RU2507381C1 - Oil prospecting and production - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: proposed method consists in revealing the oil reservoir by field and geophysical researches, estimating its hydrodynamic activity by repeated geophysical measurements and defining variation of measured parameters in time, and drilling holes directly into said oil strata. In compliance with this invention, revealed strata is localised by drilling horizontal hole across direction of said strata. Thickness of oil strata is defined to drill second horizontal hole in direction of said strata over its axial line. At a time, current thickness of said strata and drilled hole position are defined. Note here that said hole is drilled along the crest. Then, isolating agent is injected in said hole to make an artificial cap. Thereafter, under said cap, at depth larger than isolating agent penetration depth, drilled is at least one horizontal hole to extract oil.

EFFECT: oil extraction directly from oil strata.

8 cl, 4 dwg

Description

The invention relates to the field of the oil industry, and more specifically to a group of methods for searching and producing oil.

Traditional methods for searching and extracting oil from oil traps are known, including the identification of these traps by geological and geophysical methods, drilling a well to depths involving the intersection of oil horizons, lowering the casing string, cementing it and causing flow, followed by oil production from the productive layers (Sputnik of the oil and gas field geologist: Reference book / Ed. By I.P. Chalovsky. - M.: Nedra, 1989, 376 p.). However, the process of cost-effective oil production from a reservoir, as a rule, takes a limited time and at a late stage requires measures to increase oil recovery.

Modern oil production technologies at a late stage of development are associated with the injection of large volumes of water in order to displace oil from the reservoir into the production well. Injected water, firstly, increases reservoir pressure, and secondly, greatly complicates the production process and reduces its profitability (Shustef I.N. Geological foundations of technological solutions in the development of oil fields. - M .: Nedra, 1988, 199 pp.) .

There are also known methods of oil production using horizontal and multilateral wells with horizontal branches running directly through the oil reservoir. In this case, the useful length of the wells in the reservoir and, consequently, the drainage zone (filtration surface) increases, resulting in a significantly increased well production (Bulatov A.I., Avetisov A.G. Handbook of a drilling engineer. In 2 volumes Volume 1. - M .: Nedra, 1985, p.11).

This method significantly increases the productivity of the well, however, it is also focused on oil production from the trap.

The method of production based on the concept that each oil field consists of an actual trap, a deep reservoir (as the main supplier of hydrocarbon fluids) and an oil supply channel (NPK) connecting the deep a tank with a trap (RF patent No. 2204700, declared. May 16, 2002, publ. May 20, 2003). In this method, it is proposed to conduct oil production directly from the oil supply channel. To do this, it is necessary to establish the position of the oil supply channel, isolate it from the deposits and extract oil from it directly. In this method, the position of the oil supply channel is preliminarily determined, then the well is drilled to the horizons underlying the oil-bearing strata or to the surface of the crystalline basement. Around the circumference from the bottom of the main well below the bottom of the oil-saturated formation, horizontal wells are drilled through which the insulating substance is pumped, then the well is deepened, after which it is tested. The position of the oil supply channel is determined by pre-conducted field studies of wells that produce oil from the productive horizons of the sedimentary cover, as well as preliminary geophysical studies of the sedimentary cover. However, this method does not describe the specific technology for the search and localization of oil supply channels, and their opening by vertical wells is difficult to implement in practice.

Recent geological and geophysical studies have shown that oil supply channels are subvertical in the upper part of the earth's crust and, being part of tectonic disturbances, are linear or at least substantially non-isometric (in terms of) structures. Their horizontal extent can be measured in hundreds of meters, kilometers or tens of kilometers, while their thickness (again horizontally) can be tens and hundreds of times less and can be calculated from the first kilometers to the first meters. It is clear that the exact localization of such objects by seismic exploration is fraught with significant difficulties: if the very fact of the presence of the channel and its strike by seismic exploration is determined without any problems, then the error in determining the thickness of this channel and its position across the strike due to the physical limitations of the seismic method will be significant. As a result of this, targeted opening of oil supply channels by exploratory (vertical) wells is fraught with great difficulties and practically difficult.

To improve the efficiency of oil and gas prospecting, the “Method for the search for oil and gas fields” was proposed (announced on December 29, 2010, application No.2015154063 with a positive decision of March 2, 2012), based on the identification and localization of oil supply channels and deep reservoirs. The method consists in conducting seismic exploration of the MOGT in a super-deep modification, which predicts deep reservoirs (foci of generating hydrocarbons) and oil supply channels, conducting studies of the seismic exploration of the MOGT in 2D or 3D for tracing the oil supply channels, identifying the degree of activity of the oil supply channel, for which purpose in the territory the outlet of the oil supply channel, the instability of the gravitational field (NGP) is studied by conducting gravimetric observations measurements at fixed points on the terrain, and determining at each of them changes in the gravitational field in time and, in the presence of sections of increased instability of the gravitational field in time, subsequent drilling. For targeted opening of the oil and gas complex, gravimetric observations of geological surveys are carried out along profiles crossing the channels allocated by seismic exploration, and then a horizontal well is drilled across the strike of the active channel (s) or in the angle range of 60-120 degrees. At the same time, a horizontal well plays a search role: according to the results of field-geophysical and geological-technological studies carried out in it, exact localization of oil supply channels is carried out.

The technology for searching and localizing oil supply channels proposed in the aforementioned method creates the basis for the implementation of a fundamentally new ideological approach to oil production in practice - the selection of oil directly from the oil supply channel connecting the deep reservoir to the oil reservoir.

Oil coming from the channel can be extracted for a long time (tens and hundreds of years), in this case, a stable flow rate is maintained. Waterflooding technologies are not required; oil is extracted almost anhydrous. As noted earlier (RF patent No. 2204700), to increase the flow rate of deep hydrocarbon fluids, it is possible to use methods traditionally used to increase oil recovery (vibroacoustic treatment, hydrochloric acid treatment, etc.).

However, the proposed method only creates the basis for the implementation of a new ideology of oil production, but does not solve the problems of creating a development system that ensures production according to this ideology. The present invention solves the problem of creating a development system that provides oil production directly from the oil supply channel.

To solve this problem, in the method of searching and producing oil, which consists in identifying the oil supply channel by field and geophysical studies, evaluating its hydrodynamic activity by conducting multiple geophysical measurements and determining the change in the measured parameters in time, localizing the identified channel by drilling a horizontal well across the channel, determine the power of the oil supply channel and drill a second horizontal well along the strike of the oil supply channel its axial line, at the same time determine the current thickness of the oil supply channel and the position of the drilled well in it, while the well is drilled along the trajectory in the form of an anticlinal kink, then an insulating substance is pumped into this well, creating an artificial cover, and then below this cover well at a depth exceeding the penetration radius of the insulating substance, at least one horizontal well is drilled from which oil is taken.

The thickness of the oil supply channel and the position of the wellbore in it are determined by taking measurements therein while drilling using geophysical methods, such as oriented wave acoustic logging and azimuthal gamma-ray logging.

With a channel thickness exceeding 1.5 of the radius of penetration of the insulating substance, an additional well or cover wells are drilled at the same depth subparallel to the cover well, into which the insulating substance is pumped, while cover wells are drilled at a distance from each other not exceeding one and a half the penetration radii of the insulating substance pumped into them along the trajectory in the form of an anticlinal kink.

If the thickness of the oil supply channel is variable along the strike, at least one horizontal horizontal drilled well-borehole is drilled to the side of the channel, and the distance between the horizontal horizontal shafts should not exceed one and a half radii of penetration of the insulating substance injected into them.

Assessment of the channel’s hydrodynamic activity is carried out by conducting gravity prospecting using the method of gravitational field instability (GPS) or passive seismic monitoring, as well as by combining gravity exploration by the GPS method and passive seismic monitoring.

The essence of the method will be clear from the following description and drawings (Fig.1-4).

Figure 1-4 shows a diagram of opening the oil supply channel and the formation of production systems directly from this channel by horizontal wells, where 1 is the oil supply channel, 2 is the horizontal well, localizing, 3 is the horizontal well, 4, the horizontal well, producing, 5 - lateral horizontal trunks-tires, h ₁ and h ₂ - the depth of entry of a localizing horizontal well into and out of the oil supply channel (h ₂ -h ₁ ) - the thickness of the oil supply channel, L _to - the length of the oil supply channel, L _g - the horizontal length part of the well borehole.

According to the results of the identification and localization of the oil supply channel 1 by field and geophysical studies, the assessment of its hydrodynamic activity (for this, multiple geophysical measurements and determination of changes in the measured parameters over time are carried out, in particular gravity prospecting - the instability of the gravitational field), a search (localizing) horizontal well is drilled 2 across the trend of the channel, the channel thickness neftepodvodyaschego determined as the difference between, h ₂ and h ₁ and then strike it drilled horizon battening well-tire 3 (advanced navigation methods allow to pass the horizontal part of the barrel exactly localized channel) simultaneously determine the position of the drilled hole therein, and nature of the change channel thickness along the strike through it MWD.

Assessment of the hydrodynamic activity of the oil supply channel 1 can be carried out both by conducting gravimetric observations of different times at fixed points on the ground and determining the changes in the gravitational field in time on each of them, and by the method of passive seismic monitoring. In difficult geological conditions, gravity exploration of geological exploration is integrated with measurements using passive seismic monitoring.

The thickness of the oil supply channel and the position of the drilled well in it are determined by taking measurements in it during drilling using geophysical methods, such as oriented wave acoustic logging and azimuthal gamma-ray logging.

If the channel thickness is small (less than one and a half radii of penetration of the insulating substance) and is constant along the strike, then the insulating substance is pumped into the well 3, thereby creating an artificial tire. Then below this tire, at a depth exceeding the radius of penetration of the insulating substance, drill a horizontal barrel 4 from which oil is sampled (Fig. 1). To improve the shielding properties of the formed trap and increase the selection efficiency, the profile of the well-borehole 3 should be in the form of an anticlinal inflection.

If the thickness of the channel is more than one and a half radii of penetration of the insulating substance and is not constant along the strike (Fig.2-3), then create an artificial tire in the following ways:

1) in the case of constant along the strike thickness of the oil supply channel, at a depth equal to well 3 in FIG. 1, an additional horizontal well or wells blocking the oil supply channel are sub-parallel drilled. The distance between these wells should not exceed one and a half radii of penetration of the insulating substance injected into them (figure 2);

2) in the case of a variable along the strike thickness of the oil supply channel, lateral horizontal trunks 5 are drilled from the drilled horizontal well-cover to the lateral boundaries of the channel (before contact with the undisturbed enclosing rock mass). As in the previous case, the distances between the horizontal trunks are determined by the penetration radius of the insulating substance (figure 3);

3) a third option is also possible - a combined one, when not one but several horizontal borehole wells are drilled, and then lateral horizontal trunks of small length are drilled from one or several of them.

After the formation of an artificial tire, under this tire, at a depth exceeding the radius of penetration of the insulating substance, a horizontal trunk (s) are drilled from which oil is selected.

The length of horizontal shafts corresponds to the length (along strike) of the oil supply channel, determined according to 3D seismic data.

Drilling horizontal wells both to create an artificial tire and to take oil can be carried out from the day surface and, less costly, by kicking sidetracks from a horizontal search hole drilled to localize the oil supply channel.

If the length of the oil supply channel significantly exceeds the ability to drill horizontal wells of sufficient length, proceed as follows. Drill along the strike of the channel several horizontal wells - one after the other (figure 4)). Moreover, the profile of each of these wells should form an anticlinal inflection. That is, with a large length of the oil supply channel along the lateral, the formation of several artificial anticlinal traps is possible. The selection of oil from each of these traps is carried out separately from other neighboring traps by drilling independent production wells either from the day surface or from additional horizontal wells drilled across the channel strike (also clarifying the change in channel thickness along strike).

Claims (8)

1. The method of oil search and production, which consists in identifying the oil supply channel by field and geophysical studies, evaluating its hydrodynamic activity by conducting multiple geophysical measurements and determining the change in the measured parameters in time, drilling the well directly on the oil supply channel, characterized in that the identified channel is localized by drilling a horizontal well across the strike of this channel, determine the power of the oil supply channel and drill horizontal well along the strike of the oil supply channel along its axial line, at the same time determine the current thickness of the oil supply channel and the position of the drilled well in it, while the well is drilled along the trajectory in the form of an anticlinal kink, then an insulating substance is pumped into this well, creating an artificial tire, after which at least one horizontal well is drilled below this cover well, at a depth exceeding the penetration radius of the insulating substance Yat selection of oil. 2. The method according to claim 1, characterized in that the thickness of the oil supply channel and the position of the wellbore in it are determined by taking measurements therein by geophysical methods, such as oriented wave acoustic logging and azimuthal gamma ray logging. 3. The method according to claim 1, characterized in that when the thickness of the oil supply channel is greater than 1.5 of the radius of penetration of the insulating substance, sub-parallel to the well borehole, an additional well or borehole is drilled at the same depth into which the insulating substance is pumped, well-boring wells are drilled at a distance from each other, not exceeding one and a half radii of penetration of the insulating substance injected into them, along the trajectory in the form of an anticlinal inflection. 4. The method according to claim 1 or 3, characterized in that in the case of a variable along the strike thickness of the oil supply channel, at least one drilled horizontal cover well is drilled with lateral horizontal shafts to the lateral boundaries of the oil supply canal, while the distances between the horizontal lateral trunks should not exceed one and a half radii of penetration of the insulating substance injected into them. 5. The method according to any one of claims 1 to 3, characterized in that the hydrodynamic activity of the oil supply channel is estimated by conducting gravity exploration by the method of instability of the gravitational field - GSP. 6. The method according to any one of claims 1 to 3, characterized in that the hydrodynamic activity of the oil supply channel is evaluated by passive seismic monitoring. 7. The method according to any one of claims 1 to 3, characterized in that the hydrodynamic activity of the oil supply channel is estimated by combining gravity exploration by the GPS method and passive seismic monitoring. 8. The method according to any one of claims 1 to 3, characterized in that for a large length of the oil supply channel laterally, several horizontal wells are drilled along the strike of the oil supply channel — one after the other, while the wells are drilled along the trajectory in the form of an anticlinal bend, forming several artificial anticlinal traps, and the selection of oil from each of these traps is carried out separately from other neighboring traps by drilling independent production wells either from the day surface or from additional horizontal wells drilled across the strike of the oil supply channel.

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