RU110508U1 - SEISMIC CONTROL SYSTEM AND EARTHQUAKE PREDICTION - Google Patents

Abstract

 1. A system for monitoring the seismic situation and earthquake prediction, comprising a network of measuring posts with a block of earthquake precursor sensors (PZ) located on the earthquake-prone territory of the Earth and connected through a satellite communications system or mobile network of a regional communications operator to a central PZ signal processing station, which contains in series connected PZ signal processing unit, a threshold device, and an alert signaling unit about an upcoming earthquake and its location, The fact that the sensor unit of each measuring station is installed at a depth of not less than fifty meters from the Earth’s surface and contains a ferromagnetic sensor for tensile and displacement of the Earth’s rocks, a ferromagnetic temperature sensor, a ferromagnetic sensor for the intensity and direction of the lines of force of the Earth’s magnetic field and / or a ferromagnetic sensor infrasonic and acoustic signals of the PZ, and the processing unit of the PZ signals of the central station is made in the form of a digital correlator of electromagnetic radiation of ferromagnetic sensors PZ . ! 2. The system according to claim 1, characterized in that the ferromagnetic sensor for the tension and displacement of the Earth’s rocks is made in the form of a ferromagnetic film 10-100 μm thick mounted on a flexible substrate and equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding. ! 3. The system according to claim 1, characterized in that the ferromagnetic sensor of the intensity and direction of the lines of force of the Earth’s magnetic field contains a dielectric element in the form of a cube or a rectangular parallelepiped, on orthogonal surfaces of which

Description

The utility model relates to systems for monitoring seismic conditions and timely prediction of earthquakes, tsunamis, or volcanic eruptions.

Known systems for monitoring the seismic situation and predicting earthquakes [1-16], based on analog primary sensors for measuring the magnitude of the longitudinal and transverse vibrations of the earth's crust caused by shear stress of the rock during volcanic eruptions, artificial explosions carried out for the purpose of exploration. Other sensors are also used at seismic stations that monitor changes in the geomagnetic field, electric field strength, analyzers of changes in the composition of the atmosphere, radiation, etc.

The closest known technical solutions for the purpose and technical nature of the claimed utility model include a system for monitoring the seismic situation and earthquake prediction [16], which contains a network of measuring posts with a block of earthquake precursor sensors (PZ) located on the earthquake-prone territory of the Earth and connected via a satellite system a communication network or a mobile network of a regional communication operator with a central station for signal processing of a PP, which contains a series-connected block of image quipment PP signals, a threshold device and warning signal output unit of the impending earthquake and its location. In this case, the sensor block of the PP includes modules for measuring the seismic signals of the PP, modules for measuring the geophysical signals of the PP, modules for measuring the geodetic signals of the PP, and modules for measuring the geochemical signals of the PP.

The disadvantage of this system is the relatively low reliability of predicting the moment of onset and location of earthquakes, despite the increased number of types of PP sensors. This is due to the following:

Firstly, in the known system there is no spectral analysis of the received PZ signals and, as a result, synchronized cross-correlation processing of the amplitude-frequency characteristics of the received signals by different nature sensors in real time is impossible.

Secondly, the information that magma noise signals carry at depths of 50-100 m and more is ignored. It is in the spectra of magma noise signals that the basic information about the nature and development of processes in seismically dangerous areas is contained. Currently, noise signals are perceived as interference.

Thirdly, the measurement and analysis of the parameters of the PZ signals are not related to the gravitational global impact on the planet Earth of its closest moon satellite (meaning tidal gravitational influences, which play the role of a "trigger" for initiating earthquakes).

The above-mentioned shortcomings in the measurement and primary processing of the physical parameters of the external influence on the sensors lead to a significant scatter in the estimates of the forecast of the moment of onset and location of the earthquake.

The objective of the utility model is to increase the reliability of forecasting the moment of onset and location of earthquakes. The technical result is an increase in the accuracy of measurements of PZ signals.

The achievement of the claimed technical result and, as a result, the solution of the problem is ensured by the fact that the seismic situation monitoring and earthquake prediction system, comprising a network of measuring posts with a block of earthquake precursors sensors located on the earthquake-prone territory of the Earth and connected via a satellite communications system or a regional mobile network a communication operator with a central signal processing station PZ, which contains a signal processing unit connected in series A PP, a threshold device and a block for issuing warning signals about an upcoming earthquake and its location, according to a utility model, the sensor block of each measuring station is installed at a depth of not less than fifty meters from the Earth’s surface and contains a ferromagnetic sensor for stretching and displacement of the Earth’s rocks, a ferromagnetic temperature sensor, a ferromagnetic sensor of the intensity and direction of the lines of force of the Earth’s magnetic field and / or a ferromagnetic sensor of infrasound and acoustic signals PZ, and a signal processing unit in the PP of the central station is configured as a digital correlator EMI PP ferromagnetic sensors.

At the same time, the ferromagnetic sensor of tension and displacement of the Earth’s rocks is made in the form of a ferromagnetic film 10-100 μm thick, mounted on a flexible substrate and equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding. A ferromagnetic sensor of the intensity and direction of the lines of force of the Earth’s magnetic field contains a dielectric element in the form of a cube or a rectangular parallelepiped, on whose orthogonal surfaces there are ferromagnetic films equipped with a signal winding and an excitation winding sprayed and perpendicularly oriented relative to each other on its surfaces. The ferromagnetic sensor of the infrasound and acoustic signals of the PP contains a housing inside which a mechanical pendulum with a magnet is suspended above a ferromagnetic film equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding. The ferromagnetic temperature sensor comprises a ferromagnetic film mounted on a bimetallic substrate in a permanent magnet field and equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding.

The implementation of PZ sensors ferromagnetic according to [17 ÷ 19] allows more than an order of magnitude to increase the sensitivity of PZ sensors by a set of PZ parameters: displacement and stretching of the earth's crust; by registering changes in the magnetic field of the Earth and the direction of its magnetic lines of force; by registering temperature changes; on registration of infrasound and acoustic signals The consequence of this is to increase the accuracy of measurements of the PZ signals and the reliability of the earthquake forecast.

The penetration of a block of ferromagnetic sensors into the earth to a depth of not less than fifty meters from the Earth's surface allows us to exclude the influence of transport and industrial interference on the registration of PZ signals. At the same time, such a deepening makes it possible to register Earth magma noises and use their noise bursts for the operational recording of the beginning and place of earthquakes. The execution of the signal processing unit of the central station PZ signals in the form of a digital correlator of electromagnetic radiation of ferromagnetic PZ sensors additionally allows to increase the accuracy of measurements of the start moment and location of earthquakes.

Figure 1 presents a functional diagram of a system for monitoring seismic conditions and earthquake prediction through a satellite communication system, figure 2 is a design of the measuring post, figure 3 is a functional diagram of a Central station for processing signals PZ, figure 4 ÷ 7 are examples of design ferromagnetic sensors PZ for various purposes.

The system for monitoring the seismic situation and earthquake prediction contains a network of measuring posts 1 with a block 2 of ferromagnetic earthquake precursors (PZ) sensors located on the earthquake-hazardous area of the Earth and connected via the satellite communication system 3 and / or the mobile network of the regional communication operator to the central station 4 for processing PZ signals . Block 2 of ferromagnetic sensors of the PZ measuring posts 1 is installed at a depth of not less than fifty meters from the Earth’s surface and contains a ferromagnetic sensor 2.1 of tension and displacement of the Earth’s rocks, a ferromagnetic sensor 2.2 of the temperature inside the Earth, a ferromagnetic sensor 2.3 of the intensity and direction of the lines of force of the Earth’s magnetic field and / or ferromagnetic sensor 2.4 infrasound and acoustic signals PZ. In this case, the ferromagnetic sensor 2.1 of tension and displacement of the Earth’s rocks is made in the form of a ferromagnetic converter of mechanical energy of the stretching of rocks into energy of electromagnetic radiation and contains a ferromagnetic film 2.1.1 with a thickness of 10-100 μm, mounted on a flexible substrate 2.1.2 and equipped with a signal winding 2.1.3 and a winding 2.1.4 excitation oriented perpendicular to the signal winding 2.1.3. The ferromagnetic temperature sensor 2.2 contains a ferromagnetic film 2.2.1 mounted on a bimetallic substrate 2.2.2 in the permanent magnet field 2.2.3 and equipped with a signal winding 2.2.4 and an excitation winding 2.2.5 oriented perpendicular to the signal winding 2.2.4. A ferromagnetic sensor 2.3 of the intensity and direction of the lines of force of the Earth's magnetic field contains a dielectric element 2.3.1 in the form of a cube or a rectangular parallelepiped, on the orthogonal surfaces of which are applied ferromagnetic films 2.3.2 equipped with a signal winding perpendicular to their surface 2.3.3. and winding 2.3.4 excitation. The ferromagnetic sensor 2.4 of the infrasonic and acoustic signals of the PP contains a housing 2.4.1, inside which a mechanical pendulum 2.4.2 with a magnet 2.4.3 is suspended above a ferromagnetic film 2.4.4, equipped with a signal winding 2.4.5 and an excitation winding 2.4.6 oriented perpendicular to the signal winding 2.4.5. The signal and excitation windings of the ferromagnetic sensors 2.1 ÷ 2.4 are connected respectively through the block 2.5 of analog-to-digital and digital-to-analog converters, as well as through the interface optical or wire line 5 of communication with the control computer 6 of station 1. The signal and control outputs of the computer 6 are connected via transceiver the device 7 of the satellite communication system 3 or regional mobile communication with the station 4. The station 4 contains a series-connected block 4.1 processing signals PZ, a threshold device 4.2 and block 4.3 of the issuance of signals alerts about an upcoming earthquake and its location. Block 4.1 is made in the form of a digital correlator of electromagnetic radiation of ferromagnetic sensors PZ. The threshold device 4.2 is made in the form of a block of circuits for comparing the current values of the PZ signals with their maximum permissible values. Block 4.3 issuing warning signals about an upcoming earthquake and its location is made in the form of a digital module equipped with a program for ranking threats and calculating the coordinates of expected earthquakes. In a preferred embodiment, blocks 4.1 ÷ 4.3 are made in the form of digital modules mounted on a bi-directional interface bus 4.4 connected to a host computer 4.5 and input / output device 4.6 of signal and cartographic information.

The system for monitoring seismic conditions and earthquake prediction works as follows.

The host computer 4.5 of the central station 4 of the processing of the PZ signals through the communication line 3 with a given update rate conducts a survey of the measuring posts 1 about the seismic situation in the area of their location. In this case, the computer 6 of the measuring stations 1 in turn generates in digital form its own impulse polling signals, which are fed through the communication line 5 and the digital-to-analog converter 5 to the excitation windings 2.1.4, 2.2.5, 2.3.4, 2.4.6 of the PZ ferromagnetic sensors block 2. In this case, the Bohr magnetons of the corresponding ferromagnetic films 2.1.1, 2.2.1, 2.3.2, 2.4.4 are deployed along the magnetic field lines of the indicated field windings. In this case, magnetons pass on to increased energy levels. After the end of the survey, under the influence of the current state of the magnetic field, these magnetons return to their original state, emitting an energy quantum in the form of pulsed broadband radio emission proportional to the energy of the difference in the energy levels of the magnetic field in the excited and measured state [17 ÷ 19]. The radio emission of these ferromagnetic films is recorded by the corresponding signal winding 2.1.3, 2.2.4, 2.3.3, 2.4.5 and then in block 2.5 (figure 2) it is converted into a digital signal and transmitted via line 5 to computer 6 for measuring and calculating the current amplitude-frequency characteristics of PZ signals, their derivatives (rate of change of PZ signals) and their mathematical expectation at the time of the forecast. The calculation results are accumulated in the memory of the computer 6 of the measuring station 1 and at the same time some of them, including deviations from the norm, are transmitted via the communication line 3 to the central point 4 of the processing of the PZ signals. The obtained spectra of PZ signals received from all measurement points 1 are fed to the digital correlator of block 4.1. The numerical values of the amplitude of the convolution autocorrelation function and its spatio-temporal position are transmitted to the threshold device 4.2. Device 4.2 compares the current values of the PZ signals with their maximum permissible values and, if the threshold is exceeded, issues them to block 4.3 to generate warning signals about the upcoming earthquake and its location. In block 4.3, the spatial position of the expected earthquake and the depth of its occurrence in the earth's crust are further refined by the triangulation method (crossing directions to the spatial position of the correlation signals relative to each measuring point 1). At the same time, seismic threats are ranked on the scale of their danger, and the moment of the earthquake on the time the next gravitational tide arrives at the seismically dangerous territory is specified. The expected earthquake is linked to a digital map of the area and transmitted to the digital display of station 4 through an input / output device to display seismic and cartographic information. At the same time, this information through the input-output device 4.6, the transmitting channel of the transceiver 8 and the communication line 3 is issued to end users of seismic information to prevent and protect the population from the imminent threat of a dangerous earthquake, tsunami and / or volcanic eruption.

The utility model was developed at the level of technical proposal and prototypes of patented ferromagnetic sensors [18-19].

Information sources:

1. RU 2205432 C1, 05.27.2003

2. Methods of forecasting earthquakes. Their use in Japan / Ed. T. Assad. Per. from English - M .: Nedra, 1984, p. 14, 288-289, 312 p.

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5. SU 1409027 A1, 01/10/1996.

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15. Bolt B. Earthquakes: a publicly available essay. - M.: Mir, 1981, 408 p.

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17. Kolesnik V.N. "The phenomenon of stimulated electromagnetic radiation by ferromagnets in the range of radio waves." Application for the opening of the USSR No. 32-from-9935, 11.24.1978.

18. Shepilov M.M. and Ryzhonkov G.I. Sensor of seismoacoustic vibrations. RU 14682, 2000.

19. Kolesnik V.N., Kolesnik G.V. Ferrodin Ferromagnetic Converter. RU 19963, 2001

Claims (5)

1. A system for monitoring the seismic situation and earthquake prediction, comprising a network of measuring posts with a block of earthquake precursor sensors (PZ) located on the earthquake-prone territory of the Earth and connected through a satellite communications system or mobile network of a regional communications operator to a central PZ signal processing station, which contains in series connected PZ signal processing unit, a threshold device, and an alert signaling unit about an upcoming earthquake and its location, The fact that the sensor unit of each measuring station is installed at a depth of not less than fifty meters from the Earth’s surface and contains a ferromagnetic sensor for tensile and displacement of the Earth’s rocks, a ferromagnetic temperature sensor, a ferromagnetic sensor for the intensity and direction of the lines of force of the Earth’s magnetic field and / or a ferromagnetic sensor infrasonic and acoustic signals of the PZ, and the processing unit of the PZ signals of the central station is made in the form of a digital correlator of electromagnetic radiation of ferromagnetic sensors PZ . 2. The system according to claim 1, characterized in that the ferromagnetic sensor for the tension and displacement of the Earth’s rocks is made in the form of a ferromagnetic film 10-100 μm thick mounted on a flexible substrate and equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding. 3. The system according to claim 1, characterized in that the ferromagnetic sensor of the intensity and direction of the lines of force of the Earth’s magnetic field contains a dielectric element in the form of a cube or a rectangular parallelepiped, on the orthogonal surfaces of which are applied ferromagnetic films equipped with a sprayed layer and oriented perpendicular to each other on it surfaces with a signal winding and a field winding. 4. The system according to claim 1, characterized in that the ferromagnetic sensor of the infrasound and acoustic signals of the PP contains a housing inside which a mechanical pendulum with a magnet is suspended above a ferromagnetic film equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding. 5. The system according to claim 1, characterized in that the ferromagnetic temperature sensor comprises a ferromagnetic film mounted on a bimetallic substrate in a permanent magnet field and equipped with a signal winding and an excitation winding oriented perpendicular to the signal winding.