RU2586343C2 - Method to develop gas hydrate deposits using focused acoustic impact on the layer - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to the extraction of natural gas from gas hydrate deposits and gas deposits, characterized by deposition of hydrates in the bottomhole formation zone. Method development of gas hydrate deposits include heating producing formation near the wellbore through the acoustic impact, and the use acoustic transducer with a frequency range from 20 to 30 kHz and a power input of 15 to 20 kW, whose design uses ultrasonic isolation, enhancing the sound radiation due to the geometry design and having in its structure a vacuum chamber in the form of a prism for turning longitudinal sound waves 90° and an outer side surface in the form of a concave lens for focusing a cylindrical product acoustic radiation at a distance of 5 to 15 meters from the borehole axis.

EFFECT: technical result - high power stimulation without the risk of structural failure of the well.

3 cl, 2 dwg

Description

The invention relates to the gas sector and is used to produce natural gas from gas hydrate deposits and gas fields characterized by precipitation of hydrates in the bottomhole formation zone. A new method is proposed, based on the use of a focusing ultrasonic device for heating the reservoir, in order to produce natural gas from gas hydrates.

The level of technology.

A known method of acoustic impact on the oil and gas reservoir, which relates to the oil industry and can be used to increase the productivity of the well and the reservoir rocks as a whole. The method includes diagnosing the bottom-hole zone, irradiating with an acoustic field and adjusting the parameters of the irradiation modes according to the feedback results. The acoustic effect is carried out in stages of vertically directed and circular horizontally directed acoustic fields at the same time (RU 2140534 C1, 03/11/1998).

This method is characterized in that the principle of acoustic focusing is not used in the design of the ultrasonic emitter, which leads to strong energy dissipation in the formation. The selected power and frequencies in this method do not provide changes in the phase state of the fluids, but only serve to intensify the processes.

A known method of increasing oil recovery using acoustic exposure. This method relates to the oil industry and can be used to increase well production and intensify oil production. Efficiency is improved due to exposure to the fluid in the pore space of the well by multi-frequency exposure. The method involves immersion of a vibro-acoustic downhole emitter in the well to the level of the reservoir and the acoustic impact on the reservoir (RU 2355878 C2, 12.28.2006).

This method is characterized in that it is suitable only for oil fields, the effect is multi-frequency, and acoustic focusing is not used in the design of the ultrasonic emitter.

Known methods for the production of natural gas from gas hydrate deposits, such as lowering the pressure, heating the reservoir by injection of warm water, the use of inhibitors, combined methods, etc. (Prospects for the development of technology for industrial production of gas hydrates // E.V. Kreinin // Gas industry. - 2007. - No. 1. - P. 43-46; Methods of gas production from gas hydrate deposits // KS Basniev [et al. .] // Gas industry. - 2007. - No. 11. - P. 84-86 - Bibliography.).

Known methods for the production of gas hydrates by the method of reducing pressure both due to the natural differential pressure when drilling a deposit, and using additional compressor units (examples RU 2438009 C1, 05/04/2010; RU 2386015 C1, 12/15/2008). The disadvantage of the method of pressure reduction is associated with the technogenic formation of hydrates in the bottomhole zone due to the Joule-Thomson effect. Also, the temperature of the rock and the surrounding fluids will decrease due to the high negative enthalpy of decomposition of gas hydrates, equal to 0.5 MJ / kg. All this will lead to the additional effect of self-preservation of hydrates, which will stop the release of natural gas. Thus, the development of hydrated deposits by lowering the pressure is possible only when injecting inhibitors into the bottomhole zone, which will significantly increase the cost of produced gas and lead to additional environmental risks.

Known methods for producing gas hydrates by increasing the temperature of the formation and surrounding fluids by injecting a heated source (water, for example), placing a “point” heat source at the bottom, conducting chemical reactions with heat in the formation (examples RU 2491420 C2, 11/30/2011; RU 2451171 C2, 07/30/2008; RU 2424427 C1, 04/13/2010; RU 2306410 C1, 12/22/2005).

The thermal method of developing gas hydrate deposits, using a “point” heat source at the bottom of the well, is suitable for formations having a high hydrate content in the pores. However, as the calculation results show, the thermal effect through the bottom of the well is ineffective. This is due to the fact that the process of hydrate decomposition is accompanied by heat absorption with a high specific enthalpy of 0.5 MJ / kg. As the decomposition front moves away from the bottom of the well, more and more energy is spent on heating the enclosing rocks and the formation roof. Therefore, the zone of thermal influence on hydrates through the bottom of the well has a size of the order of only 2-3 meters from the axis of the well and heating is greatly reduced after this distance. Significant energy dissipation is also observed in the reservoir area without gas hydrates.

In the case of using heated water pumped into the formation as a heat source, it is necessary to encounter difficulties in maintaining its temperature during transportation to the formation and high energy costs for initial heating.

The known method of decomposition of hydrates using inhibitors (example RU 2433255 C1, 03.03.2010) is unlikely to be acceptable due to the high cost of the inhibitors and their environmental hazard.

Disclosure of the method.

The essence of the method for developing gas hydrated deposits using focused acoustic stimulation is to use a focusing ultrasonic emitter to heat the reservoir. This method can be used in conjunction with the method of injecting water into the reservoir. Water is heated directly at the bottom due to acoustic impact.

The frequency range from 20 to 30 kHz is used. The power of the surface generator of the ultrasonic installation is from 15 to 20 kW. In these calculations, a 16 kW generator is used.

Separately, depending on the parameters of the reservoir and the surrounding fluids, the focal length from the axis of the well is selected for the acoustic lens of the emitter, ranging from 5 to 15 meters.

The most promising is the combined method, which consists in simultaneously reducing the pressure and supplying heat to the well. Moreover, the heat supply is proposed to be carried out by applying a focused acoustic field to the formation. Due to the focusing of ultrasonic waves, it will be possible to achieve a greater penetration depth, less scattering into the gas-hydrate-free sections of the formation and the appearance of additional energy in the area of the radiation focus. This method of influence will help to achieve the following advantages: the impact will not be "point" at the bottom, but at a certain distance around the well; higher temperatures can be achieved without harming the well due to water cooling; in parallel, the water pumped into the reservoir will be heated; due to the small depths of gas hydrates, the losses during energy transfer to the emitter are not so great and the efficiency of the installation remains at a high level.

The exposure to the ultrasonic field using the downhole emitter is carried out with a large penetration into the reservoir relative to the downhole heater through the use of the principle of ultrasonic (ultrasound) focusing.

For thermal exposure to the formation using ultrasound, the ultrasonic emitter can be supplied with a power significantly greater than a conventional heat source, and at the same time not jeopardize the construction of the well at the bottom. This is feasible by cooling the device and the column with pumped water. In addition, removing excess temperature at the bottom, it is possible to heat water and thereby additionally heat the formation. In the case of a conventional heat source, water consumes most of the energy for its heating, which reduces the efficiency of heating the formation. Ultrasonic radiation, in contrast, is well conducted by water, and the shape and range of wave propagation will not change.

Description of drawings

Figure 1 shows a section along the diameter of the ultrasonic emitter, the surface of which has the shape of a concave lens, and the shape of the radiation from the focusing surface.

Figure 2 shows the external plan of the focusing part of the emitter with the radiation sector.

The implementation of the method

The exposure to the ultrasonic field using the downhole emitter is carried out with a large penetration into the reservoir relative to the downhole heater through the use of the principle of ultrasonic (ultrasound) focusing. For this, it is proposed to use the method of cylindrical focusing. Figure 1 shows a section along the diameter of the section of the ultrasonic emitter with 2 acoustic junctions (1, 2) interconnected (3), the surface of which has the shape of a concave lens (4). The radiation from such a surface will be in the form of a disk (5), which will make it possible to increase the intensity at the focusing point (6) and to avoid scattering into the region of the reservoir that does not contain gas hydrates. The design used ultrasonic isolation (1, 2), which serves to enhance radiation and turn longitudinal vibrations into transverse ones using a vacuum cavity in the form of a prism (7).

Depending on the properties of the collector and the fluids contained in it, the shape of the focusing lens is chosen so as to select the optimal focal length (8), determined by the focus angle (9). Depending on the required focal length, power and frequency of the ultrasonic emitter, the distance between acoustic decouples is selected from geometric considerations (10).

The following are the results of calculating the thermal effect of the proposed method using a mathematical model, which shows its effectiveness.

As an example, a surface generator with a power of 16 kW was taken. Taking into account the acoustic efficiency of the emitter, losses on the borehole cable for a depth of up to 1000 m and the design of the emitter having 2 acoustic decouples, which corresponds to the power allocated to one lens (one radiating "disk") of about 5.5 kW.

To estimate the energy consumption for the operation of the generator in comparison with the energy of the produced gas, the methane combustion heat of 33.28 · 10 ⁶ J / m ^{3 was used} .

The following values are taken as parameters of the rock and host fluids: the heat capacity of the rock and host fluids is 1.48 · 10 ⁶ J / (m ³ K); porosity 0.35; hydration saturation 75%; water saturation 0.25; the initial pressure in the reservoir P ₀ is 5.74 MPa; the initial temperature T ₀ is 283 K; the thermal conductivity of the rock and the surrounding fluids is 1.71 W / (m ^· K); the sound absorption coefficient of the rock and the surrounding fluids is 4.5 dB / m.

The temperature increase field is calculated for the area between two acoustic decouples. The height of the wellbore, in which the emitter is located, is 2.8 meters. The temperature, after 70 days of exposure, increased by the following values: at a distance of 0.7 meters from the well, the temperature increased by 100 ° C; at a distance of 0.7 to 2.5 meters - at 85 ° C; at a distance of 2.5 to 7.5 meters - at 65 ° C; at a distance of 7.5 to 15 meters - at 30 ° C; at a distance of 15 to 22.5 meters - at 20 ° C; at a distance from 22.5 to 27.5 - at 15 ° C; at a distance of 27.5 to 35 at 10 ° C; at a distance of 35 to 42 meters at 5 ° C; Further, an increase in temperature due to the acoustic value is considered to be 0 ° C.

Excessive temperature near the bottom can be removed by cooling with pumped water.

Claims (3)

1. The method of developing gas hydrate deposits, including heating the reservoir in the near-wellbore zone by means of acoustic stimulation, characterized in that an acoustic emitter with a frequency range from 20 to 30 kHz and input power from 15 to 20 kW is used, the design of which uses ultrasonic decoupling, amplifying sound radiation due to the geometry of the structure and having in its design a vacuum cavity in the form of a prism for rotation of longitudinal sound waves by 90 ° and the outer side surface in the form a concave lens for producing cylindrical focusing of sound radiation at a distance of 5 to 15 meters from the axis of the well. 2. The method according to p. 1, characterized in that at the same time as the acoustic exposure, the formation can be heated using injected water, which is heated directly at the bottom and in the bottomhole zone by absorbing excess heat from ultrasonic exposure. 3. The method according to p. 1, characterized in that it is possible to achieve higher temperatures of heating the formation without compromising the design of the well due to cooling with water pumped from the surface.

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