RU2649195C1 - Method of determining hydraulic fracture parameters - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to oil production and can be used in hydraulic fracturing of a formation while simultaneously monitoring geometric and hydrodynamic fracture parameters in real time. Method includes measuring distributed temperature and pressure in a well, and then calculating the geometrical parameters of the fracture based thereon. In addition, mechanical deformations of the well casing string are simultaneously measured with strain gauges placed on the outer surface of the well casing string in a predetermined order within the perforation interval, and seismic events are monitored by means of receivers placed above and below the perforation interval. Due to the real-time concurrent monitoring of the distributed physical parameters of the well and seismic events around it, the disclosed method enables to determine the azimuth, length, crack opening width, height (opening interval) of the crack in real time when applying a hydrodynamic action on a permeable reservoir, which, in combination with a geomechanical model of crack development, allows to optimally specify injection modes in order to achieve the target fracture parameters.

EFFECT: technical result consists in ensuring the possibility of determining with high accuracy geometric fracture parameters, specifically the azimuth, length, average opening width, height (opening interval) directly in the hydraulic fracturing process.

7 cl, 2 dwg

Description

The claimed invention relates to oil production, and in particular to the field of work to stimulate flow in an oil and gas well using hydraulic fracturing while monitoring the geometrical and hydrodynamic parameters of the fracture in real time.

Hydraulic fracturing is an effective way to intensify the influx of oil and gas wells, however, geological factors impose certain restrictions on the ultimate efficiency of the fracture, upon reaching which it is necessary to stop the injection and stop the growth of the fracture. These factors include:

- the predominant crack growth is not horizontal within the target horizon, but vertical, which is especially dangerous by joining adjacent aquifers or a breakthrough to fluid contacts;

- achievement of maximum hydraulic efficiency, after which further growth of the fracture will not lead to increased well productivity, however, it will be associated with the consumption of reagents.

Since detailed modeling of crack growth is complicated by uncertainties in the geological structure of the medium and knowledge of its physical characteristics, a hydraulic fracturing method is necessary in which, simultaneously with the injection of regents, the geometric parameters of the crack, such as propagation azimuth, length, height, and opening width, are monitored.

Known methods for controlling the hydraulic fracturing process (see patents RU: No. 2319177, IPC G01V1 / 00, published March 10, 2008; 2461026, IPC E21B47 / 14, published September 10, 2012; 2550770, IPC E21B47 / 14, published May 10, 2005 .2015; 2507396, IPC E21B47 / 14, published February 20, 2014; 2455665, IPC E21B47 / 14, published July 10, 2012), which are based on recording and interpretation of seismic events both before and during the process, and after hydraulic fracturing, the coordinates of the sources of seismic vibrations are calculated, the spatial zones of microseismic activity are identified, the size and direction of development are determined overhnostey fracture and provide control of the fracturing process.

These methods allow you to visualize a hydraulic fracture by seismic events, confined mainly to the tip of the fracture, where seismic activity is most intense, which allows you to determine the length of the fracture and the azimuth of propagation. However, the method practically does not provide information about either the height or the width of the opening of the fracture.

In addition, the method imposes restrictions on the terrain, because it requires area survey on the day surface, and also on the degree of dissection of the geological formation (with strong dissection, the acoustic picture is eroded). Real-time application in the process of hydraulic fracturing is limited by the speed of processing seismic information, and, as a rule, is not achievable in practice.

A known method of controlling the development of a hydraulic fracture and its geometry (see patent No. RU 2374438, IPC E21B43 / 26, published November 27, 2009), including injecting a conductive hydraulic fracturing fluid into the wellbore and measuring the parameters of the electromagnetic field and / or acoustic signals resulting from the application of voltage pulses to the fracturing fluid, and determine the coordinates of the tip of the crack.

This method allows you to observe the propagation of a fracture during hydraulic fracturing by changing the location of the tip of the fracture, thereby fixing the length and azimuth of the propagation of the fracture, but it does not allow one to judge either the height or the width of the fracture opening. The advantage is the absence of restrictions on the terrain, and the fragmentation of the geological formation. The disadvantage of this method is the requirement for the contrast of electrical resistance between the fluid and the rocks of the target horizon, which is problematic in low-impedance reservoirs, and imposes serious restrictions on the composition of the fluids, as well as the need for electrical isolation of the downhole equipment for measurements.

A known method of monitoring the geometrical and hydrodynamic parameters of hydraulic fracturing (see patent No. RU 2390805, IPC G01V5 / 12, published 05/27/2010), including surface radon imaging, measurement of gamma activity, radon indicator studies, to obtain such hydrodynamic characteristics of the formation , such as permeability and injectivity profile, measure gamma activity, carry out hydraulic fracturing, repeat radon survey, radon indicator studies, measure gamma activity, the obtained data is compared and establish the azimuthal location of the fractures, as well as the permeability and injectivity profile of the formation.

This method allows you to observe only the azimuthal propagation of the fracture and does not allow to judge about other parameters, such as height, length and width of the opening. The method does not impose any restrictions on the fragmentation of the geological formation, however, since it is associated with the conduct of areal surveying on the day surface, this imposes restrictions on the terrain. In addition, the method is based on comparing surveys before and after hydraulic fracturing, and therefore is not suitable for real-time observation during hydraulic fracturing.

A known method for determining the size of hydraulic fractures (see patent No. RU 2324810, IPC E21B43 / 26, published May 20, 2008), in which a numerical model of displacing hydraulic fracturing fluid from a fracture and from a filtrate zone with a formation fluid is preliminarily created in order to calculate the content change fracturing fluids in the total production during commissioning after hydraulic fracturing, and then compare the measurement results with model calculations and determine the length of the fracture based on ensuring the best match of the measurement results model calculations.

This method allows you to determine only the length of the fracture, and does not allow to judge about other parameters, such as height, opening width and propagation azimuth separately. The advantages of the method are the ability to work with any type of terrain and any fragmentation of the geological formation. However, the method does not provide real-time information during hydraulic fracturing, as it is based on observations of the well after hydraulic fracturing.

Closest to the claimed one is a prototype method for monitoring the distributed geological and technological parameters of oil and gas wells (see: Ryazantsev A.E., Cheremisin A.N., Toropetskiy K.V., Downhole monitoring in the concept of a “smart” well, Vestnik TsKR Rosnedra. 2014. No. 1, pp. 2-6), including measuring its physical characteristics using geophysical instruments lowered into the well and calculating the geological and technological parameters of the well from them, moreover, measurements are made in real time in locally selected points and / or along selected sections of the well to measure the physical characteristics of the well. In this case, the temperature of the fluid and / or the flow rate of the fluid, and / or the pressure of the fluid, and / or the characteristics of the acoustic noise of the well, and / or the composition of the fluid are selected as the physical characteristics of the well.

The disadvantages of this method include the impossibility of determining the azimuth of the fracture in real time from the beginning of formation, as well as the low accuracy of determining the geometric parameters of the hydraulic fracture.

The objective of the present invention is to improve the accuracy of determining the geometric parameters of the cracks in the on-line mode.

The technical result of the invention is the ability to determine with high accuracy a greater number of geometrical parameters of the fracture, namely the azimuth, length, average width of the opening, height (opening interval) directly in the hydraulic fracturing process.

The technical result is achieved by the fact that in the method for determining the parameters of a hydraulic fracture in a well, including measuring the distributed temperature and pressure in the well, followed by calculating the geometric parameters of the well, they also simultaneously measure the mechanical deformation of the casing of the well using strain gauges placed on the outer surface well casing in a predetermined order within the perforation interval, and monitoring of seismic events through TV receivers located above and below the perforation interval.

As a given order of placement of strain gauges of transverse microdeformations, their azimuthal distribution with a given step in several consecutive sections within the perforation interval is possible.

As a given order of placement of strain gauges of longitudinal microstrains, their azimuthal distribution with a given step in several consecutive sections within the perforation interval is possible.

As a given order of placement of strain gauges of the main radii of surface curvature, their azimuthal distribution with a given step in several consecutive sections within the perforation interval is possible.

As a predetermined order of placement of strain gages of distances from the casing to the walls of the well, their azimuthal distribution with a given step in several consecutive sections within the perforation interval is possible.

As a given order of placement of all types of strain gauges, their azimuthal distribution is possible with a given step with a shift in a spiral relative to the central axis of the well within the perforation interval.

As a given arrangement of geophones, their azimuthal distribution is possible with a given step in several consecutive sections above and below the perforation interval.

The invention is illustrated by drawings, in which Fig. 1 is a schematic diagram of a borehole monitoring system for fracture parameters of hydraulic fracturing (Fracturing), with which it is possible to implement the inventive method, in Fig. 2 is a diagram of a possible arrangement of sensors in such a system.

The downhole monitoring system comprises a well 1, a casing 2 installed therein, couplings 3 with strain sensors 4, an ADC 5, data transmission units 6 and power units 7, an annular cement screed 8, perforation 9 of the barrel, temperature and pressure sensors 10, geophones 11.

Determination of the parameters of hydraulic fracturing in the well is carried out in the following order.

First, work is carried out to prepare the well for measurements. To do this, lower the casing 2 into the drilled well 1 with temperature and pressure sensors 10 located in it, as well as with couplings 3 with strain gauges 4, ADC 5, data transmission and autonomous power supply units 6 and 7, pre-installed on its outer surface in the specified order , respectively, and the geophones 11. The space between the rock and the casing 2 is poured with cement to form a screed 8. Perforation 9 of the casing 2 is perforated through the casing (through the casing and cement stone).

Then, fluid begins to be pumped into the well 1 under pressure and simultaneously in the on-line mode, read the readings from the sensors 10 (temperature, pressure at various points inside the well 1), mechanical deformations of the casing 2 and / or near-well space from the strain gauges 4 and seismic waves in the borehole region from the geophones 11. The registration of readings from sensors 10, 4 and 11 is converted by the ADC 5 and through the data transmission units 6 it enters the processing complex all the time until the hydraulic fracturing of the near-borehole space (opening of the hydraulic fracture) and further until the geometrical dimensions of the hydraulic fracturing are stabilized. Moreover, the presence of blocks 7 of independent power provides the ability to work submersible elements of the system without connecting them to external sources.

The proposed system of borehole monitoring of hydraulic fracture parameters suggests the development of a special device made in the form of a sub pipe placed in the upper part of the liner during its assembly and lowering into the well. Important functions of the device are the collection, processing and storage of information from a system of sensors located on the surface of the shank along its entire length, providing autonomous power to the entire system. Information is transmitted to the surface using a communication channel based on modulation of the length of the grounding electrode and the supply of quasi-constant current to the circuit from the surface.

It is proposed to use overhead devices for measuring mechanical stresses on the surface of the liner pipe, temperature and pressure in the annulus as a measuring system of low information content. According to our research, this information is sufficient to determine the geometrical characteristics of the fracture in the vicinity of the well. This is the vertical propagation of the crack, the azimuth of its plane and the amplitude of the opening.

These parameters can be transmitted to the surface in almost real time during hydraulic fracturing and can be used in the process of hydraulic fracturing to adjust the process.

It is proposed to use devices for recording microseismic events based on three-component accelerometers located along the liner pipe on its outer surface above and below the perforation interval as an important information component for determining the length of a hydraulic fracture.

Microseismic mapping is based on recording microseismic events that occur in the near-wellbore space directly during the growth of a hydraulic fracture, when stress redistributions occur in the medium with the release of elastic energy in the form of elastic medium vibrations.

The complex of three-component seismic receivers is located at a depth near the hydraulic fracture, allows you to register longitudinal (primary or P-waves) and transverse (secondary or S-waves) waves and calculate the location of the seismic event. The position of each individual microseismic event is determined by the time of arrival of the longitudinal and transverse waves (which allows you to determine the distance and absolute elevation), as well as the movement of particles in the longitudinal wave (the azimuth and absolute elevation of the seismic event relative to the seismic receiver complex are determined). In order to use information on particle motion, it is necessary to determine the orientation of the receiver, which is usually achieved by monitoring explosions during perforation of wells or other seismic sources in a given or neighboring well, i.e. calibrate the velocity model of the medium.

For microseismic mapping, we used microelectromechanical (MEMS) digital accelerometers with a 24-bit output with sampling no worse than 0.25 ms, which makes it possible to record acoustic signals in the frequency range 0–2000 Hz with a dynamic range of 150 dB. For the continuity of signal tracking, the arrangement step of the seismic receivers should not exceed several wavelengths, at a frequency of 2000 Hz and a speed of 3000 m / s this is 3-5 m. To ensure the necessary accuracy of determining the removal of the source at an unknown signal excitation time, an aperture is required, 2 times exceeding source removal, i.e. not less than 200 m

An autonomous power supply unit is necessary in case of a power failure from the surface, at this point very valuable data can be obtained and recorded. Currently, there are high-temperature Li-SoCl2 batteries with an operating temperature of up to 150/165/200 ° C and a capacity of up to 800/70/15 Wh, respectively (for example, EEMB Battery or Saft). At temperatures up to 120 ° C NiMh batteries with typical capacities up to 100 Wh are suitable. There are high-temperature EEPROM microcircuits with a capacity of 32 Mbit and an operating temperature of up to 210 ° C (for example, TI SM28VLT32-HT with an SPI interface), or 64 Mbit with an operating temperature up to 150 ° C.

The well is equipped with a measuring system at the stage of well construction. Placement of sensors and electronics in the annular space between the liner and the well wall, which is filled with cement.

During hydraulic fracturing, data (temperature, pressure, microdeformations, seismic events) through an armored cable are sent to the data acquisition and transmission module and transmitted to the surface in real time, where they are processed using special software and displayed on the screen in the form of traffic. By analyzing the graphs (or using a special software package), we can obtain the vertical propagation of the crack, the azimuth of its plane and the maximum opening.

Due to real-time parallel monitoring of the distributed physical parameters of the well and seismic events around it, the claimed method allows to determine the azimuth, length, width of the crack opening, height (opening interval) of the crack in real time when performing hydrodynamic effects on the permeable reservoir, which, in total with a geomechanical model of the development of the fracture, it makes it possible to optimally specify the injection regimes in order to achieve the target parameters of the hydraulic fracture.

Claims (7)

1. A method for determining fracture parameters of a hydraulic fracturing, including measuring the distributed temperature and pressure in the well and calculating geometrical parameters of the fracture, characterized in that it additionally simultaneously measures the mechanical deformation of the well casing using strain gauges placed on the outer surface of the well casing in a given order within the perforation interval, and monitoring of seismic events by means of receivers located above and below the interval la perforation. 2. The method according to claim 1, characterized in that the azimuthal distribution with a given step in several consecutive sections within the perforation interval is used as a given order of placement of transverse microstrains strain gauges. 3. The method according to claim 1, characterized in that the azimuthal distribution with a given step in several consecutive sections within the perforation interval is used as a predetermined order of placement of strain gauges of longitudinal microstrains. 4. The method according to claim 1, characterized in that the azimuthal distribution with a given surface pitch in several consecutive sections within the perforation interval is used as a given order of placement of load cells of principal radii of curvature. 5. The method according to claim 1, characterized in that the azimuthal distribution with a given step in several consecutive sections within the perforation interval is used as a predetermined order of placement of strain gages of distances from the casing to the walls of the well. 6. The method according to claim 1, characterized in that the azimuthal distribution with a given step with a spiral offset relative to the central axis of the well within the perforation interval is used as a predetermined placement order for all types of strain gauges. 7. The method according to claims 1-6, characterized in that as a predetermined order of placement of the geophones use their azimuth distribution with a given step in several consecutive sections above and below the perforation interval.

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