RU2475778C1 - Pulsed ground-based non-explosive seismic vibrator - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: seismic vibrator has an antenna board, a tightening weight supported by the antenna board and a pulse motor which generates force between the board and the tightening weight. The seismic vibrator also has a damper whose rod is supported by the tightening weight. Between the chassis of the damper and the board there is an elastic member which reduces repeated shocks on the board generated by the tightening weight and dynamic loads on the damper. The elastic element can be in form of a compression spring.

EFFECT: high efficiency operation of the seismic vibrator.

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Description

The invention relates to pulsed ground-based seismic sources of non-explosive type used in seismic surveys.

Known pulsed non-explosive seismic source (Ivashin V.V., Ivannikov N.A. Pulse electromagnetic seismic sources: features and prospects for improvement. Magazine: "Instruments and systems for exploration geophysics" No. 2, 2005, pp. 9-13). The source contains a rigid radiating plate, a load supported on it (inertial mass) and one or more dampers installed between the load and the radiating plate.

The electromagnetic motor creates a pulsed force between the load and the plate, as a result of which the plate moves in the direction of the soil and deforms it, which causes the creation of a seismic wave in the soil. During the action of the pulsed force, the load accelerates upward and then together with the armature inertia moves upward to a certain height. The speed of moving the load from the upper position to the initial position on the plate is limited by one or more dampers fixed to the plate, which reduces the intensity of the impact of the anchor on the plate racks and the load on the emitter plate and weakens the noise waves created by the seismic source.

The hydraulic dampers used in seismic sources are made in the form of a cylinder-filled body filled with liquid, attached to a plate, the piston of which is made with a bypass valve device and is equipped with a rod for mechanical connection with the load. When the load moves upward, the piston with the rod moves behind the load. In this case, the bypass valve is open, and the liquid through the open valve flows from the cavity above the piston into the cylinder cavity under the piston. When the load is moved down, the valve device provides an increase in hydraulic resistance to fluid flow in the opposite direction.

A drawback of the design of a seismic source with a hydraulic damper, the casing of which is fixed to the emitter plate, is that large alternating loads are transmitted to the damper body when the plate moves, which reduces the reliability of the damper and leads to failures in the operation of the seismic source itself .

The technical solution of a seismic source containing a rigid radiating plate, a load supported on it and installed between the load and the plate is known for the prototype (RF Patent No. 2369883. BI No. 28, 2009). It uses an induction-dynamic type engine that creates a pulsed force between the load and the plate. The field coil of the motor is placed on the side of the plate facing the load, and the motor armature is made in the form of a plate of high conductivity material placed on the load. When a current pulse is passed through the excitation winding, a repulsive force is created between the excitation coil and the armature plate in which the current is induced. As a result, the radiating plate with the field coil is displaced in the direction of the soil, the soil is deformed by the plate and a seismic wave is created. The load with the armature plate accelerates upward and moves to a certain height in the field of gravity. The movement of the load from the upper position down is inhibited by a one-way hydraulic damper in order to reduce the impact interaction of the load with the plate and to reduce the intensity of the interference waves generated in this case.

In seismic sources with an induction-dynamic motor, a higher ratio of the generated force to the mass of the emitter plate is achieved with a lower ratio of the weight of the seismic source to the magnitude of the generated force, which allows to increase the technical and operational characteristics and expand the scope of the seismic sources, use them, for example, in the study of the zone low speeds and seismic surveys in difficult to reach natural conditions (mountainous terrain, water-land transitional zones, with engineering seismic exploration, etc.).

During the operation of such a seismic source, significant mechanical loads are created between the plate and the damper body, which reduce the reliability of the seismic source. With rigid mechanical fastening of the damper body to the plate, it moves with the plate with acceleration hundreds of times greater than the acceleration of gravity. If the damper body rests on the plate, when moving the plate down in the direction of soil deformation, a gap is formed between the damper body and the plate. The return of the plate to its original position is accompanied by the choice of this gap and an impact between the plate and the damper body, which leads to disruption of the damper and the seismic source as a whole. The shock also causes significant sound waves hindering the operation of the seismic source.

The problem to which the invention is directed, is to increase the durability of the seismic source and improve its operating conditions.

The technical result is to reduce dynamic mechanical loads on the damper.

The mentioned task is achieved in that the seismic source contains a rigid radiating plate-antenna, on which the load is supported, a hydraulic damper and a pulse motor, for example, an induction-dynamic type, installed with the possibility of applying force between the load and the antenna plate, characterized in that between the body said damper and a plate-antenna placed an elastic element made, for example, in the form of a compression spring, and the damper rod is connected to the load, for example, is supported on it.

Obtaining a technical result is achieved by eliminating the rigid mechanical connection between the damper body and the plate-antenna moving with great acceleration by placing an elastic element between them. With this solution, mechanical alternating dynamic loads between the plate and the damper body are reduced, which are transmitted to the liquid inside the damper and its piston with a valve device, which increases the reliability of the damper and the seismic source as a whole, and also reduces the acoustic noise generated by the seismic source and the seismic noise generated by the seismic source .

The device is illustrated by drawings. Figure 1 shows a section of a seismic source with a pulsed induction-dynamic type motor, the field coil of which is fixed on the side of the sink facing the plate, and the anchor is placed on the surface of the radiating antenna plate facing the sink.

Figure 2 shows a section of a possible technical solution of the seismic source, in which the coil of the field winding of the motor is placed on the plate-antenna, and the anchor on the surface of the weights facing the plate.

Figure 3 shows explaining the operation of the seismic source graphs of changes in engine power and speed of movement of the plate-antenna and load.

The seismic source (Fig. 1) consists of a rigid radiating plate 1 mounted on the soil 2. The plate is equipped with a guide rack 3. An induction-dynamic motor armature is fixed on the top surface of the plate 1, made in the form of a ring 4 of electrically conductive material. Above the base 1 there is a plate 5 made of electrical insulating material, in a groove on the side facing the plate 1 of which is placed a coil 6 of the motor excitation winding. A current pulse generator 7 is connected to the terminals of coil 6. An inertial mass 8 is fastened to plate 5, which, together with plate 5 and the coil 6 of the field winding, makes up the load 9 of the seismic source. Inside the guide strut-pipe placed a one-way hydraulic damper 10, the rod 11 of which is supported by the load 9. Between the housing 12 of the damper 10 and the plate 1 is placed a spring 13.

The seismic source works as follows. At time t ₀ (Fig. 3), a current pulse 14 is passed through the winding 6 from the current pulse generator 7. In this case, a pulse of force 15 is generated between the winding 6 and the conductive ring 4 of the armature of the induction-dynamic motor, upward, and on ring 4 and plate 1 - down. During time t ₀ -t _{1, the} action of force 15 of the armature ring, together with the rigid plate 1, accelerates in the direction of the soil 2 and deforms it with a speed of 16.

By the time t _{1, the} force 15 decreases to zero. Accelerated to a maximum value of speed 16, plate 1 continues to compress the soil by inertia (curve 17). By the time t _{2, the} speed of the 16 plate under the action of the elastic forces of the soil decreases to zero, and the soil receives a maximum strain value of 17. At the time interval t ₂ -t ₃ , the soil is unloaded, accompanied by the acceleration of the plate 1 up. Next, the damping process of oscillations of the plate 1 on the soil 2 continues, the frequency of which is determined by the mass of the plate 1 with the anchor 4 and the elasticity of the soil. Typically, this frequency for soils of different hardness is in the region of several tens of hertz and increases with decreasing mass of the radiating plate 1.

The highest value of the rate of soil deformation by the slab at non-explosive type sources usually does not exceed 1-2 m / s. The maximum acceleration of the plate depends on the force and mass of the plate acting on it and reaches values of 500-1000 m / s ² or more.

When the plate 1 is shifted down by the amount of deformation 17 of the soil, the spring 13 placed between the body 12 and the plate 1 is unclenched, and when the soil 2 is unloaded and the plate 1 moves upward at a speed of 16, it is compressed, which reduces mechanical alternating effects on the damper body 12 and provides an increase reliability and durability of its work.

In known technical solutions, the spring 13 is not used, and the damper housing 12 is either rigidly attached to the plate 1, or can be supported on it. When the damper with the plate is rigidly mounted, the force acts on its body, determined by its mass and acceleration of plate 1. If the damper body is supported on the plate, then when the plate is shifted down (time interval t ₀ -t ₂ ), a gap is formed between the body and the radiating plate. The return of the plate to its original position at time t _{3 is} accompanied by the selection of this gap and the shock interaction of the housing with the plate at time t ₃ with a significant value of speed 16 of the plate 1, violating the normal operation of the damper. The impact process is accompanied by the generation of acoustic noise, which worsens the operating conditions of the seismic source.

The load 9 with the excitation winding 6 on the time interval t ₀ -t _{1 of the} action of the motor force 15 on it is accelerated upward (curve 18) and moves along the guide post 3. Since the mass of the load with the excitation winding is much larger than the mass of the plate 1 with the armature plate 6 , then at the indicated interval it receives a speed of 18 much less than the speed of 16 plate 1. At time t greater than t _1, load 9, accelerating in the time interval t ₀ -t ₁ to a certain speed of 18, moves up in the field of gravity to a height of H _p . Moreover, its speed decreases to zero (time t ₄ ). Subsequently, its movement to the initial position on the plate is slowed down by the damper 10. At the beginning of the movement h _{p of the} load from the upper down position, the damper does not significantly resist the movement of the rod with the piston, which is caused by the switching of the damper valve device to the braking mode. By time t ₅ , corresponding to the movement of h _p rod, the damper valve device is closed. In this case, the spring 13 reduces the pulsed force effect of the load through the damper on the emitting plate 1 and the intensity of the seismic jamming waves generated by the plate.

The use of the stand 3 on the plate 1 allows the movement of the load 8 along the stand 3 with both horizontal and non-horizontal position of the plate on the ground (with an inclination angle of 30-35 degrees) of the seismic source to the horizon. Placed between the housing 12 of the damper and the plate 1 with the guide rack 3, the elastic element 13 can be made in the form of a plate of elastic material.

In order to reduce the weight of the seismic source and increase the coefficient of conversion of the mechanical energy of the engine to the energy of the mechanical action of the stove on the ground, the stove 1 (Fig. 1) can be made of a honeycomb structure of high strength material with the smallest possible specific gravity, for example, an aluminum alloy, or composite material (plastic )

In the embodiment of the seismic source shown in FIG. 2, the induction-dynamic type motor, as in the construction solution of FIG. 1, develops a pulsed force between the load 8 and the radiating plate 20. A feature of this solution is the placement of the field coil 6 of the motor in the grooves the emitter plate 20, which should be made of electrical insulating non-magnetic material. In this case, the motor armature 4 from the high-conductivity material is fixed on the surface of the load 8 facing the plate 20. The movement 17 of the emitter plate 1 in Fig. 1 and the emitter plate 20 in Fig. 2 is significantly (10 - 20 times) less than the maximum value H _n movement 19 of the load. In this regard, the constructive solution of FIG. 1 is promising for portable type seismic sources developing forces of up to 5-10 · 10 ⁴ H, in which the current pulse generator containing storage capacitors with a charging device and power switching devices, it is advisable to place on the load. In seismic sources of increased power for efforts of 20 · 10 ⁴ H or more, it may be preferable to use the technical solution of figure 2, in which the coil of the field winding 6 of the motor is placed on the plate 20.

The proposed technical solution for a seismic source with an induction-dynamic type engine is used in the development of a portable seismic source, which with a weight of ≈60 kg creates a pulsed force on the radiating plate of up to 5 · 10 ⁴ H. The source is designed to study the zone of low speeds, including those difficult to reach vehicle areas (highlands, marshy areas, etc.).

A variation of the proposed technical solution (Fig. 2) is used in the development of a pulsed seismic source with an induction-dynamic motor, which with a mass of ≈300 kg creates forces on the radiating plate of up to 20 · 10 ⁴ H.

Both sources were successfully tested in seismic batches.

Claims (1)

A pulsed non-explosive ground seismic source containing a rigid radiating plate-antenna, a load supported on it, a pulse motor installed with the possibility of applying the force it creates between the load and the radiating plate, and a one-way damper whose rod is supported by the load, characterized in that between the damper body and a plate placed an elastic element made, for example, in the form of a compression spring.

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