RU2523755C2 - Electromagnetic radiator of seismic shear waves - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a radiator of seismic shear waves which consists of a radiating platform with ground lugs, an electromagnetic drive, an armature and a housing. The electromagnetic drive is in form of a base and two inductors placed in grooves on the base at an angle of 90° to each other. The magnetic core of the armature, which is in form of an isosceles triangular prism, is freely suspended on springs between the housing of the radiator and the base of the drive.

EFFECT: improved directional properties of the radiator.

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Description

The invention relates to technical means for exciting seismic waves in an non-explosive manner and can be used in field geophysical surveys using the multiwave seismic survey method.

A device is known for exciting longitudinal and transverse waves (RF patent No. 2053525, prior. July 21, 1992, IPC G01V 1/147), comprising a mast with guides, a falling load and an emitting platform. The platform is equipped with an intermediate plate, horizontally arranged inert masses, vertically arranged permanent magnets, horizontally and vertically arranged induction coils symmetrically with respect to the vertical axis of the platform, and the coils are rigidly fixed to the platform and form vertical and horizontal cups with its walls, permanent magnets are rigidly fixed to the intermediate plate resting on the platform through vertically arranged elastic elements and form a horseshoe-shaped magnet a reactive system, each pole tip of which is included in the corresponding vertical cup, inert masses are placed in horizontal cups between horizontally located elastic elements, pairs of vertically arranged induction coils are interconnected in series, and induction coils making up horizontal cups are interconnected in pairs, and each pair is connected through a switch to a chain of vertically arranged induction coils.

The disadvantages of the described device are large dimensions, because To excite seismic waves, a load falling from a certain height is used, as well as the fact that the device undergoes multiple conversion of energy from one type to another, which leads to its unjustified losses. To excite transverse seismic waves, the potential energy of the incident load is converted into the electromotive force of the induction coils and then into the potential energy of the springs. At each stage of the conversion, losses of stored energy occur.

A device is known for exciting transverse seismic waves (RF patent No. 2419818, prior. October 26, 2009, IPC G01V 1/02), comprising a frame, a rigid base plate, a power circuit and two electrodynamic pulse emitters. The rigid base plate is made in the form of an isosceles triangular prism with angles at the base of 45 ° and lugs mounted on the base of the plate, and electrodynamic pulsed emitters are installed on opposite sides of the rigid base plate at an angle of 45 ° to the base of the plate and are powered from the power supply circuit with the possibility work one at a time. The installation of emitters at an angle of 45 ° to the base of the base plate and the presence of lugs fixed to the base of the plate make it possible to excite packets of longitudinal and transverse seismic waves in the soil.

The disadvantage of the described device is that the excitation of multidirectional seismic waves is carried out by two separate pulse emitters, each of which, in addition to the working element, has its own body and its own inertial mass. This circumstance increases the total mass of the device, increases its cost and complicates the design.

The closest analogue to the present invention is a device for exciting seismic vibrations (copyright certificate SU No. 1539703 A1, prior. 01.10.87, IPC G01V 1/04) containing an electrodynamic emitter connected to a current source and mounted on a radiating platform with lugs, and a device for pressing the radiating platform to the ground, including an intermediate plate pivotally connected to the power hydraulic cylinder of the vehicle. A wedge recess is made on the radiating platform from the side of the pressure plate, formed by two planes equally inclined to the radiating platform, on the walls of which electrodynamic radiators are installed, coupled with dampers in the form of wedges on which the intermediate plate is supported. Dampers are not rigidly connected to the base plate. This device design allows you to excite in the ground packets of multidirectional transverse seismic waves.

The disadvantage of the described device is the low shear wave excitation efficiency, since only a working wedge damper that lifts the intermediate plate up effectively and the wedge damper adjacent to the working wedge (since the wedge dampers are not rigidly connected to the intermediate plate) transfers part of the feedback to the emitting platform . This generates shear stresses in the soil opposite to the original sign and sharply reduces the directional properties of the emitter. In addition, the described device operates with a load (in the device, its role is played by the vehicle).

The purpose of the invention is the creation of a simple, easy-to-use emitter of seismic waves, the design of which eliminates the possibility of repeated impact on the ground, working without a load, realizing the possibility of obtaining seismograms of pair effects at each point of excitation, effectively using the mass of all its components for radiation of transverse seismic waves in which the possibility of transferring part of the feedback to the emitting platform is minimized. The emitter can be made in a small-sized portable version and used effectively for multiwave seismic exploration of the upper part of the geological section.

The goal is achieved in that the transverse seismic wave emitter containing the emitting platform with lugs, the housing, the armature and the electromagnetic drive, rigidly mounted on the emitting platform with lugs, has the original design of the electromagnetic drive and the armature. An electromagnetic drive consisting of a base and two inductors, which are solenoids with cores of soft magnetic material, has a recess in the form of an isosceles triangular prism with an angle between the planes of 90 ° and an angle of inclination of each of the planes to the radiating platform of 45 ° in the upper part of the base. Inductors are located in the grooves of the planes. The emitter armature made of soft magnetic material has the shape of an isosceles triangular prism, the dimensions of which correspond to the dimensions of the recess of the drive base. In the working position, the anchor is freely suspended on two rows of conical springs between the emitter body and the drive base, with gaps, the size of which is set during adjustment, depending on the required characteristics of the emitter. In the transport position, the anchor is pressed by latches fixed on the housing to the base of the drive. The inductors of the electromagnetic drive are powered alternately from the power supply circuit. With this design of the emitter, there is no need to move it on the ground to obtain pair effects at each recording point of the seismogram, which, during subsequent processing, allows to extract either longitudinal or transverse waves from the mixed seismic wave field, thereby significantly increasing the efficiency of seismic exploration and the reliability of the information received . At the same time, the design of the emitter eliminates the possibility of repeated impact on the emitting platform at the time of the return of the armature to its original position.

The drawing shows a longitudinal section of the emitter.

The transverse seismic wave emitter consists of a radiating platform 1 with lugs 2, housing 3, electromagnetic drive 4 and anchor 6.

An electromagnetic drive, rigidly mounted on a radiating platform, consists of a base 8 and two inductors 5, which are solenoids with cores of soft magnetic material. The base of the drive 8 in its upper part has a recess in the form of an isosceles triangular prism with an angle between the planes of 90 ° and an angle of inclination of each of the planes to the radiating platform 45 °. In the grooves of the planes of the recess placed inductors 5.

An anchor 6 made of soft magnetic material in the form of an isosceles triangular prism, the dimensions of which correspond to the dimensions of the recess of the drive base 8, in the transport position without gaps is fixed in the recess of the drive base, and in the working position it is freely suspended on two rows of conical springs between the drive base 8 and the housing 3.

The emitter operates as follows.

In the transport position, the emitter armature 6 is secured to the recess at the base of the electromagnetic actuator 8 using clamps fixed to the housing 3 (not shown in the drawing). In this case, the springs 7 of the upper row are stretched and the lower ones are compressed.

When translating the emitter from the transport position to the working position, the latches release the anchor and the anchor under the action of springs is installed in the center of the emitter in a freely suspended state. In this case, between the armature 6 and other functional units of the emitter (housing 3 and the base of the actuator 8), gaps are formed, the values of which are established in the process of adjustment depending on the required characteristics of the emitter (effective conversion of electrical energy into seismic wave energy and the absence of repeated impact on the ground) . As a rule, for the efficient operation of the emitter with an electromagnetic drive, the gaps do not exceed 20 mm.

The signal from the seismic station from the power source through one of the inductors 5 of the electromagnetic actuator 4 passes a current pulse of a given value and duration. When the pulse current passes through the inductor 5, electric energy is converted into the magnetic field energy of the coil with current, as a result of which the anchor is attracted to the recess plane of the drive base, in the groove of which the inductor is located, overcoming the counteraction of the springs 7 working in tension and bending. At the moment of contact of the planes of the armature 6 and the base of the actuator 8, a shock pulse is generated, under the influence of which the base of the actuator 8, together with the radiating platform 1 and the lugs 2, starts accelerated movement relative to the ground in a direction perpendicular to the plane of the recess of the base of the actuator 8. Since the inductors 5 are located in the grooves of the excavation planes of the drive base 8, the force pulse is decomposed into the normal and tangential components, acting on the soil through the surface of the radiating platform 1 and the lug 2. These forces cause the appearance of compressive and tangential stresses, which are the cause of the appearance of longitudinal and transverse seismic waves.

At the same time, a reactive force arises, which, combined with the compression force of the previously extended springs, acts on the armature 6, forcing it to move along the normal to the recess plane of the base of the actuator 8 in the opposite direction. When the armature moves in the opposite direction, it passes through its initial position, after which the springs begin to work in tension and damped oscillations of the armature arise around the initial position. After a certain time, the oscillations cease and the anchor is set to its original position.

The characteristics of the springs, the parameters of the current pulse, the mass of the armature and the base of the drive, the gaps between the armature and other structural elements of the emitter are selected in such a way that the most efficient conversion of electrical energy into the energy of seismic waves and damped oscillations of the armature do not lead to repeated shocks and, as a result to spurious seismic waves.

The design of the emitter uses conical springs, which have high resistance to lateral bending. In addition, for conical springs, the height of the spring in the compressed state is minimal, since with maximum compression, the turns go into one another. These properties of the conical springs facilitate the fixation of the armature in the recess of the drive base in the transport position and optimize the armature operation when the pulse current passes through the inductor.

After completion of the cycle, the same current pulse is applied to the second counter-tilted inductor of the electromagnetic drive to excite transverse seismic waves in the opposite direction. The principle of operation of the emitter in this case is similar to that described.

When processing seismograms of pair effects, by methods of their summation and subtraction, records of either longitudinal or transverse waves are extracted from the mixed seismic wave field, which are used to study the geological section.

Thus, the use of the described emitter makes it possible to ensure high productivity of seismic surveys during multiwave seismic exploration, including the upper part of the geological section by small-sized portable emitters without a load. There is no repeated impact on the ground.

Claims (1)

A transverse seismic wave emitter comprising a radiating platform with lugs, a housing, an armature and an electromagnetic drive rigidly mounted on the radiating platform, consisting of a base and two inductors, which are solenoids with cores of soft magnetic material, characterized the fact that, in order to exclude the possibility of repeated impact on the ground, obtaining seismograms of pair effects at each point of excitation, optimal use of the mass of structural elements for emitting seismic waves and improving the directional properties of the emitter, a notch in the form of an isosceles triangular prism is made in the upper part of the drive base with an angle between the planes of 90 ° and an angle of inclination of each of the planes to the radiating platform 45 °, in the grooves of the planes of which are placed the inductors, and the armature emits I made of soft magnetic material in the form of an isosceles triangular prism whose dimensions correspond to the dimensions of the recess actuator base, in the operating position is freely suspended on two rows of conical springs between the emitter housing and the actuator base.