RU2561420C1 - Hydraulic fracturing technique in two parallel horizontal boreholes - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: technique includes determining primary stress direction in the reservoir, drilling two parallel boreholes, their casing, cementing and perforating and performing hydraulic fracturing. Two parallel horizontal boreholes are drilled in the same plane in direction of minimum stress. Considering primary stress of the reservoir optimal location of fractures is calculated and position points for initiating hydraulic fracturing is identified. Perforation and hydraulic fracturing of the first stage are performed in both horizontal boreholes; intervals of performed hydraulic fracturing of the first stage are isolated by installation of frac plugs. Then perforation, hydraulic fracturing of the second stage and isolation by installation of frac plugs are performed with offsetting points of hydraulic fracturing initiation. Fractures in one borehole are oriented towards intermediate zone of the other borehole. Points of hydraulic fracturing initiation at adjacent horizontal boreholes may be shifted in regard to each other per a half of length of hydraulic fracturing intervals.

EFFECT: improving the efficiency of reservoir hydraulic fracturing.

2 cl, 2 dwg

Description

The invention relates to the oil industry and can be used in the development of oil fields having productive formations with ultra-low reservoir filtration and reservoir properties, including carbonate-clay-siliceous strata of the Bazhenov and Abalak formations, by hydraulic fracturing.

A known method of multiple hydraulic fracturing (hereinafter - hydraulic fracturing) in a horizontal wellbore (RU 2472926 C1, E21B 43/267, publ. 20.01.2013), equipped with filters at different intervals of the reservoir, including determining the direction of the horizontal well relative to the direction of the minimum principal stress rocks and the successive formation of cracks opposite the filters at various intervals of the reservoir, opened by a horizontal wellbore, and hydraulic fracturing is repeated separately for intervals when the minimum e the main stress of the rocks is directed parallel to the horizontal trunk, and for intervals when the minimum main stress of the rocks is directed perpendicular to the horizontal well, longitudinal and transverse cracks are obtained.

The main disadvantage of this technical solution is the formation of one hydraulic fracture at each stage only along the direction of minimum stress, which limits the coverage area of the fractures with the rock.

The closest in technical essence (prototype) is the hydraulic fracturing method (RU 2401943 C1, E21B 43/26, published on 10/20/2010), which includes drilling two horizontal shafts from a vertical well, perforating them, then lowering the casing into each horizontal well, and perforation in horizontal wellbores is carried out using a hydromechanical slotted perforator in one round trip operation in each horizontal wellbore, azimuthally oriented in the direction from one horizontal wellbore to another a vertical plane extending parallel to the vertical axis of the well borehole and perpendicularly to the axis of the lower horizontal hole, and then download the fracturing fluid and sand carrier produced in each horizontal shaft.

The disadvantages of this technical solution are the lack of hydraulic fracturing efficiency associated with the following reasons:

1) the location of the horizontal trunks in one vertical plane or at a fixed angle limits the coverage area of the reservoir rock,

2) shank cementing leads to the closure of natural fracturing and microcracking, which provide an additional flow of hydrocarbons,

3) the implementation of one hydraulic fracture on both horizontal wellbores in one vertical plane leads to the intersection of the coverage area of two horizontal wellbores and the hydraulic fracture plane, which limits the flow of hydrocarbons to the well.

The solved problem of the invention is to increase the efficiency of hydraulic fracturing due to greater coverage of the reservoir rock with the creation of a network of cracks oriented to the intermediate zones of adjacent horizontal shafts, which allows to cover large volumes of the reservoir with hydraulic fractures.

The problem is solved in that in the method of hydraulic fracturing in two parallel horizontal boreholes, including determining the direction of the main stress of the formation, drilling two parallel horizontal boreholes, casing, cementing and perforating, and, according to the invention, two horizontal parallel boreholes in one horizontal plane in the direction of minimum stress, calculate, taking into account the main stress of the reservoir, the optimal location of the cracks and determine the distribution the location of the fracture initiation points of hydraulic fracturing - hydraulic fracturing, perforating and hydraulic fracturing of the first stage are carried out in both horizontal shafts, isolate the intervals at which the first hydraulic fracturing stage was carried out by installing frac jumper, then perforating, hydraulic fracturing and isolating by installing the frac bulkhead of the next stage displacement of the fracture initiation points, and the location of the fracture initiation points is determined so that the cracks on one wellbore are oriented in the intermediate zone of the other wellbore. In addition, the initiation points of hydraulic fractures on adjacent horizontal trunks can be offset relative to each other by half the length of hydraulic fracturing intervals.

Horizontal shafts are drilled in one horizontal plane or in one plane close to horizontal, so that the shafts do not extend beyond the formation in the direction of minimum stress, then the respective stages of both horizontal shafts are punched, then hydraulic fracturing is carried out at an increased fluid flow rate in each the wellbore (more than 8 m ³ / min), after which set jumpers, isolating intervals of horizontal wells, on which hydraulic fracturing was carried out. The main hydraulic fractures are oriented according to the maximum stress, perpendicular to the horizontal boreholes.

The initiation points of hydraulic fractures on adjacent horizontal boreholes are offset relative to each other by half the length of the hydraulic fracturing stage, so that when performing hydraulic fracturing at all stages of the hydraulic fracturing on one wellbore, they are oriented to the intermediate zone of another wellbore, except for extreme hydraulic fractures.

In FIG. 1 shows the layout of the wellbore, which shows:

1 - horizontal wellbores,

2 - perforated intervals of the first stage of hydraulic fracturing,

3 - dressing bridge to isolate the first stages,

4 - the main hydraulic fractures of the first stage,

5 - secondary cracks oriented in different directions,

6 - dressing jumper of the second (subsequent) stage.

In FIG. 2 presents the parameters of a typical hydraulic fracturing design.

Hydraulic fracturing is carried out sequentially from right to left.

The proposed invention is implemented by the following sequence of operations:

- Determine the direction of the main stress of the reservoir;

- On the basis of geophysical surveys determine the direction of the minimum stress of the rocks;

- Drill two horizontal shafts 1 parallel to each other in a horizontal plane in the direction of minimum stress, then lower the casing into each horizontal well and cement them;

- Calculate, taking into account the main reservoir stress, the optimal location of the fractures to involve the largest hydrocarbon reserves and determine the location of the points of initiation of the hydraulic fractures 4. The fractures on one wellbore are oriented to the intermediate zone of the other wellbore. The initiation points of hydraulic fractures on adjacent horizontal trunks can be offset relative to each other by half the length of hydraulic fracturing intervals;

- In horizontal trunks 1 install perforators (not shown in the diagram) and perforate the intervals of the first stage of hydraulic fracturing 2;

- Conduct hydraulic fracturing of the first stage of both horizontal boreholes with such hydraulic fluid flow to stimulate the formation of primary fractures 4 and secondary cracks 5. Secondary fractures 5 are formed, oriented in different directions due to geomechanical effects associated with rarefaction zones on the primary hydraulic fractures;

- Install frac-jumpers 3 to isolate the first stage of hydraulic fracturing;

- After isolation of the first stage of hydraulic fracturing, perforation of both horizontal shafts is performed at the second stage of both horizontal shafts located at a distance determined from the optimization points of the hydraulic fracturing of the first stage (at pre-selected production intervals or at fixed distances to ensure the design density of hydraulic fractures);

- Conduct hydraulic fracturing of the second stage and isolation with the help of jumpers. The operation is repeated as many times as necessary.

An advantage of the present invention over the prototype is that when creating hydraulic fractures on adjacent horizontal boreholes 1 of the well, rarefaction zones are formed in the intermediate zone between hydraulic fractures 4 due to the additional stress exerted by the internal pressure of the hydraulic fractures when they are opened. As a result, the anisotropy of the stress field in the rock is reduced. Along with the formation of the main crack 4 and induced cracks 5 in the direction of minimum stress, rarefaction zones are revealed in the perpendicular direction to the main cracks, which leads to different orientations of the secondary cracks 5. In this way, connected fracture channels are created that unite the main cracks 4 and induced secondary cracks 5.

For hydraulic fracturing according to this technology, it is necessary to use fluids with low viscosity as hydraulic fracturing fluid to increase the pressure in the rock and the penetration of the fluid into the fracture formed. This technology is proposed for ultralow-permeable reservoirs, including carbonate-clay-siliceous strata of the Bazhenov and Abalak formations with high values of Young's modulus.

The method is illustrated by the following example.

The Bazhenov formation is being developed, characterized by low permeability of less than one millidars. According to the results of hydraulic fracturing analysis at the wells of cluster 100 of the Salymskoye field, it was found that traditional fracturing with traditional completion technologies, in the conditions of the Bazhenov formation, is low-efficient.

The roofing of the Bazhenov Formation (upper member of the 1st cycle) consists mainly of mudstones. The average value of Ed = 21 GPa (Young's modulus), md = 0.25 (Poisson's ratio), BI = 0.8 (Fragility Index). The sole of each cycle and the KS1 interval are characterized by an increased content of carbonated intervals. The interval of change of values: Ed = 24 ÷ 47 GPa, md = 0.17 ÷ 0.22, BI> 0.9. In the remaining intervals, represented mainly by silicite, the interval of variation of values: Ed = 12 ÷ 21 GPa, md = 0.2 ÷ 0.25, BI = 0.6 ÷ 0.8. Thus, in the Bazhenov Formation, rocks are non-fragile (silicites) and brittle (carbonated intervals and mudstones) with a significant contrast of geomechanical properties. In this case, partially in the second and third cycles of sedimentation and in the KC1 interval, rocks tend to form cracks (technogenic cracks according to Sonic Scaner, FMI, MDT).

The method of acoustic logging determined the direction of the minimum formation stress and in this direction we drilled two parallel horizontal shafts 1 with a length of 1000 meters of a productive rock formation with a thickness H of 30 meters in one horizontal plane parallel to each other on the rocks of the Bazhenov formation. Horizontal trunks 2 are placed at a distance d1 = 15 meters from the top of the formation and at a distance d2 = 100 meters from each other. Casing, cementing and preparation for hydraulic fracturing are carried out on both shafts (installation of pumping equipment, reservoirs for hydraulic fracturing and proppant, high pressure pipes and fountain fittings). To involve the largest hydrocarbon reserves on the basis of the geological model of the reservoir (location of hydrocarbon reserves) and productive intervals measured by well logging, we determine the location of the points of initiation of the main hydraulic fractures of the first stage. Next, in both horizontal bore 1 is installed cumulative perforator in the area under hydraulic fracturing. Perforation work is carried out in the first stage. Hydraulic fracturing is carried out at an increased flow rate (more than 10 m ³ / min) in each of the trunks. The length of the section of each stage of hydraulic fracturing is more than 100 meters. 51 tons of proppant 30/50, 4 tons of proppant 20/40 and 46 tons of proppant 16/20 will be required to create a crack system with a length of 150-200 m (stage 1) and fix a main crack with a half length of 75-100 m (stage 2). Typical fracturing design parameters are shown in FIG. 2.

At the end of the hydraulic fracturing, a frac jumper 3 is pressed through the hydraulic fracturing line to the borehole to a depth above the perforation interval where the last hydraulic fracturing was performed, but below the next place under the hydraulic fracturing, thus isolating the completed hydraulic fracturing stage from the next. Next, the operations are repeated for the second and subsequent stages at equal distances from each other, which are more than 100 meters and are selected for reasons of economic feasibility of creating the density of hydraulic fractures.

The cumulative perforator can be lowered together with the jumpers fixed to it, on a geophysical cable or on a flexible tubing.

Improving the efficiency of hydraulic fracturing is carried out due to the formation of a connected network of channels from secondary induced cracks that allow hydrodynamic bonding of a larger reservoir volume than without creating such a network.

Claims (2)

1. The method of hydraulic fracturing in two parallel horizontal wellbores, including determining the direction of the main stress of the formation, drilling two parallel horizontal wells, casing, cementing and perforating, and hydraulic fracturing, characterized in that two horizontal parallel wells are drilled in one horizontal the plane in the direction of the minimum stress, calculate, taking into account the main stress of the reservoir, the optimal location of the cracks and determine the location the fracture initiation points of hydraulic fracturing - hydraulic fracturing, perforating and hydraulic fracturing of the first stage are carried out in both horizontal shafts, isolate the intervals at which the first hydraulic fracturing stage was carried out by installing frac jumpers, then perforating, hydraulic fracturing and isolating by installing the next phase frac fracturing with offset fracturing initiation points, and the location of fracturing initiation points is determined so that the cracks on one wellbore are oriented in the intermediate zone of another wellbore. 2. The method according to claim 1, characterized in that the points of initiation of hydraulic fractures on adjacent horizontal trunks are offset relative to each other by half the length of hydraulic fracturing intervals.

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