RU2107814C1 - Method and device for pulsing action on productive bed - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: according to method, transmission is effected of molecular-wave oscillations from emitter of hydraulic hammer installed at well head through string of pump-compressor pipes via its upper end and along liquid column in bore-hole through its top level to productive bed. Simultaneously with transmission of molecular-wave oscillations, pressure is increased in bore-hole by delivering liquid from pump with pressure accumulator with their inlet connected to pump-compressor pipes at well head. Hydraulic impacts are created in liquid column in bore-hole by periodic closing of pump inlet by means of hydraulic hammer emitter during transmission of its molecular-wave oscillations to pump-compressor pipes and liquid column in well. Device has hydraulic hammer with striker and emitter which is resiliently connected with body of hydraulic hammer. Emitter is in the form of converter of pulse loads into molecular-wave oscillations and it is made integral with transmitter of molecular-wave oscillations towards upper end of pump-compressor pipes and to top level of liquid in bore-hole. Device is provided with high-pressure pump and pressure accumulator which are connected by their inlet to pump-compressor pipes at well head. Transmitter brings oscillations to top end of pump-compressor pipes and to top level of liquid in bore-hole. Lower end of transmitter is bevelled at angle of 45 deg. to its axis at side of pump inlet. Lower surface of hydraulic hammer striker is made concave, and surface of aforesaid converter which is in contact with it is made convex and mating to concave surface of striker. EFFECT: higher efficiency. 5 cl, 2 dwg

Description

 The invention relates to the mining industry, namely, to the pulsed action on the reservoir to increase oil recovery from the reservoir, restore the well and increase its productivity.

 There is a method of impulse action on a productive formation by impulse fracturing of formation rocks by injection of a working fluid into a developing fracture (see ed. Certificate of the USSR N 1221328, class E 21 B 43/26, 1986).

 There is also known a method of pulse impact on the reservoir by rupture of the membrane in the implant chamber with increasing pressure in the well to 10-45 MPa, as a result of which the well fluid at a speed of 100-150 m / s fills the implant chamber and pushes the plunger into a trap, creating in the processed formation zone water hammer [1].

 A disadvantage of the known methods is that it is not possible to obtain the required number of cracks in the reservoir, and it is impossible to obtain the required spatial development of these cracks due to the unsteady supply of energy to the reservoir, its saturation in minor directions and low repeatability of the loads.

 A known method of pulsed impact on the reservoir, including the transfer of molecular wave vibrations from the emitter of the hydraulic hammer installed on the mouth, through the string of tubing through its upper end and through the liquid column in the well through its upper level to the reservoir, and also a device for impulse action on the reservoir, including a hammer with a striker and an emitter elastically connected to the case of the hammer, in the form of a converter of pulsed loads into molecular wave swings performed in a single unit with transmitters of molecular-wave vibrations to the upper end of the tubing and to the upper level of the liquid column in the well [2].

 The disadvantages of the known method and device are the insufficient power of the impact on the reservoir due to energy losses during the transformation of the impact energy of the striker into the molecular wave oscillations of the emitter and during the passage of these oscillations along the tubing and through the fluid in the well, as well as due to insufficient preliminary stress of the rocks a productive formation that is under the influence of only hydrostatic pressure of the fluid in the well.

 The objective of the proposed method and device is to increase the impact power on the reservoir by reducing energy loss during the transformation of the impact energy of the striker into the molecular-wave oscillations of the emitter, increasing the preliminary stress of the rocks of the reservoir and imposing additional impulse loads.

 This problem is achieved by the fact that in the method of pulsed impact on the reservoir, including the transfer of molecular-wave vibrations from the emitter of the hydraulic hammer installed on the mouth, through the tubing string through its upper end and along the liquid column in the well through its upper the level on the reservoir, in contrast to the prototype method, simultaneously with the transfer of molecular wave vibrations in the well increase the pressure by supplying fluid from a pump with a pressure accumulator connected to Odom tubing to the wellhead and creating pressure surges in the fluid column in the borehole by periodically overlap pump input emitter breaker when transferring it from the molecular-wave vibrations on the tubing and fluid column in the borehole.

 This problem is also achieved by the fact that the device for pulsed impact on the reservoir, including a hydraulic hammer with a striker and an emitter elastically connected to the body of the hydraulic hammer in the form of a transducer of pulse loads into molecular wave vibrations, made in one piece with transmitters of molecular wave vibrations to the upper end The tubing and to the upper level of the liquid column in the well, in contrast to the prototype device, is equipped with a high pressure pump with a pressure accumulator connected by an input to the oil reservoir at the wellhead, the molecular-wave oscillation transmitter to the upper level of the liquid column in the well is installed with the possibility of periodically blocking the pump inlet while transmitting the molecular-wave oscillations to the upper end of the tubing and the upper liquid level in the well and is made with a lower end, beveled at an angle of 45 to its axis from the inlet side of the pump, the lower surface of the hammer head is concave, and the surface of said transducer in contact with it is a convex and counter concave surface of the hammer.

 This problem is also achieved by the fact that the total length of the specified transducer and the specified transmitters is equal to two half-waves of molecular wave vibrations, and the lowest transverse cylindrical section of the transmitter of these oscillations to the upper level of the liquid column in the well is located at the location of the maximum amplitude of the outgoing wave of these oscillations.

 This task is also achieved by the fact that the device is equipped with a hydraulic damper, the piston of which is rigidly connected to the body of the hydraulic hammer, and the cylinder has a sliding support for suspension on the boom of the excavator, and a hydropneumatic accumulator with attachment points in the boom of the excavator, and the hydraulic pressure cavities of the hydraulic damper and hydropneumatic accumulator are connected between by myself.

 And also by the fact that the contacting surfaces of the hammer head of the hammer and the specified transducer are made spherical.

 In FIG. 1 shows a device for pulsed impact on the reservoir, a General view; in FIG. 2 - emitter of a hydraulic hammer.

 A device for pulse impact on the reservoir includes a hammer with a housing 1 and a striker 2, an emitter 3 resiliently connected to the housing 1 of a hydraulic hammer. The emitter 3 is made in the form of a converter 4 of pulse loads into molecular wave vibrations and made in one piece with the transmitter 4 transmitters 5 and 6 molecular-wave vibrations to the upper end of the tubing and to the upper level of the liquid column in the well, respectively. The device has a high-pressure pump 7 with a pressure accumulator 8 connected by an input 9 at the wellhead to the tubing 10. The transmitter 5 of the molecular-wave vibrations to the upper end of the tubing 10 is made in the form of a cone, and the transmitter 6 of the molecular-wave vibrations to the upper liquid level in the well - in the form of a cylinder. The transmitter 6 is installed with the possibility of periodically blocking the input 9 during movements and is made with a lower end 11, beveled at an angle of 45 to the axis from the input side 9 of the pump 7.

 The lower surface 12 of the striker 2 is concave, and the surface 13 of said transducer 4 in contact with it is formed of a convex and reciprocal concave surface 12 of the striker 2. It is most preferable that said surfaces 12 and 13 are spherical.

 The total length of the transducer 4 and the transmitters 5 and 6 is equal to two half-waves 14 of molecular-wave vibrations (Fig. 2). The emitter 3 is located so that the lowest cylindrical cross-section 15 of the transmitter 6 is located at the location (passage) of the maximum amplitude 16 of the output wave 14 of the molecular wave vibrations.

 The impact of the transmitter 5 on the tubing 10 is carried out through a plate 17 mounted on a flange (not shown) of the tubing 10, and through an additional plate 19 connected by stiffeners 18.

 The housing 1 of the hydraulic hammer is fixed on the plate 17 and the additional plate 19 with studs 20.

 The device has a hydraulic damper 21, the piston 22 of which is rigidly connected to the housing 1 of the hydraulic hammer, and the cylinder 23 has a sliding support 24 for suspension on the boom 25 of the excavator. To damp vibrations, the device also has a hydro-pneumatic accumulator 26 with attachment points 27 for connecting to the boom 25 of the excavator. The hydraulic pressure cavities 28 and 29 of the hydraulic damper 21 and the hydraulic accumulator 26 are respectively interconnected.

 The hammer housing 1 is placed in a guide cylinder 30 mounted on bearings 31 at the wellhead coaxially with the tubing axis using a plumb 32.

 The damper 21 and the hydropneumatic accumulator 26 are controlled by the make-up pump 33 through the throttle 34 and the safety valve 35.

 The proposed method of pulse impact on the reservoir is as follows.

 The device is mounted on one car, the drive of which drives the hammer 2 of the hammer and pump 7 high pressure. During operation, the hammer 2 strikes the emitter 3, in the converter 4 of which pulsed loads are converted into molecular wave vibrations. These oscillations through transmitters 5 and 6 during their movement are transmitted to the upper end of the tubing 10 and to the upper level of the liquid column in the well, and then along the tubing 10 and along the liquid column to the bottom of the well to the reservoir. Simultaneously with the transmission of molecular-wave oscillations in the well, the pressure is increased by supplying fluid from the high-pressure pump 7 through the input 9 to the tubing 10. An increase in pressure in the well contributes to the pre-loading of the reservoir, increasing stress in it.

 When the transmitter 6 is moved, its lower end periodically shuts off and opens the input 9. As a result, water hammers are generated in the well, which propagate along the tubing 10 and the liquid column in the well to the reservoir and act on it together with molecular wave vibrations and increased pressure in the well . Such loading of the well and the reservoir is a controlled process. The controllability of this work consists in the choice of frequency, impact energy, emitter movement, pipeline diameter. The total loading by the pump, water hammer and impact pulse of the hammer hammer depends on these indicators. As a result of the combined effect of increased pressure, water hammer and molecular-wave vibrations on the reservoir, the amplitude of vibrational loads increases as compared to a separate type of loading.

 The impact of the striker 2 with the emitter 3 also contributes to an increase in the impact power on the productive formation over the maximum contact area between them. The spherical shape of the collision areas of the concave lower surface 12 of the striker 2 and the convex surface 13 of the emitter 3 (transducer 4) provides the energy flow of molecular-wave vibrations along the vectors in the body of the emitter 2 without going beyond its side surfaces. As a result, the functioning of the oscillatory system is improved by transforming small oscillation amplitudes on a larger convex surface 12 into large amplitudes on a small cross-sectional area 15 of transmitter 6. Due to the optimal shapes of the transducer 4 and the hammer 2 and the cylindrical shape of the transmitter 6, the pressure in the wave pulse transmitted increases several times into the rock of the reservoir, and thereby the pressure in it increases.

 The implementation of the transmitter 6 with the lower end 11, beveled at an angle of 45 to the axis from the input side 9 of the pump 7, allows you to direct the vector of hydraulic shock that occurs when the pump 7 and the accumulator 8 abruptly communicate with the tubing 10 along the axis of the well to the reservoir. The total length of the transducer 4 and the transmitters 5 and 6 is selected from the condition of the location of two half-waves of the arising molecular wave vibrations in it, and the lowest cylindrical cross section of the transmitter 6 is located at the location of the maximum amplitude 16 of the outgoing wave 14 of the molecular wave vibrations. All this contributes to the most efficient transfer of impact energy of the hammer 2 of the hammer.

 The configuration of the emitter 3 provides the appearance in it of the minimum values of the maximum voltages at a fixed average integrated voltage, therefore, it is optimal according to the criterion of dynamic equal tension.

 The oscillations of the "productive reservoir-well-emitter" (PSI) system are affected by the recoil force of the hydraulic hammer if it is operated in an upright position and when the hammer 2 is braked before the top dead center. The force developed by the accumulator 8 when connecting the pressure line of the pump 7 through the input 9 to the tubing 10 is periodically added to this force. The maximum value of the reactive force consists of the recoil force of the hydraulic hammer and the force developed by the fluid flow in the tubing 10 from the pump 7 and the accumulator 8 in the pipeline, connecting the pump 7 to the tubing 10. This force tends to raise the excavator beyond the end of its boom 25, moving the support to the section of the chassis from the opposite side of the boom 25. The reactive force creates a bending moment in the arrow 25 against the clock arrow. Its elimination is achieved by installing between the boom 25 of the excavator and the hydraulic hammer of the hydraulic damper 21 and the hydropneumatic accumulator 26, which ensures the beneficial use of the recoil energy to stabilize the position of the hydraulic hammer and excavator near the well.

 Thus, as field tests have shown, the impact power on the reservoir and the well increases by a factor of 3-4, which helps to restore the well and increase crack formation in the rocks of the reservoir, as a result of which the well’s productivity is restored and increased.

Claims (5)

 1. A method of pulse impact on the reservoir, including the transfer of molecular wave vibrations from the emitter of the hydraulic hammer installed on the mouth, through the string of tubing through its upper end and through the liquid column in the well through its upper level to the reservoir, characterized in that at the same time as the transmission of molecular wave vibrations in the well, they increase the pressure by supplying liquid from a pump with a pressure accumulator connected by an input to the tubing at the wellhead and create impacts in the liquid column in the well by periodically shutting off the pump inlet by the emitter of the hydraulic hammer while transmitting molecular wave oscillations from it to the tubing and the liquid column in the well. 2. A device for pulsed impact on the reservoir, including a hammer with a striker and an emitter elastically connected to the case of the hammer, in the form of a converter of pulsed loads into molecular wave vibrations, made in one piece with transmitters of molecular wave vibrations to the upper end of the tubing and to the upper level liquid column in the well, characterized in that it is equipped with a high pressure pump with a pressure accumulator connected to the tubing at the wellhead by an input to the tubing, the molecular-wave transmitter to oscillations at the upper level of the liquid column in the well is installed with the possibility of periodically blocking the pump inlet when transmitting molecular wave vibrations to the upper end of the tubing and the upper liquid level in the well and is made with a lower end, beveled at an angle of 45 ^o to its axis from the pump inlet side, the lower surface of the hammer head is concave, and the surface of said transducer in contact with it is a convex and reciprocal concave surface of the hammer.  3. The device according to claim 2, characterized in that the total length of the specified transducer and these transmitters is equal to two half-waves of molecular wave vibrations, and the lowest transverse cylindrical section of the transmitter of these oscillations to the upper level of the liquid column in the well is located at the location of the maximum amplitude of the outgoing waves of these oscillations.  4. The device according to claim 2, characterized in that it is equipped with a hydraulic damper, the piston of which is rigidly connected to the body of the hydraulic hammer, and the cylinder has a sliding support for suspension on the arrow of the excavator, and a hydraulic accumulator with attachment points to the arrow of the excavator, and the hydraulic pressure cavity of the hydraulic the damper and the hydraulic accumulator are interconnected.  5. The device according to claim 2, characterized in that the contacting surfaces of the hammer head and the specified transducer are made spherical.

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