RU45538U1 - GEOPHYSICAL COMPLEX FOR SEARCHING OIL AND GAS IN AQUATORIES - Google Patents

Abstract

Usage: means for geophysical exploration of water using combined devices, which are a combination of remote thermal and geochemical surveys. Essence: the complex contains mobile modules (PM) of geophysical exploration in combination with modules of a satellite positioning system and a stationary geographic information station for data processing. Each PM includes a measurement unit, an ADC, an accumulation and memory unit, an information recording and reproducing unit. The complex contains a set of PM remote sensing of the thermal fields of the water area and PM geochemical survey of the water area. EFFECT: provision of adequate geophysical exploration in water areas inaccessible for seismic work due to the integration of means, which provides an increase in the information content and reliability of identifying hydrocarbon deposits; reduction in the composition of the equipment compared to known devices.

Description

The technical solution relates to geophysical exploration of water using combined devices (complexes), which are a combination of two technologies: remote and geochemical surveying, and can be used in areas that are difficult to access for seismic work, for example, in shallow (up to 3 m) estuaries.

Currently, geophysical work is carried out mainly using multifunctional complexes [2, 11-13]. However, these complexes, combined with a large number of data on various geophysical fields, are difficult to use and not effective enough in such specific conditions as geophysical studies on a shallow shelf and / or in land-sea transition zones.

Specialized geophysical complexes are known that take these features into account: a marine seismic complex [10] installed on a shallow-sitting vessel with varying bow sediment; seismic exploration system [9] in extreme shallow water and in transitional zones of water-land, used on ice in winter conditions; marine geoacoustic complex [8]; technological complex [2] for shelf research.

The known complex [2] contains geophysical exploration modules, each of which includes a measurement unit connected through an ADC to a data processing and recording unit, as well as a navigation module

system, which is used as a module of the differential radio navigation system and / or module of the differential satellite radio navigation system. Geophysical complexes can be installed on ships [2, 7, 12, 13] or on aircraft [5].

However, such devices are not intended and, therefore, not effective enough for the search and detection of hydrocarbon deposits in poorly studied and difficult to access seismic waters. In such areas, alternative methods of geophysical exploration could be used, for example, the technology of gravimetric [5], electromagnetic, geochemical [4] or thermal [3] surveys, however, in some cases, they do not provide the necessary information and reliability, since they include geophysical meters parameters of only one type.

If it is impossible to conduct adequate seismic surveys of the water area, this contradiction could be resolved by a complex of two, three modules for the study of geophysical fields of various types, for example, a complex of thermal and geochemical exploration tools that are components of complex geographic information systems.

The system [1] for the study of geophysical parameters, unlike the device [2], includes means of geochemical and thermal imaging and is adopted as a prototype.

The system [1] contains geophysical exploration modules in combination with modules of the satellite positioning system (CCM), as well as a stationary geo-information processing station, each of which includes a measurement unit connected in series through an analog-to-digital converter with a data storage and data storage unit and a unit registration and reproduction of information made on the basis of a personal computer.

However, the system [1] is quite complex, includes several modules for measuring geophysical fields of 5-6 types, as a result of which

application in inaccessible shallow water zones (transitional zones of water-land) is difficult and not economically feasible. The system [1] is not mobile (mobile), and this reduces its functionality.

The essence of the proposed technical solution is to create a geophysical complex for the search for oil and gas in shallow, inaccessible waters through a combination of studies of abnormal thermal fields and geochemical surveys.

The main technical result of the proposed geophysical complex is the provision of adequate geophysical exploration in areas of the waters inaccessible for seismic work by combining means of remote temperature sensing and geochemical imaging, which increases the information content and reliability of identifying hydrocarbon deposits while expanding functionality and reducing the composition of the equipment compared to the known devices [1, 2].

The technical result is achieved as follows.

The geophysical complex for the search for oil and gas contains mobile modules (PM) of geophysical exploration in combination with modules of the satellite positioning system (CCM), as well as a stationary geographic information processing station. Moreover, each of the PM includes a measurement unit connected in series through an analog-to-digital converter with a data storage and data storage unit and an information recording and reproducing unit based on a personal computer.

A distinctive feature of the complex is that it includes a set of PM remote sensing of abnormal thermal fields of the water area (TPA) and PM geochemical survey of the water area.

The complex also differs in that the PM remote study of abnormal TPA is made in the form of scanning infrared (IR)

radiometer and mounted on board an aircraft, such as a helicopter.

In the specific case of the complex implementation, a Search-2M scanning infrared radiometer was used as an IR radiometer with a temperature resolution of at least 0.03 ° K, a spatial resolution of at least 2.5 mrad, and simultaneous recording in spectral channels in the ranges of 2.9 -4.9 and 8-12 microns and the display and recording of information in digital form on the hard disk and on the teleindicator with reference to the coordinates by means of CCM, and the MI-8 helicopter was used as an aircraft.

The difference of the complex is also that the PM of geochemical survey of the water area is made in the form of a MUSTANG marine gas analysis station installed on the vessel for continuous profiling of the water column of the water area, including a measurement unit in the form of an outboard water supply device, a device for continuous extraction of the gas phase and its supply into the analytical unit, the storage and memory unit, made on the basis of a personal computer, as well as the CCM module.

In the particular case of performing PM geochemical survey of the water area, it additionally includes a means of geochemical gas surveying by bottom sediments, for example, a spectrum analyzer of hydrogeochemical soil parameters.

In addition, the complex is characterized in that the stationary geoinformation data processing station includes sequentially connected data storage and memory unit, a unit for joint processing of two PM geophysical exploration and detection of geophysical field anomalies by means of a programmable computer, a unit for forming a decision on the presence of hydrocarbon deposits and their location as well as a unit for reproducing information in the form of an analog and / or digital card.

At the same time, the blocks of the stationary geoinformation data processing station are made on the basis of one or several personal computers with the possibility of synchronous data processing of PM remote sensing of TPA and PM geochemical survey of the water area.

In the specific case of the complex, the CCM module is made in the form of a module of the NAVSTAR and / or GLONASS differential satellite navigation system.

In this particular case, the outputs of the PM remote sensing of abnormal TPA and PM geochemical survey of the water area are connected to the inputs of the stationary geographic information station via communication lines, which are made in the form of telemetry, or telephone, or computer, or satellite data transmission systems.

The drawing shows a general structural diagram of the proposed complex for the search for oil and gas.

The complex includes PM 1 for remote research of abnormal TPA, PM 2 for geochemical survey of the water area and stationary geographic information station (GHS) 3. PM 1 contains a measurement unit 4, ADC 5, a storage and memory unit 6, a data recording and playback unit 7, and a CCM module 8. PM 2 includes a measurement unit 9, an ADC 10, an accumulation and memory unit 11, a recording and reproducing unit 12, and a CCM module 13. GHS 3 includes a storage and memory unit 14, a joint processing unit 15, a hydrocarbon decision making unit 16, and a playback unit 17. The complex may additionally include a means 18 of geochemical gas surveys on bottom sediments, which is part of PM2.

The work of the complex is as follows.

At the first stage, a regional remote thermal survey of the surface with potential deposits is carried out. Remote thermal photography [3] is performed by the PM 1 module from the side of an aircraft, for example, the MI-8 helicopter, by means of a measurement unit 4, which

made in the form of a scanning PC radiometer, for example, Search-2 M IR radiometer [3] with a temperature resolution of at least 0.03 ° K, a spatial resolution of at least 2.5 mrad with simultaneous recording in spectral channels in the ranges 2, 9-4.9 and 8-12 microns and displaying and recording information in digital form on the hard disk and on the teleindicator with reference to the coordinates by means of CCM 8. The measurement data of the thermal field of block 4 are converted into digital form in ADC 5 and transferred to block b storage and memory, which also receives data from SSM 8 (in emya, position, speed, course). Block 7 registers and reproduces the TPA value in digital form on the hard disk and on the teleindicator with reference to the coordinates according to CCM 8. Data PM 1 (from blocks 6 and 7) is received for final processing on the GHS 3.

At the second stage of the search, continuous registration of hydrocarbon gases (OHG) through the water column is carried out by means of the PM 2 installed on the vessel, which uses the MUSTANG station, the composition and operation of which are described in [4, 6, 7]. The data of geochemical measurements from block 9 through the ADC 10 enter the block 11 of the accumulation and memory of the geochemical module PM 2, made on the basis of a personal computer, synchronously with the CCM data 13 about the location. Block 12 reproduces and records the geochemical parameters of gases with subsequent data transfer to the GHS 3. In a number of cases (the third stage of operation), gas surveys of the soil by bottom sediments are carried out by means of a spectrum analyzer 18.

Data from PM 1 and PM 2 are finally processed in the GHS 3, where they can be transmitted via communication lines, made, for example, in the form of telemetry, or telephone, or computer, or satellite data transmission systems. From the storage and data storage unit 14, information and control signals are sent to the PM 1 and PM 2 data processing unit 15, where anomalies of the thermal and geochemical fields of the investigated are detected by computer processing

water areas. Block 16 of the GHS station 3 forms a decision on the presence of hydrocarbon deposits and their location, and block 17 reproduces the output information in the form of an analog and / or digital map.

The technology for searching oil and gas deposits during the integration of remote PM and geochemical PM has been tested by the SSC FGUP “Yuzhmorgeologiya” (Gelendzhik) in conjunction with the VSC “GOI im. S.I. Vavilova ”(St. Petersburg) at the famous Beisugsky gas field in the Sea of Azov and in the Temryuk Bay on the underwater mud volcano“ Bank Temryukskaya ”. The obtained results of geological exploration confirmed the effectiveness of using the complex proposed for patenting (see the appendix).

Thus, the proposed complex implements the technical result: ensuring adequate geophysical exploration in areas of the waters inaccessible for seismic work by combining remote sensing and geochemical surveying, which increases the information content and reliability of identifying hydrocarbon deposits while expanding the functionality and reducing the composition of the equipment compared with known devices.

APPENDIX Test results of the complex.

Remote thermal imaging was performed from the MI-8 helicopter using the Search 2 M scanning infrared radiometer. Recording of the spectral characteristics of the survey was carried out on a computer hard drive. Synchronously recorded from the navigation system "NAVSTAR".

At the same time as the thermal survey, a continuous gas survey was conducted of near-surface water at the MUSTANG marine geochemical station. In addition, a gas survey was performed on bottom sediments.

The first thermal sounding ground is located in the Beisugsky estuary of the Sea of Azov, in the waters of which since 1971 a gas field has been exploited (methane, up to 98%). The water depths within the landfill range from 0.2 to 1.8 m. Two tugs of thermal sounding were performed here at heights of 1200 and 2000 m. A gas survey was also carried out, and anomalies of migration methane were obtained confined to the arches of the structure. According to the results of thermal sounding, two pronounced “cold” thermal anomalies in the spectral range from 8 to 12 μm coinciding with the contours of the arches of a gas deposit were revealed in the water area of the Beisugsky estuary.

The second landfill is located in the Temryuk Bay near the city of Temryuk. Landfill with the release of gas to the surface of the water area from an underwater mud volcano - Bank Temryukskaya. The sea depth within the landfill is up to 10 m. According to the results of thermal sensing above the underwater mud volcano, several anomalous zones have been identified. “Cold” thermal anomalies were recorded when shooting from a height of 700 m. When flying at an altitude of 200 m, zones with methane output in the medium-wave channel (2.9-4.6 μm) were recorded as a signal in the methane absorption band in the atmospheric drive layer. In the long-wave channel (8-12 microns) - as a rupture of the surface film of water. The stable cold inhomogeneity observed in both spectral ranges corresponds to an anomalous methane content according to gas survey data (up to 2780 vol%) with a contrast of 2.3 units and anomalies of hydrocarbon gases in sediments with an anomaly contrast in methane homologs of up to 3.9 units.

At the first stage, a regional remote thermal survey of the surface of the water area over potential deposits is carried out. At the second stage, the refinement of the anomalous zones highlighted by thermal imaging, by means of continuous registration of hydrocarbon gases through the water column. At the third stage - a comprehensive geochemical survey of bottom sediments in order to determine the nature of the anomalies.

Thus, the obtained results confirm the effectiveness of using remote sensing using infrared equipment in combination with geochemical surveys for the search and detection of oil and gas fields in poorly studied and inaccessible waters for seismic work. This is especially true for estuaries, bays of the Sea of Azov, the water area of the Northern Caspian, most of the area of which has depths of up to 3 m, significant areas are protected areas and are not accessible for studying seismic equipment.

SOURCES BY BACKGROUND I. Prototype and analogues:

1. RU 35445 U 1, 10.01.2004 (prototype).

2. RU 16406 U 1, 12/27/2000 (analogue).

3. Handbook of the geochemistry of oil and gas / Ed. S.G. Nerucheva. - St. Petersburg: Nedra, 1988, 578 p. (analogue: p. 544-545).

4. RU 23340 U 1, 06/10/2002 (analogue).

5. RU 09653 U 1, 04.16.1999 (analogue). P. Additional sources of prior art:

6. RU 21960 U 1, 02.27.2002.

7. RU 2188440 C1, 08.27.2002.

8. RU23338 U1, 06/10/2002.

9. RU09533 U1, 03.16.1999.

10. RU28257 U1, 03/10/2003.

11. SU1754660 A1, 08/15/1992.

12. Glumov I.F. Automated geophysical complexes for studying the geology and mineral resources of the oceans. - M .: Nedra, 1986, 344 p.

Claims (9)

1. A geophysical complex for oil and gas exploration in water areas containing mobile modules (PM) of geophysical exploration in combination with modules of a satellite positioning system (CCM), as well as a stationary geographic information processing station, each of which includes a measurement unit connected in series through analog-digital converter with a data storage and data storage unit and an information recording and reproducing unit based on a personal computer, characterized in that it includes five PM the remote study of anomalous thermal waters fields (TPA) and PM geochemical survey area. 2. The complex according to claim 1, characterized in that the PM remote sensing of abnormal TPA is made in the form of a scanning infrared (IR) radiometer and mounted on board an aircraft, such as a helicopter. 3. The complex according to claim 2, characterized in that the “Search-2M” scanning IR radiometer with a temperature resolution of at least 0.03 ° K and a spatial resolution of at least 2.5 mrad with simultaneous recording in spectral channels in the ranges of 2.9-4.9 and 8-12 microns and the display and recording of information in digital form on the hard disk and on the teleindicator with reference to coordinates by means of CCM, and the MI-8 helicopter was used as an aircraft. 4. The complex according to claim 1, characterized in that the PM of the geochemical survey of the water area is made in the form of a MUSTANG marine gas analysis station installed on the vessel for continuous profiling of the water column of the water area, including a measurement unit in the form of an outboard water supply device, a continuous extraction device gas phase and its supply to the analytical unit, the accumulation and memory unit, made on the basis of a personal computer, as well as the CCM module. 5. The complex according to claim 4, characterized in that the PM geochemical survey of the water area further includes a means of geochemical gas surveys on bottom sediments, for example, a spectrum analyzer of hydrogeochemical soil parameters. 6. The complex according to claim 1, characterized in that the stationary geographic information processing station includes a series-connected data storage and data storage unit, a unit for joint processing of two PM geophysical exploration data and detection of anomalies of geophysical fields using a programmable computer, and a decision-making unit for hydrocarbon deposits and their location, as well as a unit for reproducing information in the form of an analog and / or digital map. 7. The complex according to claim 6, characterized in that the blocks of the stationary geographic information processing station are based on one or more personal computers with the possibility of synchronous data processing of PM remote sensing of TPA and PM geochemical survey of the water area. 8. The complex according to claim 1, characterized in that the CCM module is made in the form of a module of the NAVSTAR and / or GLONASS differential satellite navigation system. 9. The complex according to claim 1, characterized in that the outputs of the PM remote sensing of abnormal TPA and PM geochemical survey of the water area are connected to the inputs of the stationary geoinformation station via communication lines, which are made in the form of telemetric, or telephone, or computer, or satellite data transmission systems .