well in a cluster or row in the following order of technological operations.

3. Make vertical penetration of the upper permafrost and establish the direction (with active or passive protection against the melting of permafrost).

4. Further directional drilling is already carried out in the GGZ stratum with translation of the axis of the wellbore to the horizontal, after which a small distance (several meters) in the GGZ stratum is drilled horizontally.

5. Fix the well with a removable conductor clinging to the walls of the well with sliding spacers. Moreover, its annular space is sealed with thixotropic compositions.

6. The mouth of the conductor is equipped with a rotating preventer.

7. Further drilling is carried out during the circulation of the drilling fluid through the production, processing and treatment equipment, where the sludge of gas hydrates and its decomposition products are separated from the sludge of clastic rocks and drilling mud, and also where the final melting of the sludge of gas hydrate and separation of natural gas from the liquid followed by it collection.

8. Drilling a horizontal open hole in the GGZ with a length of, for example, 300 m or 3 km.

9. Bring the expander to the bottom of the well and begin the fastest rotation of the tool with the greatest possible axial load towards the bottom. In this case, the rocker of the expander, under the action of deflecting forces, for the most part begins to crash into the borehole walls and, destroying the surrounding walls, gradually occupies the working position perpendicular to the axis of the bottom of the drill string. Here, due to shallow depths, the weight of a conventional drilling tool may not be enough to maintain the most effective mechanical destruction of the rock. Therefore, to accelerate this process, it is possible to use both an extra-heavy boring tool (to create an axial load) and warm flushing, which causes gas hydrate cement to melt in the GGZ.

10. Produce mining through reverse expansion while cleaning and separating the crude extracted mixture and the accumulation of gas. Here, the expansion is carried out, for example, with a working diameter of the expander of 10 m and with a traction axial force of 2000 kN. At the same time, the density of the flushing fluid is selected so that the gas hydrate slurry tends to collect towards the axis of the expanded section and enter the unexpanded well channel with a flushing current. And the sand and sludge of clastic rocks would partially settle on the bottom wall of the well under the action of centrifugal forces (with stirring by the rocker) and under the influence of gravity. In this case, the pressure, temperature and composition of the flushing fluid are controlled so that the free natural gas released during mechanical drilling dissolves in the drilling fluid and is released from it only when it passes into the separator through a rotating preventer.

11. The extraction of natural gas is carried out as long as the expander reaches the conductor.

12. Carry out measures to remove the expander and conductor. For example, the expander is taken deep into the drilled shaft and turned with its downside down, as a result of which it assumes a longitudinal transport position in the well due to the difference in the weight of the sides of the rocker arm.

13. Make the movement of the drilling machine at the site of drilling the next well.

14. Begin a new cycle of gas production, drilling the next well in the bush, starting from point 3.

15. Upon completion of the development of the previous cluster plot or row, they begin to develop the next.

The inventive method of development is reliable, as it is based on modern drilling technologies used in the development of oil and gas fields.

When using drilling rigs with vertical drilling derricks, the claimed method has limitations on the smallest depth of development of the GGZ, commensurate with the radius of the curved section of the well connecting the vertical and horizontal sections.

The inventive method is applicable at appropriate shallow depths in the presence of special drilling rigs that allow you to set the directional direction and create a load on the bit due to the power machine.

The inventive method is effective in the development of bottom marine GGZ large thickness.

Literature

1. Methods of developing gas hydrate deposits: V.A. Nenakhov, Z.A. Ametova, V.P. Tsarev. - M.: VNIIEgazprom, 1988 .-- 36 p. (Obz. Inform. Ser. Information support of all-Union scientific and technical programs, issue 3). Bibliogr. - 26 titles.

2. A.S. No. 883306, class 3 E 21 B 7/28 published in 1981

3. USSR patent 1792482 A3, published 01/30/93. Bull. Number 4.

Claims (2)

1. The method of developing gas hydrate deposits, including mining through mechanical drilling and removal of cuttings and cuttings through the well, characterized in that the gas is produced by horizontal drilling with washing and back expansion, while cleaning and separation of the crude produced mixture and the accumulation of gas, and the delivery of the extender ultra-large working diameter to the place of expansion is carried out through the well, subject to reverse expansion, while The pressure, temperature and composition of the washing liquid is adjusted so that the free natural gas, freed by mechanical drilling, dissolves in the drilling fluid and is separated from it only when it passes into the separator through the rotating BOP. 2. The method according to claim 1, characterized in that they use an expander in the form of a rocker with cones, expanding the diameter of the well to 10 m or more.