RU2753805C1 - 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-saturated reservoirs through a borehole, as well as for interhole sounding during seismic exploration of the earth interior. A borehole seismic source is claimed, in which, according to the invention, each power device is equipped with an oil cavity, which is connected to its additional oil volume located in the housing, in which heating elements are installed, connected in parallel and connected to the power and control system, and the firing pin is placed in a guide with a gap.EFFECT: provision of vibroseismic impact directly on the oil reservoir, regardless of the depth of its occurrence, with higher reliability.1 cl, 3 dwg

Description

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

In the domestic and foreign practice of oil production, a large positive experience has been accumulated in the use of seismoacoustic effects on depleted, highly watered oil reservoirs to increase oil recovery and intensify oil production.

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 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 forcefully impact the walls of a well oriented normally to a deposit. This is the reason for its relatively low efficiency.

A device for wave action on a deposit is known, 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 (RF patent No. 2452853, class E21B 43/25, 2010 G.)

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 two power devices in the form of hydraulic cylinders equipped with variable diameter plungers, between which, coaxially to the plungers, a double-action electromagnetic hammer with poles and coils of forward and reverse motion, position sensors located in the diamagnetic guide of the striker, interacting with its ends with the plungers of the hydraulic cylinders of the power devices, moreover, 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 there are longitudinal grooves to accommodate the wires of communications of the power supply of the coils of the electromagnetic hammer , (RF patent No. 2642199, according to class Е21В 43/25, 2018).

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

- the presence in each of the power devices of a borehole hydraulic pump with a hydraulic or electromechanical drive, which implies installation in each device, in addition to a hydraulic cylinder with a variable diameter, a hydraulic pump feeding it with a drive, which significantly complicates the design and reduces the operational reliability of the seismic source;

- the presence of evacuated cavities in the diamagnetic guide, along which the striker moves from the side of the upper and lower ends of the striker, interacting with their ends with the plungers of the hydraulic cylinders of the power devices is very difficult technologically;

- complete evacuation of these cavities in the guide leads to the lack of cooling of the striker, which can lead to overheating of the vibration source, a decrease in the time of its continuous operation and, ultimately, its failure.

The technical result achieved by the present invention is the creation of a borehole seismic source, which makes it possible to obtain vibroseismic action directly on the oil reservoir, regardless of the depth of its occurrence, with higher reliability,

The technical result in the proposed invention is achieved by creating a borehole seismic source containing two power devices made in the form of hydraulic cylinders equipped with a variable diameter with plungers, between which, coaxially to the plungers, an electromagnetic double-action hammer with poles and coils of forward and reverse motion, position sensors located in the diamagnetic guide of the striker, interacting with its ends with the plungers of the hydraulic cylinders of the 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 there are longitudinal grooves designed to accommodate communication wires of the power supply of the coils and sensors for the position of the striker of the electromagnetic hammer, and its power supply and control system, in which, according to the invention, each power device is provided with an oil cavity, which is connected with its additional oil volume, located in the housing, in which the heating elements are installed, connected in parallel and connected to the power and control system, and the firing pin is placed in the guide with a gap.

The proposed borehole seismic source provides equality of impulses of the striker impact on the plungers of the upper and lower power devices.

Connecting heating elements of additional volumes to the power supply and control system provides the necessary heating and expansion of the oil in the power devices, and as a result, to increase their diameter and press against the walls of the casing of the well.

Installing the striker in the guide with a gap allows vacuuming of the cavities from the side of the upper and lower ends of the hammer striker through the guide and the body in the gap between the hammer coils.

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

- in Fig. 1 shows a borehole seismic source containing two power devices of cylinders with variable diameter and oil cavities in section;

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

- in Fig. 3 - power supply and control system of the borehole seismic source.

The borehole seismic source includes an electromagnetic hammer and power devices with a variable diameter connected coaxially to its lower and upper ends.

The electromagnetic hammer includes a one-piece cylindrical body 1, a striker 2, located in the body of the coil of forward 3 and reverse 4 strokes, poles 5, 6, 7, 8 and inductive sensors 9 and 10, rigidly mounted on a diamagnetic guide 11.

In this case, the guide 11 with the coils 3 of the forward and 4 reverse strokes of the striker 2, the poles 5,6,7,8 and the coils of inductive sensors 9 and 10 rigidly fixed on it, forms a single energy block of the hammer, fixed in the housing 1 by the spacer sleeves 12.

To the lower and upper ends of the housing 1 are connected, for example, power devices in the form of hydraulic cylinders 13 with a variable diameter for impulsive action through the walls of the casing (not shown in the drawing) on the oily rock.

Each hydraulic cylinder 13 contains a plunger 14 installed with the possibility of translational movement, which implements the drive of the hydraulic cylinder when interacting with the striker 2.

On the outer surfaces of the housing 1 of the electromagnetic hammer and a hydraulic cylinder 13 installed on top with a device for connecting to the tubing (tubing) 15, longitudinal grooves 16, 17 are made, designed to accommodate communication wires of the power supply of the electromagnetic hammer coils and sensors.

The supply wires 18 of the forward stroke coil 3 of the striker 2 are brought out through the pole 6, and the supply wires 19 of the reverse stroke coil 4 of the striker go through the pole 8 into the longitudinal grooves 16,17, respectively, and are further reduced to the collector 20 mounted in the upper hydraulic cylinder 13.

Likewise, through the poles 5, 8 and further through the grooves 16, 17 into the collector 20 leads 22 from the coil of the sensor 10 (see Fig. 2).

From the collector 20, the wires of the power supply lines of the coils and sensors are connected by means of a cable 23 to the power supply and control system 24

The oil cavities with which each hydraulic cylinder 13 is equipped is connected with additional oil volumes 25 in the housing 1, in which the heating elements 26 are installed. (H1, H2)

These volumes 25 are connected to the oil cavities of the hydraulic cylinders 13, which make it possible to cool the oil entering the cavities of the hydraulic cylinders and expanding in the volume 25 of the heating elements 26.

The heating elements 26, which are active resistors, are connected in parallel and connected in the control system 24 to the controlled rectifier 27 in parallel with the thyristors by the switch 28 (FIG. 3).

The power supply and control system of the seismic source according to figure 3 includes a thyristor switch 28 with thyristors 29, 30 (T _nx , T _ooh .)

In the circuit of the switch 28, electromagnetic coils 3 of the forward and reverse 4 strokes of the striker 2 are connected.

The switch 28 includes a damping unit consisting of a resistor 31 (R _r ,) capacitance 32 (C _r ), diodes 33, 34 (V _nx , V _ox ) and a switching capacitance 35 (C _to) .

The switch is powered by a controlled rectifier 27 connected to the AC mains.

Thyristors 29, 30, when switched on alternately, connect the electromagnetic coils 3 and 4 of the hammer with a controlled rectifier 27, which is connected to a pulse-phase control system 36.

Pulse-phase control system 36 serves for generating a control pulse entering the control electrodes of the thyristors controlled rectifier 27, providing different angles α _nx and α _oh thyristor rectifier regulation in which output SW 27 are realized different rectified DC voltages U _nx or U _ox, fed to the hammer reels 3 and 4, respectively. Due to this, it is possible to provide the traction force of the idle coil more than the thrust force of the operating stroke coil and provide the same energy of the striker when it strikes the plungers of the upper and lower power device.

Sensors 9 and 10 are connected to the input of the pulse-phase control system 36 through resistors 37, 38 and diodes 39, 40 (R ₁ , R ₂ and V ₁ , V ₂ ).

The same sensors are connected through resistors 37, 38 and diodes 41, 42 (V ₃ , V ₄ ) with the control electrodes of the thyristors 29, 30 of the thyristor switch 28.

Heaters 26 connected in parallel are connected to a controlled rectifier 27 through a ballast resistor 43 in parallel with a thyristor switch 28.

The inclusion of the electromagnetic coils into operation is carried out by applying a voltage pulse with the button 44 to the control electrode of the thyristor T _ox along the circuit 45 (R4-R3), 46, 47 (C1) - 48 (V5)

The device operates as follows:

Initially, voltage is applied to the controlled rectifier 27 in the system 24.

In this case, the coils of the hammer electromagnets are not _{turned on, since the thyristors T nx} , T _ox 29, 30 in the thyristor switch 28 are turned off.

However, the heating elements 26 are supplied with voltage through the ballast resistor 43. As a result, the oil heats up and expands in the volumes 25.

Expanding, the oil enters the oil cavities of the hydraulic cylinders 13, providing an increase in their diameter and pressing against the inner surface of the well casing. After that, using the P1 button, the thyristor 30 of the idle coil 4 is turned on.

The striker, under the influence of the electromagnetic forces of the coils, switched according to signals from position sensors 9, 10, reciprocates, striking at the end points of the rods of 14 hydraulic cylinders 13.

In this case, a seismic signal is emitted through the casing into the formation.

The diameter of the striker 2 of the electromagnetic hammer is made with a gap to the guide 11. Due to this, it is possible to simultaneously evacuate the cavities 49 and 50, respectively, above the upper and lower ends of the striker through the holes 51, 52 in the guide 11 and the housing 1 of the hammer.

After evacuation, the holes are plugged and a vacuum is provided in the cavities 49, 50.

In the hammer striker 2, an axial hole can be made in an area of not more than 10% of the striker cross-sectional area, which makes it possible to facilitate the evacuation of both cavities from the side of the upper and lower ends of the striker.

The presence of a hole can make it possible to completely abandon the evacuation.

Claims (1)

A borehole seismic source containing two power devices made in the form of hydraulic cylinders with variable diameter equipped with plungers, between which a double-action electromagnetic hammer located in the housing is mounted coaxially to the plungers with poles and coils of forward and reverse motion, position sensors placed in the diamagnetic guide of the striker, interacting with its ends with plungers of hydraulic cylinders of power devices, moreover, 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 there are longitudinal grooves designed to accommodate communication wires of the power supply of the coils and sensors of the position of the striker of the electromagnetic hammer and its power supply and control system, characterized in that each power device is equipped with an oil cavity, which is connected with its additional oil volume, located in the housing in which it is installed There are heating elements connected in parallel and connected to the power supply and control system, and the firing pin is placed in a guide with a gap.

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