RU213343U1 - ELECTROMAGNETIC SOURCE OF SEISMIC WAVES - Google Patents

Abstract

The claimed utility model relates to reducing the visibility of weapons, military and special equipment and can be used to simulate a functioning military facility at permanent deployment points and spare areas of concentration of troops from seismic ground reconnaissance equipment, in particular from reconnaissance and signaling equipment and precision weapons guidance systems. The electromagnetic source of seismic waves contains a base plate located on the soil surface, made of a dielectric material, a weight, an electromagnetic type converter installed with the possibility of creating a force between the base plate and the weight. Moreover, the weight is welded on the upper plane of the base plate along its central axis, with an electromagnetic drive pressed into the upper plane of the weight with a built-in excitation winding, while two steel racks with hollow bushings made in the upper end part are rigidly screwed to the base plate on both sides of the weight. with elastic-elastic cylindrical elements installed in them, on which a U-shaped steel beam is screwed with an anchor screwed into its lower part, and a steel pipe is fixed to the lower plane of the base plate perpendicularly along its central axis by a threaded connection with a ratio of the geometric dimensions of its length to the total height of the load and the electromagnetic drive is 2:1, while the structurally assembled electromagnetic source of seismic waves is placed in a removable and detachable housing, fixed to the side planes of the base plate with a screw connection. The technical result of the utility model is to reproduce seismic waves at a high transmission coefficient generated by an electromagnetic source of seismic waves of mechanical energy into the energy of mechanical impact on the soil. 3 w.p. f-ly, 9 ill.

Description

The claimed utility model relates to reducing the visibility of weapons, military and special equipment (AMSE) and can be used to simulate wheeled or tracked military equipment operating in place from seismic ground reconnaissance equipment, in particular from reconnaissance and signaling equipment (RSA), and high-precision guidance systems weapons (WTO).

The relevance of the claimed utility model of an electromagnetic source of seismic waves is caused by the lack of active technical means of simulating from seismoacoustic ground exploration, in particular from the highly efficient use of SAR.

Among the known devices adopted as analogues, a source of seismic waves is known [1], containing a base plate located on the soil surface - an emitter, a weight - an inert mass, a damper and a pulsed electromechanical converter with a pulsed excitation system. The ferromagnetic armature and the reactor of the electromechanical converter are located coaxially and contain the excitation windings in the grooves on the surfaces of the magnetic circuit facing each other.

The main disadvantage of the known source is the limited use and insufficient seismic efficiency. The limited application is due to the impossibility of prompt movement of the source along the profile during seismic surveys. Placement of the source on a vehicle with a lifting device for its installation on the ground leads to an excessive increase in the weight of the seismic device, an increase in its cost and a decrease in the efficiency of seismic surveys.

Known source of seismic waves [2], containing a plate-emitter of seismic waves, prigruz, an electromagnetic type converter, the inductor of which is rigidly connected to the prigruz, and the armature is placed above the inductor and separated from it by an air gap, electrical power circuits and an excitation winding in the grooves of the magnetic circuit of the inductor .

The main disadvantage of the known source is the limited use and insufficient durability and seismic efficiency. The movement of the weight up and down during the operation of the seismic source is accompanied by significant friction between the weight and its guides. When the seismic source is operating on hilly terrain, the position of the seismic source is non-horizontal, the friction during the movement of the weight along the guides increases, which leads to a decrease in the durability of the seismic source due to the intensive wear of rubbing surfaces, a decrease in the magnitude and stability of the mechanical effects it creates on the ground and a decrease in seismic efficiency. In this case, jamming of the sliding pair of weights - guides is possible, which leads to failures in the operation of the seismic source. In addition, the seismic source cannot create shear waves, which also limits its applicability.

A non-explosive terrestrial seismic source [3] is known, containing a rigid base-emitter, a load supported on it, an inductor magnetic circuit with an excitation winding fixed on the load, an armature magnetic circuit separated from the inductor by an air gap and resting on the plate through the first two supports. The weight is provided with a console, the end of which is connected by means of an axis to the second support with the possibility of angular movement in a vertical plane in the direction of reducing the air gap.

The main disadvantage of the known source is hard mechanical shocks between the magnetic circuits of the inductor and armature that reduce the durability of the seismic source when choosing a gap between them, an increase in the mass of the base-emitter due to the mass of the first two and second racks-supports on it, a significant uneven distribution of the mechanical load on the base, created through racks located along the edges of the plate, and insufficient force developed by the electromagnet, the specific value of which is limited by the saturation induction of the magnetic circuits. These shortcomings reduce the durability of the seismic source, its technical and operational performance and scope.

A non-explosive type seismic source is known [4], containing a rigid emitter plate, a weight supported on it and an electromagnetic motor, the magnetic circuit of the inductor of which with the excitation winding is fixed on the weight, and the motor armature is supported on the plate through the racks and is separated from the magnetic circuit of the inductor by an air gap.

The main disadvantage of the known seismic source is that when a current pulse is applied to the excitation winding, a force appears between the armature and the magnetic circuit of the inductor, which is transmitted through the racks to the plate. The plate under the action of this force is displaced in the direction of the soil, while the soil is deformed and a seismic wave is formed in it. The magnetic circuit of the inductor under the action of the force of the engine accelerates upwards, as a result, the gap between the magnetic circuit of the inductor and the armature is selected. At the moment of choosing the gap, the action of the force on the plate stops, and the accelerated weight with the magnetic circuit of the inductor and the armature move in the gravity field to a certain height, determined by the speed of the weight at the time of choosing the gap.

Since the soil is a medium with elastic properties, after the phase of soil compression, the phase of its expansion begins, during which the plate accelerates upward under the action of the elastic forces of the soil. As a result of this, the soil expands and the slab, having received a significant speed when the soil expands, “flies” above the soil and then falls onto the soil, which leads to the creation of a seismic interference wave that reduces the quality of seismic surveys.

The closest in technical essence to the claimed utility model (prototype) is a pulsed non-explosive ground seismic source with a pulsed induction-dynamic type motor [6], containing a rigid emitter plate, a weight supported on it and a pulsed motor installed with the possibility of creating a force between the plate and weight

The known device is characterized by the fact that during the operation of such a seismic source, under the action of a force, the plate deforms the soil, and the load accelerates upwards. The phase of soil compression is followed by the phase of its expansion and the displacement (“jump”) of the slab above the level of its initial position on the ground, and then the slab re-impacts the soil.

However, despite the positive results achieved, the known device, taken as a prototype, is not intended to create a simulating effect in the zone of a functioning object, and its use will not lead to the formation of a masking effect in the measurement range of seismic waves in the soil, since:

when the slab impacts the ground again, it creates an interference wave, which reduces the seismic efficiency of the seismic source and the quality of the simulation tasks;

in case of “bounces” of the plate, it is necessary to accurately calculate the time of the next impulse, i.e. force impact on the base plate from the side of the electromagnetic source with a load. Otherwise, the force impact will work on the base plate at the moment when the base plate has not yet laid down on the ground, which sharply reduces the efficiency of the electromagnetic source of seismic waves.

In addition, the known emitter has large overall dimensions and low radiation intensity of seismic vibrations generated by a seismic source, which are not able to simulate waves of the required intensity (amplitude) propagating in the ground from wheeled and/or tracked military equipment operating on the spot.

To eliminate these shortcomings, in practice, as a rule, it will be necessary to increase the weight and size parameters of a known seismic source, which will lead to significant labor costs for its manufacture and use.

The objective of the claimed utility model is to expand the functionality of the electromagnetic radiation source, providing imitation of the operation of wheeled and tracked military equipment at its location, reducing labor costs by reducing weight and dimensions when it is installed on site.

The technical result of the utility model consists in reproducing seismic waves at a high transmission coefficient generated by an electromagnetic source of seismic waves of mechanical energy into the energy of mechanical action on the ground, emitting simulating seismic waves identical to the seismic waves of wheeled and tracked military equipment operating on site.

The specified technical result is achieved by the fact that in an electromagnetic source of seismic waves containing a base plate located on the soil surface, made of a dielectric material, a load, an electromagnetic type converter installed with the possibility of creating a force between the base plate and the load, on the upper plane of the base plate along its The central axis is welded with an additional weight with an electromagnetic drive pressed into the upper surface of the weight with an excitation winding built into it. At the same time, on both sides of the load, two steel racks are rigidly screwed to the base plate with hollow bushings made in the upper end part with elastic cylindrical elements installed in them, on which a U-shaped steel beam is screwed with an anchor screwed into its lower part. A steel pipe is fixed to the lower plane of the base plate perpendicularly along its central axis by a threaded connection with a ratio of the geometric dimensions of its length to the total height of the load and the electromagnetic drive 2:1. At the same time, the structurally assembled electromagnetic source of seismic waves is placed in a removable and detachable housing, fixed to the side planes of the base plate with a screw connection, with the formation of interconnected assembly operations that are in the functional and structural unity of the device.

In addition, in the electromagnetic seismic wave source, the length of the steel pipe is equal to half of the shortest side of the base plate, and the free end of the steel pipe is threaded.

In addition, in the electromagnetic source of seismic waves, on the reverse side of the base plate, a U-shaped profile steel beam is screwed with a U-shaped profile height equal to the smallest side of the base plate and a long steel beam equal to the total height of the weight and the electromagnetic type converter.

In addition, in the electromagnetic source of seismic waves, to ensure the operability of the electromagnetic source of seismic waves, the excitation winding built into the electromagnetic drive is connected, for example, via a wire connection using a union nut, to an external autonomous power source, made in the form of a current pulse generator with a saturation choke.

The advantages of the claimed utility model over the known prototype are:

Firstly, a steel pipe screwed on the back side of the base plate allows you to tightly install the base plate of the seismic source on the ground, thereby pressing the seismic source tightly to the ground, therefore, increasing the transmitted power from the electromagnetic source of seismic waves to the ground and thus increasing the efficiency of the electromagnetic source of seismic waves, reducing power losses;

secondly, the absence of a "jump" in comparison with the prototype, the force effect will work on the base plate at the moment when the base plate has already laid down on the ground, and this dramatically increases the efficiency of the electromagnetic source of seismic waves. Thus, the weight and size parameters of the electromagnetic source of seismic waves is much lower than that of analogues and the prototype, which leads to a significant reduction in its cost;

thirdly, the steel pipe screwed from the back side of the base plate is an additional source of seismic wave radiation, therefore, it increases the efficiency of the seismic emitter compared to the prototype. To increase the power as an additional source of radiation, the length of the steel pipe screwed on the back side of the base plate is equal to half of the smallest side of the base plate, and the free end is threaded.

The technical essence of the electromagnetic source of seismic waves is shown in Fig. 1-3.

In FIG. 1 shows an electromagnetic source of seismic waves, where 1 is a base plate, 2 is a weight, 3 is an electromagnet inductor, 4 is an excitation winding, 5 is an external autonomous power source, 6 is a wire connection, 7 is a rigid steel rack, 8 is a hollow bushing, 9 - elastic element, 10 - U-shaped steel beam, 11 - anchor, 12 - steel pipe, 13 - detachable body, 14 - bolted connection, 15 - first gap, 16 - second gap, 17 - ground surface .

In FIG. 2 shows a diagram of a current pulse generator with a saturation choke (DN) where L _n is an inductive load, VD1 is a diode 1, i _LN is a current, DN is a choke, W _p is a working winding, W _y is a control winding, VS1 is a power thyristor 1 , C _to - capacitance, L _to - linear inductance, VD2 - diode 2, U _m - maximum voltage, C _n - capacitance.

In FIG. 3 shows the curves of currents and voltages on its elements, where U _SN is the voltage across the capacitance C _n , U _min is the minimum voltage, U _sk is the voltage across the capacitance C _to , i _Lk is the linear inductance current, t is time.

Implementation of the utility model

To provide imitation of a functioning military facility from seismic ground reconnaissance equipment, in particular from SAR and WTO guidance systems, in the claimed electromagnetic source of seismic waves, containing: a base plate 1 located on the ground surface, made of a dielectric material, a weight 2, an electromagnetic type converter 3, installed with the possibility of creating a force between the base plate 1 and weight 2, on the upper plane of the base plate 1 along its central axis, a weight 2 is welded, with an electromagnetic drive 3 pressed into the upper surface of the weight 2 with a built-in excitation winding 4 connected to an external autonomous source power supply 5 by wire connection 6. At the same time, on both sides of the load 2, two steel racks 7 are rigidly screwed to the base plate 1 with hollow bushings 8 made in the upper end part with elastic-elastic elements 9 of cylindrical shape installed in them, on which a U-shaped steel beam 10 with an anchor 11 screwed into its lower part, and a steel pipe 12 is fixed to the lower plane of the base plate 1 perpendicularly along its central axis with a threaded connection with a ratio of the geometric dimensions of its length to the total height of the load 2 and the electromagnetic drive 3 2: 1, while structurally assembled the electromagnetic source of seismic waves is placed in a removable-detachable housing 13 fixed to the side planes of the base plate 1 by a screw connection 14, with the formation of functional and structural unity of the device interconnected by assembly operations.

At the same time, in the electromagnetic source of seismic waves, the length of the steel pipe 12 is equal to half of the smallest side of the base plate 1, and the free end of the steel pipe 12 is threaded.

On the reverse side of the base plate 1, a U-shaped profile steel beam 10 is screwed with a height of the U-shaped profile equal to the smallest side of the base plate 1 and a long steel beam 10 equal to the total height of the load 2 and the electromagnetic type converter 3.

To ensure the operability of the electromagnetic source of seismic waves, the excitation winding 4 built into the electromagnetic drive is connected, for example, via a wire connection 6 using a union nut to an external autonomous power source 5, made in the form of a current pulse generator with a saturation choke [5].

Functioning of the claimed utility model

The electromagnetic source of seismic waves in place is carried out as follows.

Initially, in the preset mode, when single current pulses are supplied to the excitation winding 4 from the power supply circuit (see Fig. 2), a magnetic flux is created in the electromagnet passing through the first gap 15 and an electromagnetic force arises between the armature 11 and the inductor 3, which, acting on the armature 11 and the inductor 3 and further through the base plate 1 onto the steel pipe 12 fixes it deep from the ground surface 17, so that the base plate 1 is pressed tightly against the ground surface 17. Thus, ensuring the transfer of mechanical energy from the base plate 1 to the ground surface 17 with minimal losses.

When the current pulse from the power supply circuit (see Fig. 2) is re-applied to the excitation winding 4, a magnetic flux passing through the first gap 15 is created in the electromagnet and an electromagnetic force arises between the armature 11 and the inductor 3, under the influence of which the armature 11 and the inductor 3 begin to move towards each other. Moving, the anchor 11 acts on the elastic element 9, compressing it in the direction of decreasing the second gap 16. The anchor 11 accelerates. Further, the anchor 11 is braked, and the kinetic energy acquired by it in the acceleration interval is converted into the potential energy of the compressed elastic element 9. The anchor 11, compressing the elastic element 9, simultaneously acts through it on the steel racks 7 and the base plate 1, as a result of which the base plate 1 starts move with varying speed, forming in the soil 17 a wave of elastic deformations with vertical polarization. The inductor 3 with load 2 move towards the armature 11, and since the mass of the armature 11 is significantly less than the mass of the inductor 3 connected to the load 2, the armature 11 under the action of the electromagnetic force developed by the drive compresses the elastic element 9 and by the time of impact interaction with the inductor selects most of the first gap 15. After the impact interaction, the armature 11 and the inductor 3 with the load 2 move as a single whole, and the elastic-elastic element 9, expanding, transfers its potential energy into the kinetic energy of the joint movement of the armature 11 and the load 2, and the base plate 1. In addition , the mechanical energy from the base plate 1 is transferred to a piece of steel pipe 12 planted in the ground, which in this case is an additional seismic wave emitter. Thus, an SH-type elastic deformation wave is formed, the front of which transforms into an R-type longitudinal wave, forming a surface wave with vertical polarization, thereby increasing the efficiency of the seismic source.

The effectiveness of the claimed useful model of an electromagnetic source of seismic waves was evaluated according to the results of field tests, which showed a positive effect of the proposed utility model and is characterized by the expansion of the functionality of the electromagnetic source of seismic radiation, providing simulation of the operation of wheeled and tracked military equipment at its location, reducing labor costs by reducing weight and dimensions when it is installed on site, due to the reproduction of seismic waves at a high transmission coefficient generated by a seismic source of mechanical energy into the energy of mechanical action on the ground, emitting simulating seismic waves similar to the radiation of wheeled and tracked military equipment.

The possible interference arising in this case was eliminated due to the introduction of special algorithms for a number of reasons. Modern electronic signal processing converters are mainly digital devices with a high density of active and passive elements. This allows, on the basis of microelectronic devices, namely microcontrollers, microprocessors, to take into account, calculate, store in memory the influence of various harmful factors and thus eliminate the interference of the device, functioning with the frequency and amplitude of the simulated wheeled and / or tracked military equipment functioning on the spot.

The purpose of experimental studies is to evaluate the effectiveness of the application of the proposed useful model of an electromagnetic source of seismic waves, which ensures the achievement of a technical result, which consists in reproducing seismic waves at a high transmission coefficient, generated mechanical energy into the energy of mechanical action, on the ground, emitting simulating seismic waves similar to the radiation of a wheeled and caterpillar military equipment, to simulate a functioning object from seismic ground reconnaissance equipment, in particular from SAR and WTO guidance systems.

The methodology of field experimental studies included the choice of the object and subject of research.

The object of experimental research is: imitation of a functioning ground object from seismic means of ground reconnaissance, in particular from SAR and WTO guidance systems.

The subject of the study is: a physical model of the technical solution of an electromagnetic source of seismic waves.

Experimental studies were carried out at the test site in real climatic conditions of natural seismic interference (season - summer).

A schematic diagram of the placement of the test subjects of wheeled and tracked military equipment is shown in Fig. 4, fig. 5

A schematic diagram of the placement of the tested objects of wheeled vehicles and an electromagnetic source of seismic waves is shown in Fig. 4, where

18 - as a simulated object - wheeled vehicles;

19 - propagation of a seismic wave from a simulated object;

20 - as a PCA - instrumentation;

21 - propagation of a seismic wave from the simulator;

24 - as a simulator, the claimed utility model is an electromagnetic source of seismic waves;

L ₁ - distance from the SAR to the simulated object;

L ₂ - distance from the SAR to the simulator;

L ₃ - distance from the simulated object to the simulator.

A schematic diagram of the placement of the tested objects of tracked vehicles and an electromagnetic source of seismic waves is shown in Fig. 5, where

20 - as a PCA - instrumentation;

21 - propagation of a seismic wave from the simulator;

22 - as a simulated object - tracked vehicles;

23 - propagation of a seismic wave from a simulated object;

24 - as a simulator, the claimed utility model, an electromagnetic source of seismic waves;

L ₄ - distance from the SAR to the simulated object;

L ₅ - distance from the SAR to the simulator;

L ₆ - distance from the simulated object to the simulator.

To register seismic waves of the tested objects of wheeled, tracked vehicles and the claimed utility model of an electromagnetic source of seismic waves, the control and measuring equipment of the Baikal seismic station, technical and auxiliary means that provide the necessary measurement accuracy and satisfy the research conditions [7] were used.

In order to identify the verification of the possibility of simulating a functioning object under natural noise conditions, as well as understanding the overall picture of the distribution of frequency components, using the ASTRA software environment, based on the application software package for solving problems of technical calculations MATLAB, a spectral analysis of wheeled, tracked vehicles and electromagnetic source of seismic waves in the frequency band from 0 to 150 Hz [8].

The sequence of experimental studies.

Experimental studies were carried out in 3 stages.

At the 1st stage, the frequency spectrum of wheeled vehicles was determined.

At the 2nd stage, the frequency spectrum of tracked vehicles was determined.

At the 3rd stage, the frequency spectrum was determined, as well as the comparison of the frequency spectrum by the amplitude of the electromagnetic source of seismic waves and their comparison with the frequency spectrum by the amplitude of wheeled and tracked vehicles.

The results of experimental studies are presented in Fig. 6-9.

The results of statistical processing of the frequency spectra of wheeled vehicles operating on site in the range from 0 to 150 Hz are shown in Fig. 6, where:

Table 1 shows a statistical estimate according to the normal law of the distribution of bursts of the amplitudes of the frequency spectrum of wheeled vehicles;

Table 2 shows a statistical estimate according to the normal law of distribution of bursts of amplitudes of the frequency spectrum of an electromagnetic source of seismic waves:

a) the results of statistical processing of the frequency spectra of wheeled vehicles operating on site in the range from 0 to 150 Hz;

b) the results of statistical processing of the frequency spectra of the electromagnetic source of seismic waves in the range from 0 to 150 Hz.

A comparison of the recorded frequency spectra in terms of the amplitude of seismic radiation of wheeled vehicles and an electromagnetic source of seismic waves is shown in Fig. 7 where:

c) frequency spectrum by amplitude for wheeled vehicles;

d) frequency spectrum by amplitude of the electromagnetic source of seismic waves.

The results of statistical processing of the frequency spectra of tracked vehicles operating on site in the range from 0 to 150 Hz are shown in Fig. 8, where:

Table 3 shows a statistical estimate according to the normal law of the distribution of bursts of the amplitudes of the frequency spectrum of caterpillar vehicles;

Table 4 shows a statistical estimate according to the normal law of distribution of bursts of amplitudes of the frequency spectrum of an electromagnetic source of seismic waves;

e) the results of statistical processing of the frequency spectra of tracked vehicles operating on site in the range from 0 to 150 Hz;

f) the results of statistical processing of the frequency spectra of the electromagnetic source of seismic waves in the range from 0 to 150 Hz.

A comparison of the recorded frequency spectra in terms of the amplitude of seismic radiation of wheeled vehicles and an electromagnetic source of seismic waves is shown in Fig. 9, where:

g) frequency spectrum in terms of amplitude for tracked vehicles;

h) frequency spectrum by amplitude of the electromagnetic source of seismic waves.

Processing, analysis and evaluation of the effectiveness of the claimed utility model were subject to the results obtained in the course of experimental studies (see Fig. 6-9).

The analysis of the obtained results of experimental studies shows that when determining the frequency spectrum of wheeled vehicles and an electromagnetic source of seismic waves and comparing them by statistical evaluation, results were obtained confirming the identity of the work of the claimed useful model of an electromagnetic source of seismic waves and objects of a wheeled and tracked military technique.

When comparing the average value of the sample of amplitude fluctuations of the spectrum of wheeled military equipment, equal to 0.38, and an electromagnetic source of seismic waves of 0.379, a discrepancy of values equal to 0.002 was found, which is acceptable, which reliably confirms the creation of a simulation that functions on the site of wheeled military equipment by the source used electromagnetic waves.

When comparing the average value of the sample of amplitude fluctuations of the spectrum of tracked vehicles equal to 0.55 and the electromagnetic source of seismic waves 0.546, a discrepancy of values equal to 0.004 was found, which is acceptable, which reliably confirms the creation of an imitation of tracked military equipment functioning on the spot by the applied source of electromagnetic waves.

Thus, the obtained results of experimental studies confirmed the achievement of the technical result, which consists in reproducing seismic waves at a high transmission coefficient generated by an electromagnetic source of seismic waves of mechanical energy into the energy of mechanical action on the ground, emitting simulating seismic waves identical to the seismic waves of the wheel and tracked military equipment.

The claimed utility model of an electromagnetic source of seismic waves is capable of reproducing low-frequency (up to 100 Hz) and high-frequency (up to 1000 Hz) components of the seismic field of a real wheeled and tracked military equipment operating on site.

Sources of information

1. "Theory and practice of land-based non-explosive seismic exploration", ed. d.t.s. Shneerson M.B., Moscow, OJSC, Nedra Publishing House, 1998, pp. 149-151.

2. RF patent 2171478.

3. RF patent No. 2233000.

4. Impulse electromagnetic seismic sources: features and prospects for improvement. Ivashin V.V., Ivannikov N.A. Journal "Instruments and systems of exploration geophysics", No. 2, 2005, p. 9-14)

5. Churkin I.M., Kolchina N.A., Korzhev V.P. The use of a saturation choke in current pulse generators for excitation of powerful magnetic fields//Vektor Nauk TSU. Togliatti, No. 2 (24) 2013.

6. RF patent No. 2369883.

7. Jenkins G. Spectral analysis and its applications. Issue 1: per. from English. / G. Jenkins, D. Watts - M.: Mir, 1971.

8. Sedukhina G.F. Interactive seismic data processing system ASTRA in the MATLAB environment // Inform. systems and technologies. IST 2000: Intern. sci.-tech. conf.: Proceedings of conf. (reports and abstracts of reports). - Novosibirsk: NGTU, 2000. - T. 3. - S. 342-346.

Claims (4)

1. An electromagnetic source of seismic waves, containing a base plate located on the ground surface, made of a dielectric material, a load, an electromagnetic type converter installed with the possibility of creating a force between the base plate and the load, characterized in that on the upper plane of the base plate along its central axis a weight is welded, with an electromagnetic drive pressed into the upper plane of the weight with a built-in excitation winding, while on both sides of the weight, two steel racks are rigidly screwed to the base plate with hollow bushings made in the upper end part with elastic-elastic elements of a cylindrical shape installed in them , on which a U-shaped steel beam with an anchor screwed into its lower part is screwed, and a steel pipe is fixed to the lower plane of the base plate perpendicularly along its central axis with a threaded connection with a ratio of the geometric dimensions of its length to the total height of the load and electric magnetic drive 2:1, while the structurally assembled electromagnetic source of seismic waves is placed in a removable and detachable housing, fixed to the side planes of the base plate with a screw connection, with the formation of interconnected assembly operations that are in the functional and structural unity of the device. 2. An electromagnetic source of seismic waves according to claim 1, characterized in that the length of the steel pipe is equal to half the smallest side of the base plate, and a thread is cut into the free end of the steel pipe. 3. An electromagnetic source of seismic waves according to claim 1, characterized in that a U-shaped profile steel beam with a U-shaped profile height equal to the smallest side of the base plate and a long steel beam equal to the total height of the weight and transducer is screwed on the back side of the base plate electromagnetic type. 4. The electromagnetic source of seismic waves according to claim 1, characterized in that to ensure the operability of the electromagnetic source of seismic waves, the excitation winding built into the electromagnetic drive is connected, for example, via a wire connection using a union nut, to an external autonomous power source, made in the form of a pulse generator current with saturation choke.

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