RU2061845C1 - Method for development gas condensate, oil or oil/gas condensate deposit - Google Patents

Abstract

FIELD: oil or gas production. SUBSTANCE: elastic bathes are provided to effect on lower water bearing stratum. The effect is provided in area and/or out of area of oil/water or gas/water contact. Gas margin may be formed additionally at the expense of gas being evacuated. Elastic waves may be used in this case in resonance with gas margin. Concurrent heat effect is possible too. EFFECT: increased oil or gas discharge. 10 cl, 4 dwg

Description

 The invention relates to methods for oil production, gas condensate and can be used in the development of oil condensate, gas condensate and oil fields.

 A known method of developing hydrocarbon deposits, including the injection into the reservoir of water with a salinity of 200-300 g / l (AS USSR N 605429, E 21B 43/20, 1987). This eliminates the dissolution of gas from the reservoir in the injected water, and also leads to the release of a certain volume of gas from the 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 the equipment, the precipitation of salts in the well and reservoir.

 A known method of oil production using the gas pressure mode of the formation in combination with low-amplitude seismic excitation / US Patent 4417621, Nov. 29, 1983 /. The method involves the extraction of oil by pumping a gaseous fluid, such as carbon dioxide, simultaneously with the transmission of vibrations into the reservoir in the seismic frequency range from 0.1 to 500 Hz, mainly from I to l00 Hz, from a ground-based seismic source. Fluctuations increase the flow of carbon dioxide and at the same time increase the efficiency of oil production.

The disadvantage of this method is the need for injection into the reservoir of significant volumes of CO ₂ . This requires large capital investments, energy costs, special pumping equipment that wears out during long-term operation, etc.

 There is a method of increasing oil recovery using vibration from the surface of the earth to oil reservoirs with sinusoidal vibration sources with a force amplitude of l00 t and a frequency of 5 8 Hz / N.P. Ryashentsev, Aschepkov Yu.S. V.F. Yushkin, L.I. Nazarov, B.F. Simonov, AI. Kaltsiev, Controlled seismic effect on oil deposits, preprint N 31, Special Design Bureau of Applied Geophysics SB RAS, Novosibirsk, 1989, p. 37.

 The disadvantage is the inevitable degassing of oil, which is often associated with an initial increase in the flow rate of wells, but in the future this results in significant losses of oil in the reservoir.

Closest to the invention is a method of developing an oil or gas condensate field in the gas cap mode / Mirzadzhanzade A.Kh. Durmishyan A.G. Kovalev A.G. Allahverdiyev T.A. development of gas condensate fields, M. Nedra, 1967 /. Constant pressure gradients from the gas zone to the oil are created in the reservoir, which leads to the displacement and transport of oil by gas and its selection through production wells. The method is most effective with the mobility of oil-water contact (NEC)
The following disadvantages are inherent in this method: forced and usually long-term conservation of industrial gas reserves, and hence the impossibility of using them for household needs. In the presence of condensate in the gas, retrograde condensate losses occur before the start of the development of the gas condensate zone, this is even more aggravated if the formation water has insufficient pressure and activity.

 The problem the invention is aimed at increasing the efficiency of developing oil, oil and gas condensate and gas condensate fields at various stages of development and increasing the recoverable hydrocarbon reserves additionally solves the problem of more rational and efficient use of the impact on the reservoir by elastic waves.

 The result achieved in this case is expressed in an increase in oil production, gas condensate, and additional gas. The specified result is achieved as follows.

 Wells are being drilled into the horizon containing oil, gas condensate for fluid extraction, or finished wells are used in a depleted field containing oil or gas condensate remaining in the formation. Then carry out periodic exposure to the underlying aquifer. Periodic exposure is organized in such a way that it leads to the release of gas from the aquifer, which may be in the form of gas bubbles or a dissolved state, and also, if necessary, to promote water in the overlying oil-containing formation.

 Such an effect can be organized using elastic vibrations, as well as their combination with the effects of an electric field, chemical reactions, pressure reduction in the aquifer zone, combinations of these effects.

Effectively act in the zone and / or from the zone of gas-water (GVK) or oil-water contact (NVK). This increases its mobility.
The degassing of an aquifer leads to the movement of gas bubbles, jets, pillars of gas into an overlying reservoir containing oil and / or gas condensate, displacement of oil or condensate from its pores and transport to production wells, and “aeration” of oil, which reduces its viscosity and increases mobility . The advancement of water into the reservoir additionally contributes to the displacement of hydrocarbons, such flooding is organized, for example, in cases of low gas factors of aquifers.

 Also, a gas rim is formed between the oil or gas condensate reservoir and the water, for example, by reducing the pressure in at least part of the aquifer by taking water from wells drilled into the aquifer. In this case, the pressure is reduced not lower than the pressure of the overlying oil horizon.

 Formed rim allows you to develop a reservoir in the gas "cap" mode, only located in a more favorable lower position in relation to the oil (oil and gas condensate) reservoir. Such a gas cap is constantly replenished with gas from an aquifer. Caps (rims) can be formed, for example, between an aquifer and low permeable clay reservoirs containing highly viscous oil.

 The development of the field is also possible in the regime of two gas "caps" - natural and artificially formed, as well as more than two artificially formed.

 In addition, the aquifer is affected by elastic vibrations (waves), this is the most effective method of exposure, it leads to intensive gas evolution from the aquifer and its advancement into the overlying reservoir, as well as the formation of a gas rim (“caps”). Moreover, in many cases there is no need to reduce the pressure in the reservoir. The evolution and movement of gas occurs without an additional pressure gradient, the action of vibrations activates NEC and GVK. Also, due to sound-capillary effects and accelerated impregnation, water-flooding of a hydrocarbon-containing formation is organized.

 The combination of the effects of oscillations with a decrease in pressure, for example, water withdrawal, significantly accelerates the evolution and filtration of gas with a greater completeness of its extraction.

 Having formed a gas rim ("cap") of a certain initial volume, they are influenced by vibrations in resonance with it, this leads to an even more intense inflow of bubbles, pillars of gas to the rim, and the development of the deposit is carried out in a more efficient mode of expansion of the gas "cap" and ripple.

 They also organize a resonant effect on other gas caps, acting on them, for example, synchronously and asynchronously, in mixed sequences.

The process of developing the reservoir in the mode of exposure to the aquifer may additionally be accompanied by fluid injection. For example, if the formation has low gas factors, extra injection of gas (air, CO ₂ and others.) Into the formation, but the download thus lead to significantly smaller volumes and minimal duration of time. Other fluids can also be injected fluids, for example, a wide fraction of light hydrocarbons (NGL). It is used in the process of miscible displacement, the gas released from the aquifer enriches NGL. The combination of displacing, for example, gas condensate deposited in the formation by gas emitted by BFLH enriched with BFLH gas leads to a more complete recovery of hydrocarbons from the formation.

 In the case of the extraction of highly viscous oils, along with operations involving exposure to the aquifer, its degassing, creation of a gas rim, etc. to reduce the viscosity of oil on the oil reservoir, they exert a thermal effect, this effect can be carried out by in-situ combustion, the oscillation source is located in a zone, preferably, NEC. Then the elastic waves affect the aquifer and additionally the oil, thereby increasing the radius of the heated zone, intensifying heat transfer. In addition, the combined action of elastic waves and heat to a greater extent reduce the viscosity than each of the effects individually, and also, by elastic waves, they form a burning center.

 In addition, in addition, the source of vibrations from the earth's surface can act on the hydrocarbon reservoir, which accelerates the movement of gas bubbles and oil in the oil reservoir.

 The method implies the possibility of combining it with other traditional secondary and tertiary hydrocarbon production methods.

 FIG. I. scheme of an embodiment of the method.

 FIG. 2. a diagram of an embodiment of a method involving the formation of a gas rim.

 FIG. 3. scheme of the arrangement of seismic sources in the presence of contour water.

 FIG. 4. arrangement of seismic sources in the plan at the current moment of formation of the gas rim.

Example I. At the oil site of the field at a depth of 1600 m, the volumetric content of the components of the water-dissolved gases is: 64% CO ₂ , 32% CH ₄ , 4% N ₂ , and the source of impulse effects I is established on the day surface above the reservoir (Fig. 1). It is connected to the waveguide 2, through which the oscillations are transmitted to the aquifer 3. The end of the waveguide 2 in the aquifer 3 can be performed in the form of a concentrator. Changing the frequency of pulses from I to 45 pulses per minute and from 45 to I, they act on the aquifer 3 through waveguide 2. If possible, a smooth change in the pulse repetition rate is alternated by pulse packets, in a series of 5 to 20 predominantly rectangular pulses of different duration and amplitude. As a result of this effect, gas begins to be released from the formation 3, mainly CO ₂ , which, when entering the oil formation 4, displaces the oil to production wells 5.

 Example 2. Above the reservoir of highly viscous oil I (Fig. 2), having clay sections 2, a pulse source 3 is installed with a waveguide 4 ending in the aquifer 5. In wells 6 and 7 drilled into the aquifer 5 are also located in the region of the reservoir 5 sources of elastic waves 8. Under the influence of vibrations, gas is released from the formation 5, which accumulates in the trap 9, forming a gas rim ("cap") between the aquifer 5 and the oil 4, partially shielded by clay section 2. Then, the development is carried out in gas mode " caps ", taking oil by wells 10.

 Example 3

Sources of harmonic oscillations 3 are installed above the reservoir of high-viscosity oil I (Fig. 3) in the region of contour waters 2, sources of harmonic oscillations 3 are buried in the ground. By acting on sources on the aquifer 2, they are degassed and a gas rim is created 4. Then, in the course of geophysical studies, the resonant frequencies of the artificially created rim 4 and the natural gas “cap” 5. Then, the resonance effect by oscillations on the rim 4 is continued. This leads to the implementation of the rim and makes the development of the deposit in the gas “cap” mode more efficient d. Similarly, they can affect the gas "cap" in resonance 5. Oil is taken from wells 6
The advantages of the proposed method are that it allows to increase the production of oil, gas condensate, as well as additional gas, to increase their recoverable reserves. In addition, deposits that are considered unprofitable are involved in the development: those with insufficient trap filling, depleted ones containing gas condensate resulting from retrograde condensation, residual oil, and watered gas and oil fields. The method either does not require injection of displacing fluids at all, or it is carried out in significantly smaller volumes. This also applies to water withdrawal, conducted to reduce reservoir pressure and degass the aquifer. The method allows either to exclude the selection of water or to conduct it in significantly smaller volumes and time intervals. Another advantage of the method is a more rational and efficient use of vibration sources, minimizing possible negative effects.

 Each gas or oil field is associated with a water system involved in its formation. The proposed method allows you to develop this relationship, influence the process of formation of deposits, accelerate it and form deposits with the desired parameters, as well as restore depleted deposits, elastic waves from vibration sources and the accompanying effects of acoustic emission directly in the reservoir, stimulate gas evolution from the aquifer and intensifies its movement into overlying strata.

 As the gas advances, its thermodynamic conditions change, which can lead to a shift in phase equilibrium and the release of liquid hydrocarbons, which contribute to an increase in the recoverable reserves of oil and gas condensate. Thus, the method allows not only to displace oil from the oil deposit formed as a result of geological processes, to increase the content of condensate and oil in it, but also to additionally increase the recoverable gas reserves. In fact, it repeats the natural seismic mechanism of the formation of hydrocarbon deposits, but unlike the latter it is controllable.

 The method may contain other advantages arising from the above description and obvious to specialists in this field of technology

Claims (10)

 1. A method of developing a gas condensate, oil or oil and gas condensate deposit, including the use of gas elasticity and mobility, drilling one or more wells in a hydrocarbon containing horizon and selecting produced fluids from them, characterized in that they periodically apply elastic vibrations to the underlying aquifer.  2. The method according to p. 1, characterized in that the effect is carried out in the zone and / or from the zone of gas-water or oil-water contact.  3. The method according to PP. 1 and 2, characterized in that the aquifer is degassed.  4. The method according to claims 1 to 3, characterized in that a gas rim is formed between the oil or gas condensate and aquifers.  5. The method according to claims 1 to 4, characterized in that the rim is created by gas evolution from the aquifer.  6. The method according to claim 1, characterized in that the impact of elastic vibrations on the aquifer is in resonance with the gas rim.  7. The method according to claims 1-6, characterized in that the fluid is pumped into the formation.  8. The method according to PP. 1-7, characterized in that the hydrocarbon containing formation have a thermal effect.  9. The method according to claim 8, characterized in that the in-situ combustion is used as the thermal effect.  10. The method according to claims 1 to 9, characterized in that they have an additional effect of elastic vibrations on the hydrocarbon containing formation.

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