RU2753806C1 - Borehole seismic source - Google Patents

Abstract

FIELD: vibroseismic technology.

SUBSTANCE: invention relates to vibroseismic technology and can be used to increase reservoir recovery of oil and gas fields by generating and transmitting seismic vibrations to oil-containing reservoirs, as well as for seismic exploration of the earth interior. A borehole seismic source is claimed, in which each of the power devices is made in the form of an elastic chamber with an oil-filled cavity located in the body of the power device. Moreover, the elastic chamber is connected along the outer surface with orthogonally movable wedges and punches, on which there are pads mounted in the holes of the housing with the possibility of radial movement. Moreover, the plunger is connected to an elastic chamber, and the device is equipped with a converter with an elastic diaphragm designed to separate oil-filled cavities connected by pipes from the elastic chambers of the upper and lower power devices.

EFFECT: creation of a device that allows the compatibility of the operation of a borehole seismic source with the technology of oil reservoir flooding.

1 cl, 3 dwg

Description

The proposed invention relates to vibroseismic technology and can be used to enhance oil recovery of oil and gas fields by generating and transmitting seismic vibrations to oil-containing formations, as well as for seismic exploration of the earth's interior.

In the domestic and foreign practice of oil production and geo-exploration, a theoretically and practically grounded idea of the effectiveness of the use of pulse-wave technologies for influencing depleted, high-watered oil reservoirs for intensifying oil production has been formed.

A device for wave action on a deposit is known, including a load for striking, a lifting mechanism associated with a load of a traverse with gripping elements and a breaker fastened to the well (ed. St. USSR No. 1710709, class E21B 43/25, 1992) ...

The weight for striking is made in the form of drill pipes filled with a weighted liquid, interconnected by couplings with through channels, having a fishing head in the upper part, and a drain valve and a blank in the lower part.

The interrupter is made in the form of a glass with clamps on the inner perimeter mounted on the fishing head with the possibility of interaction with clamps with gripping elements and fastened with cables to the well.

The gripping elements are made with a groove for the lock and with inclined working surfaces for turning the gripping elements under the action of the gravity of the load.

The disadvantages of the known device are the complexity of the design and the large dynamic loads that the parts experience when hitting, reduce the durability of the device. This is especially true for couplings that connect drill pipes with threaded connections.

The device cannot be used to force the walls of the well, oriented mainly normally to the reservoir. This is the reason for its relatively low efficiency.

A device for wave action on a deposit containing a power element in the form of a hydraulic cylinder with a variable diameter, equipped with a plunger interacting with the mechanism of its reciprocating movement along the axis of the hydraulic cylinder and a control system is known (RF patent No. 2452853, class Е21В 43/25, 2010 ).

The known device, as part of the moving part of the reciprocating movement mechanism, rope, cargo with a hydraulic cylinder plunger with a variable diameter, is a complex multi-mass system with shock-dissipative connections in the form of a rope, elastic suspension and working fluid inside the hydraulic cylinder.

The device has a number of significant disadvantages, namely:

- low operational reliability;

- complex tuning to the optimum required vibration mode resonant to the frequency of natural elastic vibrations of the rock mass adjacent to the borehole walls;

- high metal consumption and cost of installation and operation.

The closest in technical essence to the proposed solution is a borehole seismic source containing power devices in the form of hydraulic cylinders equipped with plungers with a variable diameter, between which, coaxially to the plungers, a double-acting electromagnetic hammer with poles and coils of forward and reverse motion, placed in the diamagnetic guide of the striker, is mounted coaxially to the plungers, interacting with its ends with the plungers of the hydraulic cylinders of power devices, and the cavities of the electromagnetic hammer on the side of the upper and lower ends of the striker are evacuated, and on the outer surfaces of the body of the electromagnetic hammer and hydraulic cylinders, longitudinal grooves are made to accommodate communication wires of the power supply of the electromagnetic hammer coils and its control system ( RF patent No. 2642199, class Е21В 43/25, 2018).

The known device has a number of significant disadvantages, namely:

- the presence of a borehole hydraulic drive of power devices, which implies installation in each device in addition to a hydraulic cylinder with a variable diameter supplying it to a hydraulic pump with an oil tank and control elements, which significantly complicates the design and reduces the operational reliability of the seismic source;

- the execution of power devices in the form of hydraulic cylinders with a variable diameter, adjacent to the walls of the casing along the entire surface, makes it impossible to circulate fluid past the seismic source and contradicts the technology of well operation;

- the presence of a stagnant environment around the electromagnetic hammer leads to intense heating and a reduction in the time of actual vibration action due to a decrease in PV.

The technical result solved by the invention is the creation of a device that allows the compatibility of the operation of a borehole seismic source with the technology of watering an oil reservoir.

The technical result in the proposed invention is achieved by creating a borehole seismic source containing power devices with plungers, between which a double-acting electromagnetic hammer is mounted in a one-piece housing with coils of forward and reverse striker travel, poles, inductive position sensors of the striker on the diamagnetic guide of the striker, which has the upper and lower ends interacts with the plungers of the power devices, and the cavities of the electromagnetic hammer are evacuated, and on the outer surface of the power devices and the body of the electromagnetic hammer there is a cable intended for connecting the hammer with a power and control unit located on the surface, in which, according to the invention, each of the upper and lower power devices are made in the form of an elastic chamber with an oil-filled cavity located in the body of the power device, and the elastic chamber is connected along the outer surface with orthogonally movable wedges, and punches interacting with return springs, and on the punches there are pads mounted in the openings of the body with the possibility of radial movement, while the plunger is connected to the elastic chamber, and the seismic source is equipped with a transducer with an elastic diaphragm designed to separate the oil-filled cavities connected by the branch pipes of the elastic chambers of the upper and lower power devices which is attached to the top of the oil-filled cable gland fixed to the upper power device body.

The proposed borehole seismic source allows to increase the duration of switching on the electromagnetic hammer up to continuous operation, due to continuous cooling of the body.

The essence of the invention is illustrated by the following description of the structure and drawings, where:

- in Fig. 1 shows a downhole seismic source in a well casing for watering an oil reservoir;

- in Fig. 2 - section A-A, in Fig. 1;

- in Fig. 3 - view B, in figure 2.

The borehole seismic source contains an electromagnetic hammer and power devices connected coaxially to its lower and upper ends.

The electromagnetic hammer includes a cylindrical body 1, a striker 2 in a diamagnetic guide 3, a forward coil 4 and a reverse coil 5 of striker 2, poles 6, 7, 8, 9 and inductive sensors 10, 11 of the striker position.

The lower and upper ends of the housing 1 are rigidly attached to their bodies 12, respectively, the lower 13 and upper 14 power devices, identical in design.

Each of the power devices contains an elastic chamber 15 with an oil-filled cavity, hermetically fixed inside the power devices by nipples 16, 17 and connected along the outer surface with orthogonally movable wedges 18 and punches 19 (see Fig. 2), interacting with the return springs 20.

A pad 21 is rigidly attached to each punch 19 (according to Figs. 2, 3), for example, by a bolt connection 22.

The pads 21 are provided with a notch 23 on the surface facing the inner surface of the casing 24 with perforations 25.

The pads 21 are installed with the possibility of radial movement in the holes 26 of the bodies 12.

An oil-filled cable gland 27 is fixed to the body 12 of the upper power device 14.

Through the cable gland 27 from the power supply and control unit 28 (hereinafter referred to as BPU 28) located on the surface, the cable 29 inside the borehole seismic source is hermetically sealed with power wires to power the coil 4 of the forward stroke and the coil 5 of the reverse stroke of the striker 2 of the electromagnetic hammer, as well as the control wires to the position sensors 10, 11.

A transducer 30 is connected to the upper part of the cable gland and is connected to a set of tubing 31 (hereinafter referred to as tubing 31).

The transducer 30 has an oil-filled cavity "P", separated from the tubing 31 by an elastic diaphragm 32.

The cavity "P" of the transducer 30 is communicated through the nozzle 33 and the nipple 16 with the elastic chamber 15 of the upper power device 14 and through the nozzle 34 mounted along the outer surface of the borehole seismic source (according to Fig. 2, 3) and the nipple 16 with the elastic chamber 15 of the lower power device 13.

In the nipples 17 of each of the power devices 13 and 14, plungers 35 and 36 are hermetically mounted, respectively, provided with collars 37 and return springs 38 each.

The casing 24 is hermetically sealed by the wellhead assembly 39, through which the pipeline 40 with the valve 41 communicates with the water pump 41 of the flooding system.

Having become tubing 31, hermetically sealed at the top, it is connected to a high-pressure water pump 43 (hereinafter referred to as pump 43) by a pressure line 44 containing a shut-off valve 45.

The pressure line 44 is connected to the low pressure line 47 by means of a controlled safety valve 46.

The device operates as follows:

The borehole seismic source is launched by turning on the pump 43. At the same time, it fills the tubing 31 with water.

The hydrostatic pressure of the liquid column deforms the diaphragm 32 of the transducer 30, imparting equal pressure to the oil in the cavity "P".

From the cavity "P" through the pipes 33, 34, the oil enters the elastic chambers 15, which, expanding, act on the wedges 18 and punches 19.

The punches 19, overcoming the elastic force of the return springs 20, are pushed as far as the stop by the linings 21 into the casing 24 above the perforations 25.

The pads 21 form a static thrust force acting on the casing 24 in direct proportion to the pressure of the water column in the tubing 31.

After filling the tubing 31 with water, the pump 43 creates an excess pressure in the pressure line 44, the value of which is limited by the setting of the safety valve 46, which transfers the excess flow to the low pressure line 47.

Then the electromagnetic hammer is turned on. The voltage from the BPU 28 is supplied to the reverse coil 5.

Under the action of the electromagnetic force, the striker 2 accelerates upward along the diamagnetic guide 3. When the upper end of the striker 2 reaches the level of the inductive sensor 11, the latter generates a signal in the BPU 28, through which the reverse coil 5 is turned off and the forward coil 4 is turned on.

Striker 2, moving by inertia, strikes the plunger 36 of the upper power device 14. Penetrating into the elastic chamber 15, the plunger 36 creates a hydraulic pressure impulse in it.

The specified impulse is transmitted through wedges 18, punches 19, pads 21 in the form of a thrust force impulse on the casing 24, from which the seismic wave propagates into the oil reservoir.

After that, the plunger 36, under the influence of the elastic force of the return spring 38, returns to the stop with the collar 37 into the nipple 17, and the firing pin 2 under the action of gravity and the electromagnetic force of the coil 4 accelerates downward.

After some time, the lower end of the striker 2 reaches the level of the inductive sensor 10, at the signal of which the BPU 28 turns off the coil 4 and turns on the coil 5.

Meanwhile, the inertial firing pin 2 strikes the plunger 34 of the lower force device 13, which, working similarly to the upper force device 14, emits a seismic wave into the oil formation.

Then the working cycle is repeated.

Simultaneously with the operation of the borehole seismic source through the wellhead assembly 39 and the valve 41 by the pump 42, the procedure for watering the oil reservoir along the annular space of the well is carried out. In this case, the flow of water, moving to the perforations 25, continuously washes the housing 1.

From the above description, it follows that the presence of a transducer 30 with an elastic diaphragm 32, tubing 31, a pressure line 44, a pump 43 and a controlled safety valve 46 makes it possible to create a static thrust force of the upper 14 and lower 13 power devices.

At the same time, by adjusting the safety valve, the pressure of the water column in the tubing 31 is changed.

Thus, they provide a structurally simple and reliable technology for creating and regulating in a wide range of spacer forces of power devices 13, 14.

The presence of retractable pads 21 guarantees a gap between the bodies 12 and the casing 24, through which water can be pumped into the oil reservoir by the pump 42 along the annulus of the well.

In this case, the flow of water, washing the body 1, contributes to its cooling and an increase in the duration of the activation of the electromagnetic hammer up to continuous operation.

Thus, the compatibility of the operation of the borehole seismic source with the technology of watering an oil reservoir and an increase in the efficiency of vibration treatment by increasing the time of actual vibration exposure are ensured.

Claims (1)

A borehole seismic source containing power devices with plungers, between which a double-acting electromagnetic hammer with forward and reverse striker coils, poles, inductive striker position sensors on the striker's diamagnetic guide is mounted in a one-piece housing, which interacts with the power devices plungers with the upper and lower ends, and the cavities of the electromagnetic hammer are evacuated, and on the outer surface of the power devices and the body of the electromagnetic hammer there is a cable designed to connect the hammer with the power supply and control unit located on the surface, characterized in that each of the upper and lower power devices is made in the form of a power devices of an elastic chamber with an oil-filled cavity, and the elastic chamber is connected along the outer surface with orthogonally movable wedges and punches interacting with return springs, and on the punches there are pads mounted in openings of the housing with the possibility of radial movement, while the plunger is connected to the elastic chamber, and the seismic source is equipped with a transducer with an elastic diaphragm designed to separate the oil-filled cavities connected by the branch pipes of the elastic chambers of the upper and lower power devices, which is connected to the upper part of the oil-filled cable gland fixed to the body of the upper power device.

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