RU2113000C1 - Method for prospecting of mineral deposits using their radiation, device which implements said method, microleptonic indicator - Google Patents

Abstract

FIELD: prospecting mineral deposits, in particular, oil pools. SUBSTANCE: method involves displaying microleptonic radiation of object under investigation by making their photography from aircraft or on earth surface, processing satellite photographs or film in order to investigate unknown radiation of object under investigation. Processing of satellite and aerial photographs of object under investigation provides visualization of microleptonic radiation of object under investigation. Then method involves development of mathematical model and map of geological object for detection of coordinates and shape of object under investigation. Corresponding device, which may be located on board of aircraft, helicopter or spaceship, has two digital cameras or video camera, microleptonic active generator, on-board computer and monitor. One claim of invention describes visualization of object under investigation by means of excitation of satellite photograph and analysis of frequency spectrum and histograms of signals by means of computer. Results are detected by means of comparison to reference characteristics. EFFECT: increased quality of oil prospecting, detection of oil pool shape and optimal coordinates of test drilling, facilitated environment protection in region of industrial developing of mineral deposit. 10 cl, 7 dwg

Description

 The invention relates to the search and exploration of various types of mineral deposits, in particular oil deposits, which by its own radiation.

 A known method of searching for underground inhomogeneities by multispectral aerial photography in the visible and infrared ranges of the spectrum of electromagnetic waves. The results of aerial photography are introduced into a computer, where, using an algorithm based on the construction of a mathematical model of the object under study, a conclusion is made about the presence of the object [1]. There is also a method of searching for endogenous deposits by conducting multi-zone aerial photography, in which spectral brightness anomalies are detected in the spectral region of 640-740 nm with values that are 1.5-2.5 times higher than the background, corresponding to areas of hydrothermally altered rocks development, which identified with the areas most promising for surface searches of endogenous deposits, such as tin, etc.

 The closest in technical essence to the proposed one is a method of searching for hydrocarbon deposits by infrared aerial photography, which consists in a sequential round-trip of the studied area with simultaneous scanning of the earth's surface and registration of radiation in the wavelength range of 8-14 microns with subsequent processing of the recorded signals and determining the coordinates of the detected anomalies, identified with hydrocarbon deposits [2].

 However, the known method does not allow with the necessary reliability to identify the desired objects with small amplitudes of temperature changes.

 The technical result of the proposed method is to increase the reliability of the search for mineral deposits by their own radiation.

 To achieve a technical result, a method is proposed for searching for mineral deposits by their own radiation, in which they visualize the energy microlepton radiation of the studied objects by photographing them from aircraft or on the surface of the earth, activate the digital device with a microlepton generator operating in the mode of tunable microlepton resonance at the frequencies of the studied object, then process the incoming information, highlighting the microlepton image of the object, receive an extra-machine information base in the form of space and photographs of the studied area and an intra-machine information base containing microlepton processing of satellite images, direct measurements of the microlepton radiation of the studied objects, mathematical and cartographic modeling of geological objects by constructing digital, electronic and thematic maps, determining coordinates and contours of the desired objects. At the same time, visualization of the radiation of the studied object from the finished satellite images is carried out by exciting satellite images, subsequent analysis of the frequency spectrum and histograms of the signals, processing them on a computer, identifying the results obtained when comparing with the reference parameters of objects. The radiation of the studied object in the active mode is visualized by photographing it from the aircraft, exposing the radiation to film, exciting and amplifying the frequency spectrum of the signals, and processing the data. Visualization of the radiation of the studied object is carried out by directly photographing it with the illumination of a halogen lamp and a exposure time of 1-2 seconds.

 Indication of microlepton radiation from objects studied in static mode is carried out by scanning space images with a microlepton indicator, subsequent amplification of signals from the indicator and processing of the obtained data.

 To implement the proposed method, a device has been developed for searching for mineral deposits by microlepton radiation, in which the system installed on board the aircraft or vehicle contains two digital cameras, a microlepton generator designed to activate the digital camera, and a computer that implements visualization and information processing from the microlepton fields of the studied objects by entering to the computer through one channel of electromagnetic information together with creeping, and on the second channel - only electromagnetic.

 In the case of using ready-made satellite images to obtain the contour of the microlepton portrait of the desired object, the satellite image is placed in the shielding chamber, where the scanning device is located, on which the ML indicator is mounted, connected to the computer via an analog-to-digital converter. To excite a space image at a distance of about 30 cm from the shielding chamber, an ML generator with a Tesla antenna is placed.

 For direct photographing of an object or for re-photographing a space photograph, a camera is used, on the lens of which a freely rotating lens hood with a wound cambric spiral is installed, a cone with a cambric base is attached to the rear wall of the camera. This is a static mode for obtaining a microlepton portrait of an object under study.

 To indicate microlepton radiation in static mode, a microlepton indicator is developed, consisting of a cone, inside which is placed a container with the material of the object under study and the antenna in the form of a flat spiral coil. A microlepton indicator is installed in a shielding chamber on a scanning device from satellite images, while the indicator is connected to a computer through a preamplifier, matching amplifier, and an analog-to-digital converter.

 The present invention is based on the property that all physical objects, including geological (rocks, oil, gas, ores, minerals, water, etc.). no matter how deep they are in the land or on the sea shelf, they have their own microlepton fields, just like all physical objects have gravitational and electromagnetic fields.

 Each of the fields characterizes a certain class of fundamental physical interactions between elementary particles: gravitational - gravitational, electromagnetic - electromagnetic, and leptonic - the so-called weak. The carriers of weak fields are leptons and their lighter variety - axions. There are six known leptons: an electron, a muon, a tau lepton, and three types of neutrinos that do not have an electric charge. In addition, there are six antileptons. Of particular interest among leptons is neutrinos, which make up the bulk of the substance of the universe.

 The mathematical model of the lepton gas is based on the hypothesis that nonrelativistic light particles are excited as a result of exposure to a magnetic field. As a result, they acquire a short-range weak charge, which can interact with a weak charge of an electron or nucleon.

At present, even more ultralight subatomic particles, which are part of matter, are identified. For convenience, they were designated, by analogy with leptons, microleptons. The microlepton rest mass of about 10 ^-5 eV, which is 10-15 orders of magnitude less than the electron rest mass, has been experimentally determined.

 Relatively small masses and weak charges of microleptons primarily determine their colossal penetrating ability in natural environments. In other words, the microleptons of a deposit or deposit are practically not screened by solid rocks of the Earth and the waters of the coastal shelf and, freely spreading in outer space, will be displayed on the corresponding film frame of a space camera during the exposure of a region where the deposit is located.

 A microlepton gas in neutral and excited (weakly charged state) states is in solids, liquids and gases, and also penetrates all the Earth’s media and is in space. In homogeneous media and Cosmos, these gases are structured into spheroidal forms such as cluster formations, and around individual solids into multilayer cluster structures, and the mass of the microlepton is proportional to the mass of the chemical element of the body. The microlepton gas is in a state close to superfluid, and its cluster structures are in constant motion. Microleptons are part of the atom and its nucleus and are located around the electron. Excited microleptons and axions interact with free and bound electrons and nucleons of a substance, which leads to a change in its electromagnetic and mechanical characteristics (dielectric and magnetic permeability, strength, viscosity, etc.). In media, excited microlepton and axion gases induce weak magnetic and electric fields. In general, the state of microlepton gas (clusters) is determined by the complex interaction of leptonic and electric charges, as well as leptonodynamic (spinor) and magnetic fields. A change in the state of a microlepton gas induces electric and magnetic fields. More precisely, there is a mutual induction by the electromagnetic lepton and lepton electromagnetic fields.

 The technical essence of the proposed method consists in measuring the radiation of the desired geological objects from aircraft or during ground surveying by indicating the radiation of objects on storage media, in particular on microcircuit ISS type CCD. Before the exposure, the microleptonic fields from all sources within the radius of action of which this ISS are exposed to the ISS CCD object. However, the intensity of the mentioned fields is insufficient for its excitation. In the process of space photography, the reflected electromagnetic (light) signal from all physical bodies in the area of the device affects the ISS CCD. At the same time, local electrostatic fields arise in the CCD elements due to the action of the microlepton fields of physical objects located on the Earth's surface or in its bowels. The process is enhanced when a static microlepton field is superimposed on the ISS CCD. This leads to the total charge density on the ISS optical and microlepton. When processing on a computer, the optical is subtracted from the total portrait, and as a result, the microlepton remains, characterizing, for example, the contours of the occurrence of oil in the corresponding deposits in three dimensions. The technological implementation of the method is not associated with any power, destructive effects on the study area. When implementing the microlepton search technology, specialists deal with environmentally friendly work procedures.

 The set of ordered information used in the operation of the method forms its information base, which consists of two parts: an extra-machine information base, used in a form reproduced by a person without the use of computer technology (satellite images of the studied territories and microleptonic portraits of the same territories, topographic maps and etc.), and the internal machine information base on machine media (electronic and digital cards, other problem-oriented models).

 The internal machine information base, especially the part that is associated with obtaining microleptonic portraits of the studied oil reservoir, is formed in the general case using the following technological operations: specific microlepton and machine processing of the initial image, in particular, the space one; direct measurement of some parameters and conditions of the location of oil and other deposits by geophysical anomalies as a result of direct measurements of the parameters of the above-mentioned anomalies using special measuring microlepton equipment installed on a helicopter, aircraft, etc.

 Mathematical-cartographic modeling (MKM) allows you to combine the process of using maps and mathematical models when displaying (visualizing) and exploring objects.

 The basis for modeling the structures of geological objects, for example, oil deposits displayed on a map and presented in digital form, is the principle of territorial zoning. An internal structural feature of territorial (volumetric) complexes is the intensity of oil occurrence. In the process of zoning, the presence of zoning centers (cores) is taken into account (in a particular case, these can be the coordinates of the points of the most preferred laying of exploratory wells), the continuity and compactness of territorial units, the materiality and stability of intra-district connections (for example, in the form of reservoir properties). In this case, the homogeneity of the territorial properties, grouped into classes according to the intensity of oil occurrence, and which can be both continuous and territorially divided, is considered. The task of zoning the territory of the field by a set of indicators (or in a particular case by the intensity of oil distribution) is solved using factor analysis.

 An electronic card refers to the display of a digital card on a monitor screen or its presentation on a plotter (printer).

 A thematic map is a kind of electronic map that displays the structure and shape of the desired deposit, as well as its regionalization by the intensity of oil distribution in the field.

The functions that are implemented in the thematic electronic map include:
- assignment or change of colors of individual elements of the map (i.e., territories with different intensities of occurrence of deposits). Moreover, color manipulation can be statistical when individual colors are set, and dynamic when the user sets the initial and final color for a given scale, and all intermediate colors are automatically calculated by the system;
- display on the display screen of numerical, textual and other information associated with each element of the thematic map. In this case, requests can be either graphic or numerical;
- cartometric definitions, i.e. obtaining values of line lengths, perimeters, closed loops, areas of territories, volume of deposits;
- extraction of additional information based on analysis carried out with the data available in the system. These may be, for example, the optimal coordinates of the drilling points;
- functions that can be considered as rigidly defined and tied to the territory of the deposit or the volume of the deposit. Such, for example, can be a layer-by-layer representation of the structure of the reservoir with the necessary discreteness along the Z coordinate.

 In FIG. 1 shows a block diagram of the visualization of microlepton radiations emitted by the investigated geological object; in FIG. 2 is a block diagram of a device for measuring radiation of an object under study during aerial photography; in FIG. 3 is a data processing flowchart; in FIG. 4 and 5 - devices for visualizing radiation when directly photographing the object under study, or when retaking from aerial and space images; in FIG. 6 - a device for indicating static microlepton radiations (fields); in FIG. 7 - device microlepton indicator.

 The method is carried out by measuring the intrinsic radiation of the desired geological objects (rocks, ores, water, oil, gas, etc.).

 In FIG. 1 shows a block diagram of a device for implementing the proposed method, which includes two digital cameras (DFA) or video cameras 1,2, a microlepton active generator (MLG) 3, a transported computer 4 and a monitor 5. Electromagnetic information is received along channel 1 together with microlepton, and on channel 2 - only electromagnetic. A computer is designed to process information and extract from it only a microlepton image of an object and the results of its mathematical processing.

 The microlepton generator is designed to activate the ISS CCD digital apparatus. The microlepton generator consists of a generating and receiving microlepton inductors in the form of two windings embedded in each other.

 MLG works as follows. The reference signal with a frequency of 50-70 kHz comes from a master adjustable oscillator, which is loaded on a generating microlepton inductor. The microlepton signal from the secondary winding of the generating inductor is fed through a conductive channel to the secondary winding of the receiving inductor. The generator operates in a tunable microlepton resonance mode at the frequencies of the object under study.

 The intrinsic radiation of geological objects is exposed on film. In this case, the generator excites the frequency spectrum of the studied object, amplifying the signal. The film shows the previously invisible energy radiation of the desired object, as if its visualization occurs. In the process of further processing, the obtained data is combined with a geological map and the coordinates of the object of study.

 The block diagram of the indication and visualization of microlepton radiations emitted by the investigated geological object is depicted in figure 2.

 Indication is as follows. The indicator 2 of the selective voltmeter 1 with a bandwidth of 1 MHz is mounted on the scanning device 3. The generator 6 and the antenna 7 are located at a distance of about 30 cm from the screen camera 5, in which the space image 4 is located. The generator 6 and the antenna 7 excite the space image. Pulses occur in the frequency range below the frequency of the generator after 15-20 minutes after making a space image in the camera.

 The frequency spectrum and histograms of the signals coming from the voltmeter 1 and the scanning device 3 are processed on a personal computer according to the circuit shown in FIG. 3, where voltmeter 1, ADC 8, computer 9.

 Identification of the results is carried out on a PC using the reference parameters of geological objects with data output to the monitor.

 Visualization of the energy microlepton radiation of the studied objects is carried out both by direct photographing of the desired object, and by re-photographing from space images.

 To do this, use a camera type "Zenith" with a fast lens "Helios". In FIG. Figures 4 and 5 show a device for visualizing the radiation that is on received films when reshaping aerial and space images.

 In FIG. 4 shows a camera with a hood.

 In FIG. 5 - it is with a cone on the back cover.

 A hood 2 is mounted on the camera 1 through a special ring, which rotates freely on the lens. A spiral tube of cambric 3, in which there is a mixture of boric acid with epoxy, is wound clockwise on the hood on the outside. The end of the spiral tube on the inner side is joined with the beginning of the spiral.

 To energize the camera and film, a cone 4 of 3-4 cm in diameter is installed on the back of the camera. The cone is made of copper oxide and iron mixed with epoxy resin. At the base of the 5 cone around the perimeter, equal to the size of the frame, lay a tube of cambric with a composition of a mixture of boric acid with epoxy.

 When photographing, the image is highlighted with a powerful halogen lamp to optimize exposure. Film processing is carried out in an x-ray developer in the usual manner.

 After processing, the film reveals the energy formations that characterize this object, which do not record ordinary photographing. Thus, the energy fields of the desired object are visualized.

 Indication of static microlepton fields is carried out in accordance with the block diagram of FIG. 6, where a scanning device 3, a microlepton indicator 10, and a space image 4 are installed in the screen camera 5. The signal from the microlepton indicator is fed to the preamplifier 11, then to the PC 9 through the matching amplifier SU-12 and the analog-to-digital converter 13 to obtain data in the form histograms, spectra, graphic information and other types of display of the desired geological objects.

 In FIG. 7 shows the device of the microlepton indicator 10, which is a stainless steel cone, inside of which is placed a container 15 with the material of the object under study and the antenna 14 in the form of a flat spiral coil.

 Example. The proposed method is implemented in one of the oil fields by a two-stage study of local excitations of the natural microlepton field of the earth, caused by hidden geological formations of oil fields. At the first stage, two-dimensional (in X-Y coordinates) visualization of the microlepton "oil" information located in the satellite image is carried out. The second stage involves the determination and refinement of the field contours and its industrial reserves with the help of special equipment installed on a helicopter. To clarify the boundaries of the field, determine the approximate depth of the oil and preliminary estimates of the reserves of the investigated field, as well as select the optimal coordinates for exploration drilling, fly around the area by helicopter and scan the area using special on-board instruments and sensors. In the process of helicopter flying around, special on-board devices respond to variations in the intensity of the microlepton radiation of oil located in different zones of the studied reservoir. Such variations are appropriately recorded and subsequently used for mapping the field.

 The color image is a color-coded image of an oil field. When analyzing the microleptonic portrait of an oil reservoir on a computer, its boundaries were determined. An oil reservoir is a heterogeneous formation, but rather separate regions. Color separation shows that there are places with a high saturation of hydrocarbon raw materials. Areas bounded by blue and deep purple are characterized by the presence of oil. Areas bounded by green show only weak saturation or the presence of oil. The rest of the space, painted in yellow, red and crimson colors, has no oil formations.

 The results of the work allow us to give a qualitative analysis of the studied area (whether there is oil or not), determining the contours of the oil reservoir, the profile of the reservoir, including the Z coordinate, the optimal coordinates of the drilling verification points, and a quantitative forecast of oil reserves.

 The predicted reduction in financial costs is achieved not less than 3 times when working on land, and more than 10 times on the shelf. Optimization of the location of drilling points will predetermine a smaller amount of environmental work in the territory during the industrial development of the oil reservoir.

Claims (10)

 1. A method of searching for mineral deposits by their own radiation, including flying around the study area, scanning the Earth’s surface and registering radiation with subsequent processing of the recorded signal and determining the coordinates of the identified anomalies identified with the desired geological objects, characterized in that they visualize the energy microlepton radiation of the studied objects by photographing them from aircraft or on the surface of the Earth, they activate the digital apparatus with a microlepton generator operating in a tunable microlepton resonance mode at the frequencies of the object under study, the incoming information is processed, highlighting the microlepton image of the object, an extra-machine information base is obtained in the form of space and photographs of the territory under study, and an intra-machine information base containing microleptonic processing of satellite images, direct measurements of the microlepton radiation of the studied objects, mathematical and cartographic modeling of geological objects Comrade by building digital, electronic and thematic maps, determining the coordinates and contours of the desired objects.  2. The method according to claim 1, characterized in that the radiation of the test object in the active mode is visualized by photographing it from the aircraft, exposing the radiation to film, exciting and amplifying the frequency spectrum of the signals, and processing the data.  3. The method according to claim 1, characterized in that the radiation of the investigated object is visualized by exciting a space image, then analyzing the frequency spectrum and histograms of the signals, processing them on a computer, identifying the results obtained when comparing with the reference parameters of the objects.  4. The method according to claim 1, characterized in that the radiation of the studied object is visualized by directly photographing it with the illumination of a halogen lamp and the exposure time of 1 to 2 seconds.  5. The method according to claim 1, characterized in that, when processing the incoming information, the static microlepton fields of the objects under study are indicated by scanning satellite images with a microlepton indicator, subsequent amplification of the signals from the indicator and processing of the obtained data.  6. A device for searching for mineral deposits by microlepton radiation, in which the system installed on board the aircraft or vehicle contains two digital cameras, a microlepton generator for activating a digital device, operating in the mode of tunable microlepton resonance at the frequencies of the studied object, and a computer that visualize and process information from the microlepton fields of the studied objects by receiving electromagnetic information through one channel together with the microlepton, in the second - only electromagnetic.  7. The device according to claim 6, characterized in that for the visualization and processing of information, the device is equipped with a shielding camera with a scanning device on which a selective voltmeter indicator is connected, connected via an analog-to-digital converter with a computer, the generator and antenna exciting the space image, located from the shielding chamber at a distance of about 30 cm  8. The device according to claim 6, characterized in that it contains a camera, on the lens of which is mounted a freely rotating hood with a wound cambric spiral, a cone with a cambric base is attached to the rear wall of the camera.  9. A microlepton indicator, consisting of a cone, inside of which is placed a container with the material of the object under study and the antenna in the form of a flat spiral coil.  10. The device according to claim 9, characterized in that the microlepton indicator is mounted in a shielding chamber on a scanning device with a satellite image, while the indicator is connected to a PC through a preamplifier, matching amplifier and analog-to-digital converter.

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