RU2279695C1 - Method of prospecting of carbon methane - Google Patents

Abstract

FIELD: geophysics; prospecting.

SUBSTANCE: described method has to be combination of two and more methods and techniques which can be used for exploration and prospecting of carbon beds as non-traditional collectors of absorbed methane and for revealing of free gas accumulation in carbon opencast collieries for production of carbon methane. Method intends for study and preparation of methane-carbon deposits for exploration and includes field works, registration, subsequent combined processing and geological interpretation of data of multi-wave seismic prospecting by means of common depth point method, three-component vertical seismic profiling and geophysical inspection of wells. Data of multi-wave seismic prospecting are registered by means of common depth point method simultaneously onto on-ground azimuth profiles passing the well and directly inside the well in at least one point which is chosen inside zone of dislocation of metal-carbon collectors.

EFFECT: improved truth of results.

Description

The invention relates to geophysics, exploration or discovery using combined methods, which are a combination of two or more methods, and can be used in the study and exploration of coal seams as unconventional reservoirs of sorbed methane and the detection of free accumulations of gas in a coal-bearing section in order to produce coal methane. The proposed method for the exploration of coal methane is designed to study and prepare methane-coal deposits for development and includes a set of geophysical methods: multi-wave seismic exploration using the common deep point method with recording data simultaneously on ground azimuth profiles passing through the borehole and directly in the borehole, three-component vertical seismic profiling and geophysical well research.

At present, Russia does not have complex geophysical technologies for prospecting unconventional sorbed methane reservoirs and detecting free gas accumulations in the coal-bearing section for the purpose of producing coal methane.

In domestic coal exploration, the methods of geophysical research of wells [1] and seismic exploration [2], which are used in coal deposits, are known. Materials of geophysical research of wells are used to isolate coal seams in sections of coal exploration wells, determine their thickness, depth, a complete set of petrophysical characteristics, as well as to correlate well sections and identify discontinuous faults [1]. The aim of seismic exploration is to detail the hypsometry of the coal seams to be developed, as well as to identify and track the area of tectonic disturbances that complicate the structural plan of the target horizons [2].

However, these technologies [1, 2], necessary for the correct calculation of coal reserves and the subsequent design of mines, do not provide solutions for predicting areas of high sorbed methane content in coal seams and are not aimed at identifying free gas accumulations within the studied areas.

A known method for predicting the gas content of coal seams according to geological and geophysical studies of coal exploration wells [3]. It is based on the creation of a lithological and genetic model of gas content in coal seams, implemented using the mathematical apparatus of non-linear Markov statistics. The forecast of gas content in coal seams, made in separate areas in the Donbass, Yakutia and Kuzbass, made it possible to choose the right means of combating methane occurrences and increase the safety of mining in mines.

A significant drawback of the practiced method [3] is the fragmentation of the source geological materials due to the incomplete output of the coal core when drilling coal exploration wells. In the framework of the proposed technical solution, the issue of targeted production of methane sorbed in coal seams is not considered, although it is mentioned that it can be extracted as an independent mineral in the creation of coal mines.

Closest to the proposed technical solution, i.e. its prototype is the geophysical technologies developed in recent years in the USA [4] where the coal methane production areas coincide with the traditional coal seam mining areas, and the geological studies of which were performed only for the upper part of the section to a depth of 500 m. In connection with This significantly increases the role of seismic exploration as a means of exploring methane-coal deposits to a great depth, designing object-oriented exploration coal-methane wells and choosing the optimal location of coal-metal s wells. It is shown that to solve these problems, field work, registration, subsequent joint processing and geological interpretation of ground multiwave seismic data using the common depth point method, three-component vertical seismic profiling and well logging are necessary. When considering various issues of joint processing and geological interpretation of data, the possibilities of the AVO analysis procedure by seismograms for the identification of porous and fractured zones are investigated. When analyzing seismic materials from the positions of polarization of longitudinal and transverse waves, zones of increased anisotropy are identified, which are associated with the presence of a certain system of fracturing and cleavage, which allows predicting zones of increased sorbed methane content in coal seams. Among other results of the interpretation of geophysical materials, the most important are maps of seismic attributes (attenuation and Poisson's ratios, Young's modulus, gamma parameter equal to the ratio of the velocities of transverse and longitudinal seismic waves), which have a correlation with gas saturation and allow detecting free gas accumulations in the coal-bearing section.

The main disadvantage of the prototype [4] is that when conducting multi-wave ground seismic surveying using the common deep point method in areas with a low-velocity zone extending from the surface to a depth of several tens of meters, the initial seismic wave field recorded on the surface is characterized by the presence of interference waves, unsatisfactory signal-to-noise ratio, irregular nature of tracking the travel time curves of reflected waves.

The difference of the proposed method for coal methane exploration from the prototype [4] is that the registration of multiwave seismic data using the common deep point method is performed simultaneously on ground azimuthal profiles passing through the well, and directly in the well, at least at one point that is selected in the zone of location of methane-bearing coal reservoirs.

Multiwave seismic exploration using the common deep point method with simultaneous recording of data on ground azimuth profiles passing through the borehole and directly in the borehole, performed at the Kuzbass test site, where the thickness of loose sediment varies from 5 to 40 m, showed that the initial seismic recorded on the surface the wave field is characterized by the presence of intense low-frequency interference waves associated with a surface wave that forms in the zone of low speeds - in loose sediments hne part of the cut. Due to the screening of the energy of seismic vibrations at the interface between high contrast medium sediments and consolidated bedrock, the intensity of reflected seismic waves sharply decreases when they are recorded on the surface by ground-based receivers, the signal-to-noise ratio decreases, and the travel time curves of the reflected waves are intermittently observed.

When seismic information is received by a borehole probe directly in the borehole, at one or several points, the quality of the recorded field of reflected waves improves significantly: there are no surface interference waves, the signal-to-noise ratio increases, and the travel time curves of the reflected waves are observed almost continuously. The level (depth) at which the three-component receiving device is installed in the well is selected based on the depth of the selected coal seam or group of reservoirs of sorbed methane in order to form the optimal arrival geometry of the reflected seismic waves. So, when conducting seismic surveys aimed at studying a powerful coal seam lying at a depth of 500 m, for optimal reception of reflected waves in the well, the receiving device was located at a depth of 300 m.

Another disadvantage of the prototype [4] is that it does not provide a holistic picture of how coal methane exploration can be realized by a geophysical complex, and suggests predicting zones of high sorbed methane content in coal seams only on the basis of polarization analysis of longitudinal and transverse seismic waves, although other prediction methods based on seismic data can be applied.

The objective of the proposed technical solution is the implementation of a method for the exploration of coal methane using a complex of geophysical methods.

The problem is solved as follows. In the method of exploration of coal methane, which consists in conducting field work, recording, subsequent joint processing and geological interpretation of multiwave seismic data using the common deep point method, three-component vertical seismic profiling and geophysical well surveys, multiwave seismic data are recorded using the common deep point method simultaneously at ground azimuth profiles passing through the well, and directly in the well, at least about bottom point, which is chosen in the zone of the location of methane-bearing coal reservoirs.

The method is carried out in stages.

The first stage involves the sequential implementation of field work.

Carry out geophysical studies of the coal-methane well, including broadband acoustic logging, and three-component vertical seismic profiling.

A multiwave seismic survey is carried out using the common deep point method with data being recorded simultaneously on ground azimuthal profiles passing through the borehole and directly in the borehole, at least at one point that is selected in the zone where methane-bearing coal reservoirs are located. A feature of the technology is the observation of the wave field directly in the well, which provides registration of the full volume of seismic information at internal points of the medium, free from the influence of the low-velocity zone and including waves of various types — longitudinal, exchange and transverse. The number of points - observation levels is determined by the number of investigated coal seams - collectors of sorbed methane. The latter allows using seismic data both at the point of the well and in the near-borehole space to obtain the distribution of elastic parameters and link them with the data of geophysical studies of the well and three-component vertical seismic profiling. Simultaneously with the registration of information in the well at a fixed point of excitation of seismic waves, vibrations are received on the surface through a network of azimuthally oriented seismic profiles. The presence of data from the common depth point method over the surface makes it possible to refine the continuous geometry of coal seams and to localize areas of tectonic disturbances and fracture zones. Based on the ground-based and multilevel observations in the well, both the general structural plan and individual structural details of the studied area of the methane-coal field are specified.

The second stage includes the joint processing and geological interpretation of multiwave seismic data using the common depth point method, three-component vertical seismic profiling and well logging. Successively perform the following sub-steps.

1. Construction of geological and geophysical models of promising areas of methane-coal deposits in order to prepare them for the extraction of methane from coal seams.

2. AVO analysis by seismograms to identify porous and fractured zones.

3. Construction of maps of seismic attributes (attenuation and Poisson ratios, Young's modulus, shear and bulk elasticity, as well as the gamma parameter equal to the ratio of the shear and longitudinal seismic wave velocities) for the target groups of coal seams and some of the most powerful coal seams.

4. Construction of maps of parametric geofields (statistical and gradient characteristics) for the target groups of coal seams and some of the most powerful coal seams. Statistical characteristics - average values of instantaneous amplitudes, phases, frequencies, etc., are calculated in a sliding window, the size of which is determined by the interpreter within the target interval of the coal-bearing section based on the available a priori information. The dispersion of the field of instantaneous amplitudes, phases, and frequencies makes it possible to single out regions characterized by increased heterogeneity. Gradient characteristics - horizontal, vertical and full gradients of the wave field, as well as the direction of the full gradient, are used to increase the resolution of the recording at the stage of highlighting subtle features of the field structure. Gradient characteristics emphasize the details of the structure of the medium due to tectonic dislocations.

5. Prediction of zones of high sorbed methane content in coal seams using a complex of seismic attributes (attenuation and Poisson's coefficients, Young's modulus, shear and bulk elasticity, as well as the gamma parameter, equal to the ratio of transverse and longitudinal seismic wave velocities) and parametric geofields (statistical and gradient characteristics).

6. Detection of free gas accumulations within the studied areas based on AVO analysis, according to a set of seismic attributes (attenuation and Poisson's ratios, Young's modulus, gamma parameter equal to the ratio of transverse and longitudinal seismic wave velocities) and parametric geofields (statistical and gradient characteristics) .

7. Submission of materials for the calculation of coal methane reserves.

8. Designing object-oriented exploration coal-carbon wells and choosing the optimal location of carbon-methane wells within the studied areas of methane-coal deposits.

9. Submission of recommendations on the methane extraction technology sorbed in coal seams or in the form of free clusters at a preselected location of a coal-methane well or wellbore and the drilling direction — vertical, directional, horizontal.

The implementation of the claimed invention is planned with the continuation of work at a research site in Kuzbass, as part of a project to study the possibility of methane extraction from coal seams. Such a project is being implemented in Russia for the first time and has high sociopolitical and economic importance, especially for regions experiencing a shortage of natural gas supplies or not yet covered by gasification.

Information sources

1. Grechukhin V.V. and others. Geophysical methods for studying the geology of coal deposits. M .: Nedra, 1995 .-- 477 p.

2. Kozelsky I.T. and others. The geological conclusion on the results of ground-based seismic exploration in the field of mine No. 7 of the Sokolinsky deposit in the Kuznetsk basin. Narofominsk: NPP Zemlya, NPP Uglegeotehnologiya, 1995. - 22 p.

3. Chernikov A.G. and other recommendations for predicting the gas content of coal seams in a complex of geological and geophysical studies of coal exploration wells. M .: GEON, 2000 .-- 62 p.

4. Ramos A.C., Davis T.L. Case History. 3-D AVO analysis and modeling applied to fracture detection in coalbed methane reservoirs. GEOPHYSICS. VOL 62, N6, 1997, p. 1683-1695.

Claims (1)

The method of coal methane exploration, which consists in field work, registration, subsequent joint processing and geological interpretation of multiwave seismic data using the common deep point method, three-component vertical seismic profiling and geophysical well surveys, characterized in that the multi-wavelength seismic data are recorded by the common deep point method on ground azimuth profiles passing through the well, and directly in the well at least one point that is selected in the area of the methane-bearing coal reservoirs.