RU2728000C1 - Method of guiding horizontal wellbore in target range of sedimentary rocks based on elemental analysis of slurry - Google Patents

Abstract

FIELD: soil or rock drilling.

SUBSTANCE: invention relates to geological tracking of well drilling for correction of trajectory of horizontal wellbore borehole in the target interval of sedimentary rocks on the basis of elemental analysis of slime. Method of horizontal well shaft boring in target range of sedimentary rocks based on element analysis of sludge involves obtaining during drilling of inclination and well logging data from the bottomhole of location of drilling tool, extraction and washing of slurry from drilling fluid with subsequent drying, correction of trajectory of shafting along target interval. Prior to drilling, target interval is divided into patches and sub-patches using logging data, microdescription of core and element composition of rocks, investigated with spacing of not more than 0.3 m. Based on seismic prospecting data and selected patches and sub-patches of target interval in all wells of the deposit by method of layer-by-layer deepening, three-dimensional structural framework of the target interval is constructed, and the planned profile of the horizontal wellbore is selected. Barrel passes through interval of cut, containing maximum volume of headers. Elemental composition of the slurry is quickly analyzed to determine slurry affiliation to a particular patch of the cut, and based on the logging data and the determined patch of the cut, a decision is made on the need to correct the trajectory of the horizontal wellbore.

EFFECT: high accuracy of guiding a horizontal shaft in target patches by accurate determination of the position of the drilling tool in the section of deposits, to minimize risks of flight to non-target patches of the section, loss of the shaft during collapse of unstable rocks, high efficiency of HFF, start-up rate and operating time of the well.

1 cl, 2 tbl, 4 dwg

Description

The invention relates to the field of field geophysics (geological support for drilling wells) and can be used to correct the trajectory of a horizontal wellbore in the target interval of sedimentary rocks based on elemental analysis of cuttings under sanctions restrictions on the use of high-tech geosteering equipment (GIS, LWD).

An important feature of sedimentary rocks is their layering and the stability of the mineral-component composition along the lateral with the variability of the composition of rocks along the vertical - this property is the main proposed method for laying a horizontal well. In practice, it has been proven that the most sensitive indicator of the variability of sedimentary rocks is not the mineral composition, but the elemental composition.

Productive reservoirs of sedimentary rocks are often thin (a few meters thick). The main technology for the development of thin-layered sedimentary rocks containing reservoirs is drilling wells with horizontal completion followed by hydraulic fracturing (hydraulic fracturing). The development efficiency multiplies in the case of horizontal wellbore drilling in the reservoir interval, since it is they that are optimal for the initiation of hydraulic fractures. Since the reservoirs compose thin strata, up to a few meters thick, the task of geosteering while drilling is relevant and nontrivial, which cannot be solved using known methods.

An example of target sedimentary intervals is source deposits such as the Bazhenov Formation.

Oil resources in the Bazhenov Formation, which has a regional distribution in Western Siberia, according to various estimates, amount to billions of tons. But they are still not being developed on an industrial scale due to the lack of an effective technology for extracting oil from them.

There are various methods of drilling horizontal wells of horizontal wells.

For example, a method for drilling a horizontal wellbore (RF patent No. 2263782), which consists in receiving bottomhole information by surface tools via a communication channel with operational monitoring and control of the wiring. In this case, the bottomhole information displays the position of the diverter relative to the magnetic meridian and the values of the azimuth and zenith angles obtained from the bottomhole sensors.

The disadvantage is that the drilling is carried out "blindly", based on the previously available information about the trajectory, without taking into account changes in the geological section, which can lead to the drilling of a horizontal wellbore outside the plane of occurrence of the productive formation.

The known method of posting a horizontal wellbore on the basis of geological research (RF patent No. 2313668). The method includes obtaining, using geological-technological, geological-petrophysical and lithofacies research, information from the bottom of the well about the location of the drilling tool. The obtained data analyze and build a correlation diagram of the lithological-facies state of the section with reference to vertical depths indicating the most promising intervals for oil and gas, and adjust the trajectory of the horizontal wellbore, which ensures the movement of the drilling tool along the productive formation.

All known methods of drilling a horizontal wellbore while drilling into the Bazhenov formation deposits do not give reliable results, since horizontal wellbores must be carried out in a narrow interval of the target pack, 2-3 m thick, which is impossible without detailed core studies before drilling and identifying the differences between the packs by elemental composition.

The technical result of the proposed invention is to improve the accuracy of drilling while drilling a horizontal wellbore in the target packs of layered sedimentary rocks, due to the accurate determination of the position of the drilling tool in the section of the sediments, which minimizes the risks of flying out into the non-target packs of the section, loss of the barrel during the collapse of unstable rocks, increase the efficiency of hydraulic fracturing , initial flow rate and well operation time.

The specified technical result is achieved by the proposed method of drilling a horizontal wellbore in the target interval of sedimentary rocks based on elemental analysis of cuttings, which includes obtaining logging data and data on the location of the drilling tool by directional survey during drilling, sampling cuttings drilled from the bottom of the well and adjusting the trajectory of the wellbore to the target interval, while the new one is that before the start of drilling, the target interval is divided into packs and sub-packs, using the logging data, the macro-description of the core and the elemental composition of the rocks, investigated with a step of no more than 0.3 m, then based on seismic data and selected packs and of the target interval in all wells of the field, the method of layer-by-layer deepening is used to build a three-dimensional structural frame of the target interval, and select the planned profile of the horizontal wellbore, so that the wellbore passes through the interval of the section containing the maximum a large volume of reservoirs, while after removing the cuttings, it is washed from the drilling fluid with subsequent drying, then the elemental composition of the cuttings and logging data are promptly examined to determine the cuttings belonging to a particular section of the section and, based on the data obtained, a decision is made on the need to adjust the trajectory of the horizontal wellbore ...

The delivered technical result is achieved due to the following.

Typically, horizontal wells are drilled using high-tech logging equipment (GIS, LWD), which transmits data in real time to determine the position of the bit in the target sediment section. In modern conditions, when drilling on the Bazhenov suite and similar objects of thin-layered sedimentary formations, the use of such equipment is often impossible. When drilling in real time, only the following logging methods are available: GK and directional survey. It is impossible to separate the section of the Bazhenov Formation based on logging alone. There was a need to develop the proposed method, with the help of which it would be possible to determine the position of the bit in the section with maximum accuracy.

Preliminary division of the section into packs and sub-packs, carried out on the basis of a macro-description of the core and determination of the elemental composition of rocks, investigated with a step of no more than 0.3 m, makes it possible to compile an accurate description of the entire section, revealing the unique features of all the units identified in it.

Washing the rock from the drilling mud allows you to correctly determine the elemental composition of the cuttings rocks by cleaning it from the drilling mud.

On-line determination of the elemental composition of the drilled rock allows obtaining reliable data on the section of the Bazhenov formation from which it was sampled, which makes it possible to judge the current location of the bit in the section and promptly make a decision on the necessary correction of the drilling trajectory.

Thanks to the construction of a detailed three-dimensional structural frame of the Bazhenov formation section, which is the basis of the planned profile for drilling, based on the definition of the pack in which the bit is located, the compliance of the planned profile with the actual geology is assessed, as well as, if necessary, the well drilling trajectory is adjusted.

Taking into account the comparison of the planned profile and data on the elemental composition of the cuttings, the trajectory of the horizontal wellbore is corrected, which ensures the movement of the drilling tool along the productive formation.

As an example, the method of drilling of horizontal wellbores in the interval of the Bazhenov formation at the Sredne-Nazymskoye field is considered.

The method of drilling a horizontal wellbore in the sedimentary oil source deposits of the Bazhenov formation, with a target permissible drilling interval of 2-3 m, is represented by the following graphic images:

fig. 1 - Section of the Bazhenov Formation, divided into 6 members and sub-members;

fig. 2 - An example of a detailed per-by-step correlation of wells 231R, 5231R, 3005 and 3006 in the interval of the Bazhenov formation of the Sredne-Nazymskoye field.

fig. 3 - Structural map of the roof of the Bazhenov formation.

fig. 4 - An example of a planned profile for drilling a horizontal well 111 with a length of 1500 m.

Table 1 shows the Boundary and average values of the contents of elements and their ratios in the section of the Bazhenov formation at the Sredne-Nazymskoye field. Table 2 shows the main distinguishing features of the members of the Bazhenov Formation.

A preliminary study of 14 reference wells with core and 42 wells with logging data was carried out at the Sredne-Nazymskoye field. FIG. 1 shows a section of the Bazhenov Formation, divided into 6 members and sub-members, where the numbers correspond to the numbers of the members of the section.

Member 1. Dark-brownish-gray silicites, low-clayey and low-carbonaceous, in thin (2-3-15 cm) interbedding with siliceous radiolarites (more often) and heterogeneously carbonated (less frequently).

The interval of unit 1 on the logging curves is on the decline (from bottom to top) of the IK values, a slight rise in VC, there are increased, compared to the underlying sediments, the values of natural radioactivity, reflecting an increase in the content of organic carbon (Corg). Thus, the log curves of unit 1 show a smooth transition from the underlying formations to the typical Bazhenov ones. Numerous thin (first cm) radiolarite interlayers are reflected in the jagged logging of well logging curves. Bottom-up, to the top of the member, an increase in NKT and density values follows up to a distinct peak in the curves of these values, which corresponds to a relatively thick (up to 1 m) interlayer of radiolarites in the top of the member. The radiolarite interlayer is heterogeneously carbonated (up to secondary limestone or dolomite), which determines the peak amplitude according to NKT, VC and density methods.

Unit 1 is ubiquitous, matured, and is characterized by a low thickness of about 2 m.

Member 2 - slightly clayey carbonaceous silicites (Corg 5-10%) with different-sized interlayers and interlayers (0.01-1 m) of radiolarites, rare bivalves, ammonites and numerous remains of radiolarians, fish, and teutids.

On the logs, unit 2 has moderately increased GK, VC, minimum IK, caliper. The boundaries of layers 2a and 2b are broken off along the most thick and sustained radiolarite interlayers - contrasting local minima GK and DT, maxima NTK and density. The thickness of member 2 is variable; in the studied area it reaches 7 m.

Member 3 is “radiolarite”. It is represented by high-siliceous silicites and radiolarites, most often secondary calcified or dolomitized, with thin (first cm to a few tens of cm) interlayers of more clayey (up to 20% clay) silicites.

This interval is clearly expressed on the logs as a positive HA anomaly (the first HA anomaly is below the top of the first stratum of the Bazhenov horizon). In the upper layer (3b), thick layers of radiolarites are usually developed, including the secondarily carbonated ones. Layer 3b is plotted on the log as a single compacted interval (minimum GK and DT, maximum NTK and GGK). The thickness of the radiolarite member is on average about 3 m.

Member 4 - “high-carbon” - is contrasted with abnormally high OM contents, high radioactivity, increased clay content, lateral homogeneity and consistency. The tops of the member can be secondary calcitized. Presented in two layers.

On the well logging, the “high-carbon” member is clearly expressed by a large peak of high values of natural radioactivity, lower values of neutron logging and density in relation to the enclosing rocks, and higher values of acoustic logging. In the case of the presence of an abundant amount of small calcareous nodules of various shapes, intervals of contrasting dense rocks are observed on the logging curves. The sole of the pack corresponds to the sole of the upper layer. The roof runs along the compacted interval, the appearance of layers saturated with buchia and coccolithophorids. The average thickness is 3-4 m.

Member 5 - "coccolithophoride" - high-carbon carbonate-clayey silicites. The rocks are heterogeneously saturated with biogenic carbonate - the remains of coccolithophorids.

On the GIS, a layer is expressed as an interval of decreased GK values, increased NKT values.

Above - on the well logging interval with abnormally high sustained values of the GK curve. Distinctly overestimated lateral logging values correlate with high content of carbonate material and OM (Corg 15-25%). The layer is characterized by the highest resistivity in the Bazhenov horizon.

Member 6 is “pyrite”. It is composed of siliceous carbonaceous clays up to clayey silicites. The rocks are thinly horizontally layered, intensely pyritized, carbonate-free (rarely low-carbonate) with the constant presence of fish remains.

The "pyrite" member is distinguished by a distinct decrease in the HA values in relation to the lower and overlying deposits. Neutron logging has sustained values. Induction and density logs from bottom to top have a smooth gradual rise in values.

The Bazhenov Formation is overlain by terrigenous rocks of the Frolov Formation, the lower part of which is represented by bituminous clays. The boundary on the logging is confident - by the appearance of highly radioactive sediments with low resistance (clay) with an uneven wall in the wellbore.

On the available core from reference wells in the interval of the Bazhenov suite, the elemental composition of rocks was determined with a determination step of 3 measurements per meter, table 1 was compiled with the characteristics of each pack and fill.

Based on the identification of packs by core and logging in the key wells, logs were identified in all 42 wells of the field. As a result of detailed per-by-stage correlation of wells (Fig. 2), the following breaks were obtained: 6b - top of unit 6b - top of Bazhenov formation; 6а - top of unit 6а; 5b - top of unit 5b; 5а - top of unit 5а; 4b - top of unit 4b; 4а - top of unit 4а; 3 - roof of unit 3; 2b - roof of unit 2b; 2а - top of unit 2а; 1 - roof of unit 1; 1_bot - bottom of unit 1 - bottom of the Bazhenov Formation. A three-dimensional structural frame of the Bazhenov formation was constructed based on the integration of seismic and logging data by the method of layer-by-layer deepening.

Generalization of geological and geophysical information on the Bazhenov formation of the Sredne-Nazymskoye field made it possible to establish the presence of several intervals of reservoir development in it - these are units 2, 3 and less often 5.

Core study showed that the reservoirs are confined to tight rocks, represented by:

- siliceous radiolarites and secondarily carbonated radiolarites with fractured-porous reservoir space, distributed mainly in the lower part of the section - members 3 and 2;

- fractured peloid-intraclastic limestones and shells in the upper part of the section - member 5.

As the target interval for drilling the horizontal wellbore, units 3 and 2 were selected, which have the highest mineralogical rock density, therefore, the most stable for drilling; these units contain the maximum volume of the Bazhenov formation reservoirs, which will help to obtain the maximum oil inflows after hydraulic fracturing.

Planned profiles for drilling were built based on the choice of the location of the horizontal wellbore in the area and the structural frame. The profile trajectory was laid along the top of the pack 26 or its middle in order to minimize the risk of flying out into the non-target pack of the section (Fig. 4). Further, the calculation of the drillability of the profile by the standard method followed.

At the field, the GTI station, which is responsible for the selection of cuttings, is being retrofitted with devices for the rapid determination of the elemental composition (by XRF method) of cuttings.

In the process of drilling, cuttings are taken by a standard method.

Cuttings sampling begins 50 m from the proposed top of the Bazhenov formation in order to fit the casing into the most stable target unit of the section (unit 3), the rock drilled at the bottomhole comes to the surface after 40-60 minutes by means of drilling mud circulation.

At the exit of the sludge, the first sample of it weighing 150-200 g is taken from the vibrating screen, while the depth of origin of the sludge is calculated by the GTI software according to the standard method. A subsequent sample of the cuttings is taken with equal frequency every 4 meters. Only one sludge sample is taken at a time.

The cuttings sample is delivered from the drilling rig to an equipped room for cleaning and drying cuttings. First, the OBM is washed out by means of diesel fuel until all the OBM components leave the drilled rock particles. Then a control wash is carried out in unleaded gasoline and an aqueous solution with a surfactant - Fairy (manufactured by Procter and Gamble). The washed sludge is dried with a construction hair dryer under a hood until completely dry. Then the elemental composition of the rock is determined.

Cuttings composition data are analyzed in conjunction with cuttings petrography (Table 1) and gamma ray logs obtained during drilling. The stratigraphic binding of the sample is determined by the table of boundary values (Table 1) and by the plotted graphs and histogram, after which a conclusion on the position of the bit is issued.

This data is used to track the trajectory of the drilling tool.

Comparison of the bit position determined from the cuttings with the planned profile allows, if necessary, to adjust the drilling angle in order not to exit the target block of the section. It is recommended to drill in the central part of unit 2.

To date, 9 wells have been drilled with a total length of horizontal wells 13,500 m long, the initial oil production rates of the wells amounted to 50-120 tons / day.

Claims (1)

A method of drilling a horizontal wellbore in a target interval of sedimentary rocks based on elemental analysis of cuttings, including obtaining logging data and data on the location of a drilling tool by directional survey while drilling, taking cuttings drilled from the bottom of the well, and adjusting the trajectory of the wellbore at the target interval, which is different the fact that before the start of drilling, the target interval is divided into packs and packs, using logging data, a macro-description of the core and the elemental composition of rocks, studied with a step of no more than 0.3 m, then based on seismic data and the selected packs and packs of the target interval in all wells field by means of layer-by-layer deepening, a three-dimensional structural frame of the target interval is constructed, and a planned profile of the horizontal wellbore is selected, so that the wellbore passes through the interval of the section containing the maximum volume of reservoirs, while after removing cuttings it is produced washing off the drilling fluid followed by drying, then the elemental composition of the cuttings and the logging data are promptly examined to determine the cuttings belonging to a particular block of the section and, based on the data obtained, a decision is made on the need to adjust the trajectory of the horizontal wellbore.

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