RU2737476C1 - Method for geosteering horizontal and directional wells in low-power formations - Google Patents

Abstract

FIELD: physics; mining.

SUBSTANCE: invention relates to geophysical exploration of geological exploration wells at alternating current during drilling and can be used for geosteering horizontal and directional wells in formations of reservoirs. Method comprises: geosteering of horizontal or directional well bores in low-power formations includes control of the process of drilling the well in the reservoir of the oil collector based on comparative analysis of distances to the boundary with beds of enclosing rocks, having contrasting properties as per specific resistivity relative to oil collector rocks. That is ensured by passing current pulses through the generator coil and recording the EMF of the transient processes in the receiving coil. Determination of the distances to the formation boundary is performed successively at two points of the well axis at a distance of not less than 1 m, during drilling as per values of time of extremums of EMF drop signals in the receiving coil. At the same time drilling direction is preserved when obtaining close values of distances obtained at two points on the well axis. Drilling direction is changed to obtain distances differing from each other. Drilling direction varies depending on the sign of the difference in distances.

EFFECT: technical result is improved accuracy of geosteering in reservoirs of low power.

1 cl, 3 dwg

Description

The proposed invention relates to the field of geophysical research of directional wells in the process of drilling and can be used when drilling sub-horizontal wells in thin (up to 2 ÷ 3 meters) formations, productive for hydrocarbons, to avoid uncontrolled opening of the underlying aquifers of the reservoir bottom or clay roof.

The known method of geosteering of horizontal wells, including high-frequency induction logging isoparametric sounding with measurement of a number of EMF amplitudes and at least five phase differences, identification of reservoirs and technogenic electrical inhomogeneities (VIKIZ). The change in the phase difference and the values of the amplitudes of the extrema of the EMF are judged on the accuracy of the wellbore in the reservoir [1]. The device for performing the known method contains five induction geometrically similar probes, each of which is formed by a transmitter and a receiver coils, the axes of the coils are coaxial with the axis of the well. The method is suitable for geosteering of directional wells in productive formations of large (more than 3 meters) thickness and is ineffective in formations of low (less than 3 meters) thickness.

The known method of geosteering of horizontal wells, based on the excitation of a pulsed electromagnetic field using an electric dipole powered by a pulsed bipolar current [2]. Measurement of magnetic fields is carried out during a pause between current pulses by inductive sensors oriented in three orthogonal directions. By analyzing the curves of the extreme values of the amplitudes of the decay of the magnetic fields, commands are generated to control the position of the whipstock of the drilling tool. The measuring module is made in the form of a non-magnetic tube with supply electrodes located at the ends. Inductive sensors are located in the body of the pipe. The main disadvantage of this method is the use of an electric dipole with a system of galvanic electrodes powered by a pulse current as a source of the supply field. The use of galvanic contacts in the wells of the old stock does not make it possible to achieve the necessary identity of the excitation conditions at each observation point.

The known method of induction logging of wells while drilling, which can be used for geosteering purposes, which is a prototype of the proposed method [3]. The method includes passing current pulses through a generator coil, recording the voltage amplitude of the EMF of transient processes in the measuring coil. The induction logging device contains a transmitter and a sensing coil located coaxially on a non-magnetic metal pipe built into the bottom hole assembly, a pulse current source connected to the transmitter coil, and the sensing coil connected to a processing device.

The main disadvantage, leading to the impossibility of widespread practical application of the prototype method [3], is that for the implementation of this method, a device mounted on a non-magnetic conducting body is proposed. The systems of the generator and receiving solenoid coils are connected by a single conductive core-pipe, the physical properties of which are highly dependent on external factors (temperature, etc.). This actually leads to the defining dependence of the system of registered EMF amplitudes on uncontrolled external factors (the conductivity of the borehole fluid and the conductivity of the metal of the supporting drill pipe) and, accordingly, to the impossibility of obtaining identical repeatable results in real borehole conditions. Especially the influence of interfering factors on the parameter of the EMF amplitude is enhanced in cases of drilling with saline (conducting) solutions. It is practically impossible to shield the coils from the core connecting the receiving and generating coils, therefore, the level of uncontrolled noise during the measurement increases dramatically. Measurements of the EMF amplitude in the range of 0.1-200 µs with elimination by filtering the signal in the range over 30 µs, as proposed in the patent [3], does not allow any interference caused by external factors and the direct influence of the generator coil field on the values EMF amplitudes on the receiving coil through the effective core and are comparable with the useful signal or, as a rule, significantly exceed it.

The purpose of the proposed solution is to improve the accuracy of geosteering of directional wellbores in low-power reservoir formations by using pulsed excitation of the electromagnetic field and recording the temporal characteristics of transient processes of the electromagnetic field, which provide increased measurement accuracy and reduce dependence on external uncontrolled interference.

The method for geosteering horizontal and directional wells in low-power formations includes determining the distance to the boundary with host rocks with contrasting properties in resistivity with respect to the formation by passing current pulses in the generator coil and recording the temporal characteristics of the position of the extrema of the EMF decay of the electromagnetic field in the take-up spool.

The proposed method differs in that the determination of the distance to the boundary with the enclosing rocks is carried out on the basis of the analysis not of the EMF amplitude, but of the values of the time of the extremum of the EMF decay t _extr in the receiving coil located at a distance L from the generator coil (Fig. 1) [4, 5] ...

It is known [6] that in the pulsed mode of excitation and registration of EMF decay with coaxial generator and measuring coils of small radii, in comparison with the spacing L, the position of the EMF extremum on the time axis t in a homogeneous medium is determined only by the values of the spacing and the specific electrical resistance of the medium ρ ( fig. 1):

t = μ ₀ L ^2/10 / ρ, where μ ₀ - magnetic constant.

In heterogeneous conductive rocks, under the additional influence of the resistance of the drilling fluid and the conductive drill string, the dependence of the EMF extremum value is more complex [6] and is numerically determined using the sinus Fourier transform on the spectral characteristic of the imaginary quadrature of the axial component of the magnetic induction ImB _z :

where: S _and - effective area of the measuring coil, m ² ; t - time, s; ω - circular frequency, sec ^-1 .

The effect of the resistance of the drilling fluid and the resistance of the metal of the supporting drill string on the EMF value can be considered constant during the drilling of the well and the amplitude of the EMF voltage will be determined by the resistance of the rocks of the oil reservoir along which the directional wellbore is drawn (Fig. 2) [6].

It is known that the specific electrical resistance is determined by the genesis of the reservoir rocks. For example, the reservoir of the terrigenous type is low-resistivity, and the reservoir, composed mainly of carbonate rocks, is usually high-resistivity [7].

For the main oil-saturated thin reservoirs (water-saturated bottom, clay roof), the resistance of the rocks is distributed as follows (for example): the resistance of the clay roof is 3.5 ÷ 6 Ohm⋅m, for the gas-saturated roof up to 50 Ohm сопротивлениеm, the resistance of the reservoir rocks is 12 ÷ 20 Ohm ⋅m, the resistance of rocks of the water-saturated bottom is 25 ÷ 40 Ohm⋅m [7]. In fact, the rocks of an oil-saturated reservoir are a contrasting zone in terms of resistivity. The investigated range of values of electrical resistivity of rocks is from 3 to 200 Ohm⋅m (Fig. 2), which makes it possible to fix the geometric position of the wellbore relative to the base - reservoir - top system, provided that the petrophysical properties of the reservoir rocks and enclosing sediments are known in advance.

The values of the electrical resistivity values of the rocks that make up the section are assumed to be known from the data of electrical logging methods for exploration wells in this area and laboratory studies of the core extracted during drilling.

FIG. 3 presents materials that explain the principle of implementation of the proposed technical solution.

To determine the distance to the boundary of media with different electrical resistivities, an installation of coaxial transmitter and measuring coils located at a distance L from each other (spacing) is used. The axis of the installation is initially parallel to the boundary of media with different electrical resistivity. The distance between the axis of the installation and the boundary of the media is h.

FIG. 3 shows the palette for determining the distance h to the boundary of the media by the time value t _{extr of the} extremum of the EMF decay of the electromagnetic field with the contrast of the specific electrical resistance of the media, for example, 4 times.

To reduce the number of parameters required to determine the distance to the boundary, FIG. 3, the time f _{extr is} reduced to the value L ^{2 of the} separation distance of the installation and is designated as the reduced time T _p , and the distance h is reduced to the separation of the installation L. The obtained dependence T _p is due to different electrical resistivity of rocks and the distance from the installation to the boundary of the media h As seen in FIG. 3, the proposed method makes it possible to determine the distance to the boundary of media with different specific electrical resistances of rocks by the time of extreme values of the EMF values of the decay of the electromagnetic field.

The methodology of the geosteering process of directional wells based on the proposed method is reduced to monitoring the distances to the boundary with the enclosing rocks, which have contrasting properties with respect to the formation according to the values of the time of the extrema of the EMF decay in the receiving coil when passing current pulses through the transmitter coil at two points on the axis wells spaced from each other, for example, at a distance of at least 1 meter, determining two different distances to the border of contrast media, and maintaining the direction of drilling when obtaining close values of distances or changing the direction of drilling when obtaining distances that differ from each other, and the direction of drilling change depending on the sign of the distance difference.

The essence of the claimed invention is expressed in a set of essential features sufficient to achieve the technical result, which is expressed in increasing the accuracy of determining the distances from the well being drilled in an oil reservoir and the host rocks of the top or bottom of the formation.

The stated set of essential features is in a direct causal relationship with the achieved result. An analysis of the current state of the art showed that the proposed technical solution meets the criteria of "novelty" and "inventive step" and can be industrially implemented using existing technical means.

Sources used in the preparation of the application:

1. Antonov Yu.N., Epov M.I., Glebocheva N.K., Medvedev N.Ya., Ikhseanov R.K. Method for geosteering of horizontal wells. RF patent No. 2230343. 10.08.2003. Bul. No. 22.

2. Teplukhin V.K. Method for geosteering of horizontal wells and device for its implementation. RF patent №2395823. 27.07.2010. Bul. No. 21.

3. Potapov A.P., Sudnichnikov V.G., Chuprov V.P., Belkov A.V., Sudnichnikov A.V. Method for induction logging of wells while drilling. RF patent No. 2466431. 10.11.2012. Bul. No. 31.

4. Ratushnyak A.N., Baidikov SV., Teplukhin V.K. Induction logging of wells while drilling // Izv. universities. Mining Journal. 2017. No. 3. S. 93-102.

5. Teplukhin V.K., Ratushnyak A.N., Kostitsyn V.I., Wang Xiaolong. Development of technology for induction logging in non-stationary mode when drilling sub-horizontal sections of oil and gas wells. // Bulletin of Perm University. Geology. 2017. Volume 16, No. 2. S. 122-129.

6. Ratushnyak A.N., Teplukhin V.K. Theoretical and experimental foundations of induction methods for well survey. Yekaterinburg: Ural Branch of the Russian Academy of Sciences, 2017 .-- 127 p. ISBN 978-5-7691-2479-2.

7. Technology for research of oil and gas wells based on VIKIZ. Methodical guide // Ed. Epov M.I., Antonov Yu.N. Novosibirsk: SRC JIHGM SB RAS, Ed. SO RAN, 2000, 121 p.

Claims (3)

A method for geosteering of boreholes of horizontal or directional wells in low-thickness formations, including control of the process of drilling a well in an oil reservoir based on a comparative analysis of the distances to the boundary with host rock formations with contrasting resistivity properties in relation to the oil reservoir rocks, by passing current pulses through the generator coil and recording the EMF of transient processes in the receiving coil, characterized in that the determination of the distances to the boundary of the layers is carried out sequentially at two points of the borehole axis, spaced at a distance of at least 1 m during drilling, measuring the time values at which the EMF decay of the electromagnetic field have extreme values, and: - keep the direction of drilling while obtaining close values of the distances obtained at two points on the axis of the well; - change the direction of drilling when obtaining different values of the distances, and the direction of drilling is changed depending on the sign of the difference in distances.

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