RU2064572C1 - Method for exploitation of gas-condensate or oil/gas- condensate field - Google Patents

Abstract

FIELD: mining. SUBSTANCE: method provides keeping seam pressure inhydrocarbon-bearing seam using gas and/or water of lower water bearing seam. Gas and/or water motion is carried out by elastic oscillations applied to the water bearing seam. EFFECT: high efficiency. 1 dwg

Description

 The invention relates to methods for producing gas, gas condensate and oil and can be used in the development of gas condensate fields, including those containing an oil rim.

 A known method of developing a gas condensate field for depletion (SN Zakirov. Theory and design of the development of gas and gas condensate fields, M. Nedra, 1989). It provides for the production of gas due to the natural reservoir pressure in the reservoir. The disadvantage of this method is the retrograde loss of gas condensate in the reservoir.

 A known method of developing a gas condensate field (ed. St. USSR N 605429, class E 21 B 43/20, 1987), including the injection into the reservoir of water with a salinity of 200-300 g / l. This eliminates the dissolution of gas from the reservoir in the injected water.

 The disadvantages of the method are the instability of the effect, operating costs for the preparation of brines, reducing the service life and reliability of equipment, the precipitation of salts in the well and reservoir.

 A known method of developing a hydrocarbon field (ed. St. USSR N 1596081, class E 21 B 43/00, 1990), including the vibration effect from ground-based seismic sources on a hydrocarbon-containing formation.

 The disadvantages of the method are its low efficiency, the absence of operations to promote gas or water into a hydrocarbon containing formation, due to which the formation pressure is maintained.

 Closest to the invention is a method of producing gas condensate by maintaining reservoir pressure by re-injection of gas into the reservoir (S. N. Zakirov. Theory and design of development of gas and gas condensate fields, M. Nedra, 1989), keeping the pressure constant in the gas reservoir, preventing loss parts of hydrocarbons in the liquid phase and their losses in the reservoir.

The main disadvantages of the method are:
the need to inject pre-drained gas into the reservoir during the entire life of the reservoir, as well as the long-term preservation of gas reserves;
large capital investments;
the need to equip fishing with special equipment;
high operating costs;
decrease in the reliability of fishing equipment in connection with the increase in the term of its operation.

 The problem to which the invention is directed simplification of the method, reducing the cost of its implementation, increasing the volume of recoverable reserves.

 The specified technical result associated with a reduction in capital investments, as well as time for the extraction of gas condensate, lower operating costs, eliminating the need for injection through injection wells into the fluid reservoir or a significant reduction in injection volumes while increasing the recoverable reserves, is achieved by the fact that the pressure in the gas condensate reservoir support above the pressure of the beginning of condensation by moving into the reservoir gas and / or water directly from the underlying aquifer. In this case, the advancement of gas and / or water from the aquifer is organized by exposing the aquifer to elastic vibrations.

 The drawing shows a diagram of the implementation of the method.

 The method is illustrated by the following example implementation of the invention.

 A source of harmonic oscillations 2, recessed into the ground, is installed on the day surface 1 so that the elastic waves from it act on the aquifer 3. Also, pulse and shock sources 6 and 7 are respectively placed on waveguides 4 and 5, using, for example, the energy of the incident body, in the well 8, preferably at the level of the gas-water contact (GWC), place the oscillation source 9. The selection of produced fluid is conducted through the wells 10. Waveguides 4 and 5 may contain concentrators in the region of the aquifer. When exposed to vibrations from sources 2, 6, 7, 9 on the aquifer 3, gas from the aquifer in the form of dispersed bubbles in dissolved form, as well as a possible gas hydrate form, begins to be released from it. The evolved gas enters the gas condensate reservoir 11, increasing the pressure in it, as well as the gas content. The selection of gas from the reservoir through the wells 10 is regulated and synchronized with the effects of vibrations from sources 2, 6, 7, 9 so that the pressure in the reservoir 11 does not fall below the pressure of the onset of condensation. This helps prevent condensation from forming in the formation and increase the completeness of its extraction. In addition, the reserves of gas (and condensate) increase due to replenishment of the reservoir 11 with gas from the aquifer 3.

 Impact does not have to be carried out by all sources. For example, it is sufficient to use only pulsed sources (source).

 It is advisable to conduct the impact in the frequency range from 1 to 100 Hz, changing the frequency from its lower value to the larger one and vice versa.

 Along with the gas released into the reservoir 11, water from the reservoir 3 enters, which, in addition to transporting it with gas bubbles, is stimulated by sound capillary effects and the acceleration of impregnation in the field of elastic waves. This also leads to an increase in pressure in the reservoir 11 and the displacement of gas to production wells. In this case, pinched gas pillars are not formed due to the greater mobility of the gas than water in the field of elastic waves, additional gas filtration through the displacement front, etc.

 Exposure to fluctuations, it is advisable to conduct in the zone (or zone) GVK. Therefore, the source 9 is moved along the well 8 in accordance with the change in the position of the GWC.

 In the case of low gas factors of the aquifer (for example, a decrease in the gas factor as a result of degassing from the impact) and with slow movement of water into the reservoir, additional injection of gas or water through injection wells is possible (not shown). However, the volume and duration of injection, in this case, is significantly less than in the known method of maintaining reservoir pressure.

 Thus, the main advantages of the method are: no need to pump large volumes of fluid into the formation; gas preservation for a long period; reduction in capital investment and operating costs; increase in recoverable reserves of gas and condensate. Also, if the field is supported by an aquifer with large gas factors, the method allows to extend the life of the field with more intensive extraction of produced fluid from it.

Claims (1)

 A method of developing a gas condensate or oil and gas condensate field, including maintaining the reservoir pressure in a hydrocarbon containing formation using gas and / or water, characterized in that the reservoir pressure is supported by moving gas and / or water into the formation of the underlying aquifer by applying elastic vibrations to it.