RU2602735C2 - Method for seismic monitoring of process of development of hydrocarbons in water areas - Google Patents

Abstract

FIELD: geophysics.

SUBSTANCE: invention relates to geophysics and can be used to specify the structure of a deposit of hydrocarbons in water areas and increase the efficiency of its development. Proposed is a method for seismic monitoring of the process of development of a hydrocarbons deposits in water areas including three-dimensional seismic survey and building on its data a model of the reservoir, predicting orientation of subvertical cracks systems and designing arrangement of operational and injection wells, as well as arrangement at the bottom of the water area over the deposit of stationary seismic streamers, recording seismic traces with elastic vibrations from artificial sources and monitoring the process of development of the hydrocarbons deposit by dynamic and kinematic changes in the detected vibrations when processing the seismic traces. Before drilling of the projected horizontal section of the well arranged is a mobile seismic streamers liner on the bottom following a radial different-azimuth observation system on the object of survey with a center located above the horizontal section of the well. During drilling microseismic vibrations are recorded excited by the bit at the bottom hole, when processing which by dynamic and kinematic characteristics determined are anisotropic properties of the medium in the zone of drilling, specified is orientation of subvertical cracks systems and corrected are three-dimensional models of the reservoir. After completion of the well drilling the liner of seismic streamers is dismantled and moved to a new object of analysis. Herewith during the hydraulic fracturing microseismic vibrations are recorded, determined are three-dimensional coordinates of their sources and also refined is the three-dimensional model of the reservoir and orientation of the cracks systems.

EFFECT: technical result is the increase of efficiency of hydrocarbons development in water areas at drilling horizontal wells.

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Description

The invention relates to the field of geophysics and can be used to clarify the structure of a hydrocarbon field in the waters and increase the efficiency of the process of its development.

A known method of seismic monitoring of the process of developing a hydrocarbon field in water areas (prototype), including three-dimensional seismic exploration and building a reservoir model based on it, predicting the orientation of subvertical fracture systems and designing the location of production and injection wells, placing stationary seismic streamers at the bottom of the water area, registering seismic surveys with elastic vibrations from artificial sources and control of the development of the coal field hydrodynamics on dynamic and kinematic changes in recorded oscillations during seismic processing (Smit F., Ligtendag M., Wills P., Calvert R. Towards Affordable Permanent Seismic Reservoir Monitoring Using the Sparse OBC Concept. Exploration and production: the oil and gas review, 2006 , p. 56-62).

It is known that the efficiency of developing oil and gas fields, especially hard-to-recover reserves from low-permeability reservoirs, depends on the accuracy and detail of three-dimensional constructions of geological, hydrogeological and geomechanical models of the medium (field). In the construction of the latter, the orientation of subvertical fractures along which accelerated fluid movement occurs during the life of the fields and their development is especially important. The most reliable and accurate models of the environment are built according to the data of three-dimensional seismic (3D), the results of geophysical studies of exploration wells and petrophysical core analysis.

In modern exploration and development of oil and gas fields in the waters, 3D seismic is widely used at the stage before drilling exploratory wells or after drilling the first successful well (the latter was often practiced in Russia). In the vast majority of cases, 3D seismic exploration is carried out by exciting elastic oscillations by groups of pneumatic sources and registering them with several (theoretically up to 24, and in fact the record set by PGS companies - 17) multichannel receiving seismic devices (seismic streamers) continuously moving in the water column along with the vessel ( Ampilov Yu.P., Baturin DG The latest 4D seismic monitoring technologies in the development of offshore oil and gas fields. Seismic exploration technologies, No. 2, 2013, P. 31-36).

However, even wide (up to 1,500 m) seismic streak spacings do not allow for full-fledged migration transformations and to study the anisotropic environmental properties due to the flawed narrow-azimuth observation system implemented using the traditional single-vessel 3D seismic exploration, and the use of multi-azimuthal or multi-vessel 3D seismic exploration significantly increases the cost of research. In addition, the use of 3D seismic surveying with floating streamers complicates future seismic monitoring (4D seismic exploration) and does not allow seismic monitoring of the well drilling process.

The various drawbacks of 3D seismic surveys with floating seismic strips are deprived of various modifications of OBC (Ocean Bottom Cable) technology with seismic streamers at the bottom. The spatial observation system of the OVS technology is almost similar to the full-azimuthal 3D seismic survey carried out on land, which allows to obtain the highest quality results. The classical technology of 4D seismic surveys involves the complex processing of old (preferably before the start of field development) and new 3D data obtained using the same observation systems with the most approximate parameters of excitation and registration of oscillations. The best result is obtained when implementing seismic monitoring with seismic streamers installed for the entire field development period (PRSM - Permanent Seismic Reservoir Monitoring), and transmit the recorded oscillations, excited from the incoming vessel periodically (from three months to two years), via cables to the nearest platform or over the air to a data collection and processing center. Such equipment was installed and successfully used abroad at a number of fields, including the Norwegian Valhall in the North Sea (since 2003 - the first in the world). However, in most cases, it was installed after the development of the field began, in particular, after 21 years at the Valhall field (BP) in the North Sea, when a significant part of the hydrocarbons has already been extracted and the information obtained from 4D seismic surveys can only affect the placement and drilling of new production (including water and gas injection wells (Smit F., Ligtendag M., Wills P., Calvert R. Towards Affordable Permanent Seismic Reservoir Monitoring Using the Sparse OBC Concept. Exploration and production: the oil and gas review, 2006, p. 56-62).

The technology with the placement of seismic streamers at the bottom of the water area before the start of drilling production wells can contribute to improving the efficiency of field development. In this case, it becomes possible to register microseismic vibrations excited by a bit at the bottom of the well during drilling, and when processing the recorded elastic vibrations (seismic wave fields), a number of important tasks are solved, including refining the three-dimensional model of the reservoir and the orientation of the fracture systems, choosing the optimal location for perforation and hydraulic fracturing formation (hydraulic fracturing), control of hydraulic fracturing, etc.

For example, when carrying out work at the Shtokman gas condensate field in the Barents Sea, the gas area of which is 1600 sq. Km. km, it would be necessary to place bottom seismic streamers in an almost square section of not less than 45 × 45 km (an area of 2025 sq. km). Even with a large distance between seismic streamers of 1 km, about 1800-2000 km of seismic streamers will be required, which is 15-17 times more than was placed in 2003 at the Valhall field (120 km). In addition, to solve seismic monitoring tasks during drilling, a much denser network of observations is required, located at a small distance from the well, which is associated with a strong attenuation of microseisms with increasing distance from the source of oscillations.

The disadvantage of this method is the installation of a large number of seismicos.

The technical result of the present invention is to increase the efficiency of the process of developing a hydrocarbon field in the water when drilling horizontal wells.

The technical result is achieved due to the fact that in the method of seismic monitoring of the process of developing a hydrocarbon field in water areas, including three-dimensional seismic exploration and construction of a reservoir model based on it, predicting the orientation of subvertical fracture systems and designing the location of production and injection wells, placement at the bottom of the water area above the field stationary seismic streamers, registration of seismic traces with elastic vibrations from artificial sources and control of percent The development of hydrocarbon deposits according to the dynamic and kinematic changes in the recorded oscillations during seismic processing, before drilling the projected horizontal section of the well, place a mobile arrangement of seismic skids at the bottom using a radial multi-azimuth observation system at the research object with a center located above the horizontal section of the well, microseismic are recorded during drilling oscillations excited by the bit at the bottom of the well, the processing of which is dynamic Kim and kinematic characteristics determine the properties of anisotropic medium in the drilling zone, specify the orientation of sub-vertical fracture systems and corrected three-dimensional reservoir model, and after completion of drilling alignment streamer disassemble and move to a new research facility. In addition, during hydraulic fracturing, microseismic vibrations are recorded, three-dimensional coordinates of their sources are determined, and a three-dimensional reservoir model and the orientation of the fracture systems are further refined.

The essence of the method is illustrated in the drawing. The drawing shows: 1 - the water column, 2 - the oil and gas reservoir, 3 - the wellhead near the rig, 4 - the current position of the bottom of the horizontal section of the well, 5 - the center of the mobile radial arrangement of seismic strips, 6 - one of eight seismic strips.

The essence of the invention lies in the fact that they implement seismic monitoring of the process of developing a hydrocarbon field in the waters at the initial stage in the process of drilling production wells with a horizontal section inside the field (reservoir). This allows you to obtain detailed information about spatial changes in the anisotropic properties of the environment of the field being developed with a forecast of the orientation of the main systems of subvertical fractures to refine three-dimensional hydrogeological and geomechanical models of the field, to optimize the placement of vertical, inclined and horizontal wells of production wells and the directions of opening of the layers during their perforation, as well as the choice places of hydraulic fracturing and the quality of its conduct. The technology involves the installation of radially oriented seismic streamers on the bottom of the mobile array before the start of drilling production wells, with the center of the radial arrangement being located above the horizontal section of the well. The number of lines and points of reception of elastic vibrations is set taking into account economic considerations, but the number of lines should be at least four, forming a cross-observation system, in which two lines are located in the direction of the main extrema of the indicatrixes (azimuthal dependencies) of the kinematic and dynamic characteristics of the propagation of elastic vibrations defined as a result of preliminary 3D seismic data and geophysical surveys in exploratory wells.

In Arctic conditions, ice cover exists almost everywhere from 7 to 10 months, and before climate warming it is often up to 12 months (for example, in the Kara Sea). Therefore, the operational installation and dismantling of a mobile bottom seismic arrangement from a ship is practically impossible. However, these operations may well be carried out from inhabited or uninhabited vehicles launched from an icebreaking vessel or from a drilling platform and carrying a series of compact winches. As the most optimal underwater carrier for a seismicos, robotic underwater uninhabited vehicles ROV (Remotely Operated Vehicles) manufactured abroad and at the FSUE OKB OT RAS can be used. In particular, the ROVs were adapted by the Norwegian company SeaBird Exploration in the CASE System for arranging autonomous bottom seismic recorders (Nodes) that carry 6 ROVs in one removable cassette. At the same time, up to 1200 bottom seismic recorders were placed in real conditions. Obviously, instead of heavy seismic recorders, compact winches with bottom seismic streamers can be installed, which should be as light as possible and of a minimum diameter. Such braids have already been developed and are being manufactured at AKIN OJSC (Acoustic Institute named after Academician NN Andreev). Their diameter along the carrier cable is 12 mm, the diameter of the hydrophone is 22 cm, and the weight in air is about 100 kg for 500 m of braids (and in water about 30 kg).

Seismic strips periodically record elastic vibrations (seismic wave fields) that occur during rock destruction during the drilling of horizontal sections of the trunks of the first and subsequent wells in the reservoir reservoir (microseisms). During processing, the amplitude-frequency spectra (ASF) and other dynamic characteristics of the recorded wave fields are calculated, the ASF of seismic channels are selected that are equidistant from the projection point of the current bottom of the well to the bottom, for the frequencies of the maximum ASF amplitudes, the indicatrixes of the amplitudes of the fixed frequencies of ASF are constructed, with the interpretation of which Based on the identification of extrema, the orientation of the main systems of subvertical cracks is determined (Epiphany V.I., Urupov A.K., Budagova T.A., Dobrynin S.V. Anisotropic properties sedimentary cover of the continental shelf. Gas industry, No. 7, 1997, S. 16-18).

The possibility of obtaining seismic records of wave fields excited by a bit suitable for studying the anisotropic properties of the medium was proved in (Blank AM, Urupov AK, Zhukov AM Possibility of monitoring natural-technogenic processes in the geological environment by seismic methods for drilling deep wells. .: “Problems of technogenic environmental change and subsoil protection in mining regions. Perm, 1991, pp. 70-71) as an example of a field experiment to study the near-wellbore space in the Skvortsovskaya-1 well on the north side of the Dnieper in the Donetsk Depression. The results of this experiment are in good agreement with the ultrasound data of core samples. The information obtained on the anisotropic properties of the medium according to the data of direct waves excited by a bit in the bottomhole zone is more accurate and correct than the reflected waves excited and recorded in the body of water or near the surface of the earth. This is due to the fact that the former pass through the system of subvertical cracks to the points of reception along one beam at one angle to the system of cracks, and the latter along two rays (incident and reflected) at two angles.

Using the described method by promptly obtaining information about the orientation of fracture systems in real-time conditions allows us to clarify the structure of a hydrocarbon field in water areas and improve the efficiency of its development by possibly correcting the orientation of horizontal wellbores, and after completing the drilling of wells, select the optimal locations for perforation and multistage fracturing based on the choice of zones with the most pronounced anisotropy of dynamic characteristics bathrooms wave fields. The correctness of determining the orientation of fracture systems and the effectiveness of each hydraulic fracturing is confirmed by processing microseisms excited during its conduct (Butula K.K., Vereshchagin S.A. Development of hard-to-recover reserves - data integration for well completion for optimal field development. Oil & Gas Journal Russia, No. 7 (73), 2013, pp. 42-43, Aleksandrov S.I., Mishin V.A., Burov D.I. et al. The use of microseismic monitoring to control the technological risks of hydraulic fracturing. Nefteservis, No. 1 (21) , 2013, p. 50-52) and recorded by bottom seismic braids of the same mobile arrangement, after which it is dismantled and moved to a new research object.

Claims (2)

 1. A method of seismic monitoring of the process of developing a hydrocarbon field in water areas, including conducting three-dimensional seismic exploration and building a reservoir model based on it, predicting the orientation of subvertical fracture systems and designing the location of production and injection wells, placing stationary seismic streamers at the bottom of the water area, recording elastic seismic surveys fluctuations from artificial sources and control of the process of developing a hydrocarbon field by dyne physical and kinematic changes in the recorded oscillations during processing of seismic surveys, characterized in that prior to the start of drilling the designed horizontal section of the well, a mobile arrangement of seismic skids is placed on the bottom along a radially different-azimuth observation system at the research object with a center located above the horizontal section of the well, microseismic vibrations are recorded during drilling excited by a bit at the bottom of the well, during the processing of which according to dynamic and kinematic characteristics sticks are determined by the anisotropic properties of the medium in the drilling zone, the orientation of the subvertical fracture systems is refined, and three-dimensional reservoir models are corrected, and after completion of the well drilling, the seismic line arrangement is dismantled and moved to a new research object. 2. The method according to p. 1, characterized in that during the fracturing process microseismic vibrations are recorded, three-dimensional coordinates of their sources are determined and an additional three-dimensional model of the reservoir and the orientation of the fracture system are specified.

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