UA143899U - METHOD OF EXTRACTION OF BOTTOM HYDRAULICS OF HYDROCARBON GASES - Google Patents

Abstract

The method of extraction of bottom hydrates of hydrocarbon gases includes the destruction of the gas hydrate deposit, the effect of electromagnetic radiation on the gas hydrate formation under the bedrock, heating of the gas hydrate formation. Pre-set the intensity of ultrahigh-frequency electromagnetic radiation, based on the mining and geological conditions of the gas hydrate deposit, taking into account the value of which in the process of longitudinal drilling of the gas hydrate layer is a continuous outflow of ultrahigh-frequency electromagnetic radiation with controllability.

Description

The useful model belongs to the gas production industry, namely to the methods of extracting energy gases from the seabed during the development of gas hydrate deposits.

A known method of developing gas hydrate fields (patent KO Mo 2211319, IPC E218B 43/24, 2003), which includes drilling a deposit consisting of at least two layers isolated from each other by impermeable bridges, two wells with horizontal sections, one of which is an injection well , and the other mining. A coolant is pumped through the injection well - liquid radioactive waste, which creates a thermal field for heating productive layers of gas hydrates. Injection well drilling is performed with the number of horizontal sections corresponding to the number of layers being drilled, the upper ones of which are laid in productive layers, and the perforated lower one in non-productive ones, where liquid radioactive waste is injected.

Disadvantages of the implementation of the mentioned method are related to the dangerous transportation and injection of liquid radioactive waste, the need for complex construction of a hermetic underground storage, as well as the creation of a radiation and environmental safety system.

A known method of heating oil products that have thickened and solidified (patent KO Mo 2224387,

IPC NOZBV 6/64, B650 88/74, 2004), which uses a device containing a microwave generator (for example, a magnetron), a rigid waveguide transmission line connected to it, and a conical emitter located above the surface of the medium containing oil With such a location of the emitter and a fixed operating frequency of the generator, the depth of penetration of electromagnetic waves into the medium is determined by its dielectric permeability and the tangent of the dielectric loss angle, and, therefore, does not depend on the characteristics of the device.

The disadvantage of this method is that the microwave heating of the medium occurs only in its surface layer, it takes a long time to warm up the deep layers. Another disadvantage of the method is that due to reflections of the electromagnetic wave from the boundary of the medium and lateral radiation through the gap between the emitter and the boundary, the microwave energy does not completely pass into the dielectric medium. Thus, the efficiency of the device (that is, the conversion of microwave energy into heat) could be higher if the microwave energy was completely transferred to the environment.

The closest analogue is the method of extracting methane from gas hydrate deposits (patent

OA Mo 8548, IPC E21В43/00, 2005), which includes vertical drilling into the productive layer,

From which lies under the layer of sedimentary rocks, heating the formation by exposure to electromagnetic wave oscillations and additional processing with acoustic wave oscillations.

Electromagnetic and acoustic emitters have a certain angle of directional action, and the intensity of the release of the gas phase from the gas hydrate deposit is carried out by changing the power of the electromagnetic emitter.

The disadvantages of this method are the complexity of the technology, namely its multi-stage nature, the placement of two emitters of electromagnetic and acoustic oscillations in the well, the inhomogeneous nature of the oscillations, and the penetrating properties of the waves, which do not allow working out the gas hydrate layer in a sufficiently complete volume, provided that the emitters are placed at the level of the gas hydrate deposit, which contributes to significant gas losses. Also, under the conditions of the occurrence of hydrates in sedimentary rocks, which serve as a hermetic retainer, the use of narrowly directed radiation makes the development of the deposit insufficiently effective.

The basis of a useful model is the task of improving the method of extraction of bottom hydrates of hydrocarbon gases, in which, through the introduction of new technological operations and parameters, the possibility of a different type of influence on the gas hydrate layer lying between associated rocks, including sedimentary ones, is achieved, with the simplification of technology and operations of environmentally safe operation of marine gas hydrate deposits with any composition of the original hydrocarbon gas, due to which efficiency and productivity are increased and rational use of resources and equipment is ensured.

The problem is solved by the fact that in the method of extraction of bottom hydrates of hydrocarbon gases, which includes drilling a gas hydrate deposit, the effect of electromagnetic radiation on the gas hydrate layer under the rock layer, heating the gas hydrate layer, according to a useful model, the intensity of ultra-high-frequency electromagnetic radiation is pre-set, based on the mining geological conditions of the gas hydrate reservoir, taking into account the value of which in the process of longitudinal drilling of the gas hydrate reservoir, they are continuously affected by ultra-high-frequency electromagnetic radiation with the possibility of continuous process control.

In Fig. 1 presents a general diagram of the method of extraction of bottom hydrates of hydrocarbon gases; in Fig. 2 - cross-section of the productive horizontal section of the well with perforation, which include: bo 1 - microwave radiation system

2 - the field of influence of microwave waves

C - horizontal section of the well 4 - vertical section of the well - waveguide 5 6 - gas hydrate deposit 7 - associated rocks 8 - sea space 9 - solid wall of the well 10-perforation 11 - wall of the waveguide

The method is carried out as follows.

The method of decomposition and extraction of natural gas hydrates of hydrocarbon gases (or their mixture) from marine deposits by impacting the deposit with ultrahigh-frequency (HF) radiation is carried out as follows. From the platform located above the sea space 8, the vertical section of the well 4 is drilled into the layer of gas-hydrate deposit 6, which lies between the layers of associated rocks 7. In the process of implementing the method, the vertical section of the well 4 performs the functions of both injection and production wells. When approaching the place of occurrence of gas hydrates, using directional drilling, the vertical section of the well 4 is bent and conducted along the productive layer of the gas hydrate deposit 6.

After the bending limit, the horizontal section of the well C has perforation 10, which is capable of passing electromagnetic microwave waves, the size and number of which holes are set in advance. The microwave radiation system 1 is connected to the vertical section of the well 4, which sends electromagnetic wave oscillations through the waveguide 5, which runs along the entire well.

Waveguide 5 in the horizontal section of the well C through perforation holes 10 releases electromagnetic microwave waves into the gas hydrate deposit b, creating a field of influence of microwave waves 2.

The created field of microwave waves 2 heats the gas hydrate deposit 6, destroying the crystal lattice of the hydrate that holds the gas. The released gas is pumped to the surface through perforation 10 of the horizontal section of the well Z in the reverse way.

The microwave radiation system 1 is shielded with a casing to protect people and the environment from

From electromagnetic microwave waves. To achieve the maximum efficiency of the method, the microwave radiation system 1 is placed near the mouth of the vertical section of the well 4.

Directional drilling allows you to set the angle of the drill string for longitudinal drilling of the gas hydrate deposit 6, which does not necessarily lie horizontally and has a certain angle of inclination.

The horizontal section of the well Z is centered along the layer of the gas-hydrate deposit 6 for a uniform all-round effect of the field of influence of the microwave waves 2. The accompanying rocks 7, including the sedimentary ones that close the layer of the gas-hydrate deposit 6, serve as a hermetic barrier and do not allow the microwave radiation to spread uncontrollably into maritime space 8.

The UHF radiation system 1 generates microwaves when the electron flow interacts with the electric component of the ultra-high-frequency field in the space where the constant magnetic field is perpendicular to the constant electric field. The waveguide 5 is represented by a tube capable of propagating microwave waves generated by the microwave radiation system 1. The dimensions of the waveguide are set depending on the wave frequency. The continuous walls of the well 9 prevent the scattering of microwaves into the sea space 8 and allow to protect the surrounding space from the influence of microwave radiation. At the stage of gas production, waveguide 5 has an additional application, it prevents the formation of gas hydrate plugs in the vertical section of the well 4. The walls of the waveguide 11 are heated, creating such conditions in the vertical section of the well 4 that exclude the possibility of nucleation of gas hydrates.

At the initial stage, the mining and geological conditions of the gas hydrate deposit 6 are pre-determined. Based on the parameters of temperature, pressure and height of the gas hydrate deposit 6, regardless of the gas composition, the output power of the microwave radiation system 1 is set, which can be adjusted during the production process. The intensity of the influence of microwave waves is determined by the intensity of the process of gas release from the layer of the gas-hydrate deposit 6, which is controlled by adjusting the parameters of the microwave radiation system 1. The production process is continuous and takes place during the longitudinal drilling of the productive layer of the gas-hydrate deposit 6, and the homogeneous field of influence of the microwave waves 2 is comprehensively distributed parallel to the drilling process. The rate of passage of the gas-hydrate deposit 6 is controlled by the gas release parameter, which provides an opportunity to influence the working efficiency.

In a continuous production process for the release of gas from hydrate electromagnetically. Microwave radiation affects water molecules, heating them and destroying the crystal lattice of gas hydrates. Based on the temperature and pressure parameters of the gas hydrate deposit 6, in the process of decomposition of the hydrates, the necessary degree of heating is applied within the homogeneous field of influence of microwave waves 2, disturbing the balance in which the gas hydrates lie. A slight rise in temperature, which is determined relative to the pressure parameter in the gas-hydrate deposit 6, is sufficient to destroy the crystal lattice of the hydrate, which allows you to locally influence the formation without affecting the accompanying rocks 7 and save energy.

The advantages of the proposed method include accessibility and ease of maintenance, a significant reduction in energy consumption when heating the array, which definitely indicates the high efficiency of the microwave technology for the development of gas hydrate deposits.

Claims (1)

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