RU15584U1 - DEVICE FOR PROCESSING BOTH ZONE OF PRODUCTIVE FORM - Google Patents

Abstract

The utility model relates to the mining industry, namely to the field of production of fluid liquid or gaseous media through boreholes, and can be used to increase the permeability of reservoirs when processing bottom-hole zones of productive formations, in particular, composed of dense low-permeability terrigenous rocks, the tightness of which is caused by stress relaxation around the borehole.

The utility model is based on the task of developing a device for treating the bottom-hole zone of a productive formation that would allow, by improving the deflecting device, to achieve the ability to concentrate the acoustic effect in the perforation slots, directing it to equilibrium zones that balance rock pressure, and turbulent the flow of working fluid at the location of the deflecting device creating cavitation processes, and only then create additional force action, which expands , complements and consolidates the effect achieved by the influence of sound impulse and cavitation, and, due to this, reduce the working pressure created by the device, which is necessary for crack formation and increase its reliability and working capacity.

To do this, in a device that contains a column of pressurized tubing, above which the action of the hydraulic shock generator is located, with a possibility of transmitting the action into the depth of the column, a deflecting device, a reservoir with working fluid, a pump, the inlet of which is connected to the reservoir, and the outlet with the void of the column are installed , a means of sealing a borehole, a means of sealing the upper part of the column, the deflecting device is made in the form of a hollow body of revolution, inside the cavity of which is installed in its lower part to nical reflector on the side surface of which there are longitudinal, through slots, the length of which equals the value of the projection on the vertical axis of the borehole minimum distance between two adjacent slits perforations. In this case, the rotation body can be made in the form of a hollow cylinder or a hollow hyperbolic paraboloid, the conical reflector is mounted with the possibility of adjusting the gap between the inner side surface of the rotation body and the cone of the reflector, and the inner side surface of the through longitudinal grooves is at an acute angle to the side surface of the body rotation so that the opening of the groove on the outer surface of the body of revolution is smaller than the opening of the groove on its inner surface.

1 n.p. fili, 1 ill.

ESSAY

Description

DEVICE FOR PROCESSING BOTH ZONE OF PRODUCTIVE FORM

DESCRIPTION OF A USEFUL MODEL A utility model relates to the field of mining, and

namely, to the field of production of fluid liquid or gaseous media through wells, and can be used to increase the permeability of reservoirs when processing bottom-hole zones of productive formations, including those consisting of dense low-permeability terrigenous rocks, the impermeability of which is caused by relaxation of stresses around the well.

For the treatment of reservoirs in terrigenous rocks, devices that cause hydraulic fracturing of formation 1 are most often used. The device contains means for creating pressure, i.e. a pump for injecting the working fluid or foam under high static pressure into the well drilled through the reservoir, and means for sealing the well. The perforation slots previously formed in the well under the influence of high pressure become a kind of stress concentrator, in which along the lines of least resistance formed by cracks, rock breaks, expansion and development of cracks in the formation. The device is simple and easy to operate, but to intensify the extraction of minerals from very dense terrigenous rocks, the device is ineffective. High density and low permeability of the rocks necessitate the creation of ultra-high loading pressures. This circumstance in itself already causes great technical difficulties, for example, the need for additional sealing of the device components, hardening of the production casing, cement ring of the well, etc. In addition, it happens that excessive pressure leads to violations of the mining and geological conditions of the field development , which subsequently cannot be restored by any known means and methods. After this treatment, the working well completely leaves the existing ones.

IPC "E21 B 43/25

Closest to the claimed device is device 2. A known device for processing the bottom-hole zone of a productive formation contains a string of sealed tubing (tubing), above which is located a water hammer generator that can transmit the impact of the latter deep into the column, and in its lower part a deflecting device is installed. A throttle is installed in the lower part of the tubing string in front of the diverting device, which controls the flow rate of the working fluid supplied to the well. The device also contains a reservoir with a working fluid, a pump inlet connected to the reservoir, and an outlet with a cavity of the column, means for sealing the well and means for sealing the upper part of the column. A disadvantage of the known device is the impossibility of directed shock and sound waves acting on zones in which the stress arising from the redistribution of rock pressure is concentrated, i.e. to equilibrium zones balancing rock pressure. The deflecting device deflects and divides the continuous power wave into discrete pulses thanks to specially provided longitudinal grooves on its surface. Thus, it enhances the uneven loading, which only reduces the effects of static and shock loads, causing the need to further increase the loading pressure to achieve a pressure in the well above pore pressure. In addition, the device during operation requires large labor costs, caused by the duration of exposure to the reservoir to achieve the desired increase in its productivity, and these labor costs are not always justified, because can lead to a negative result, namely to the destruction of the well. In addition, the passage of water hammer through the throttle hole adversely affects the operability of the device, leads to overloads, causes depressurization and breakage of the tubing.

When creating the device, they were based on the well-known fact that the pressure existing in the depth of the existing rock layers, the so-called rock pressure, is redistributed during mining operations, and individual equilibrium zones are formed around the contour of the drilled well, in which

concentrated stress, and which balance the redistributed rock pressure around the specified mine workings. The creation of a utility model is based on the task of developing a device for processing the bottom-hole zone of a productive formation, in which by improving the deflecting device it is possible to concentrate the acoustic effect in the perforation cracks, directing it to the equilibrium zones balancing the rock pressure, and turbulent the flow of working fluid at the location of the deflecting device , creating navigation processes, and only then exert additional force impact expanding, additional The complementary and fixing effect achieved by the action of a sound pulse and cavitation, and also increase the reliability and performance of the device. Such a successive effect of acoustic, cavitation, and force effects on the equilibrium zones allows one to reduce the pressure developed by the device and necessary for crack formation. Low load static pressure makes it possible to apply the inventive method both for the reconstruction of old, inactive, cased wells that cannot be restored by any other known methods, and to increase the productivity of new working wells with reduced flow rate. The device at the same time consists of simple, widespread, inexpensive equipment and does not require large labor costs for its maintenance and commissioning. The problem is solved in that the device for processing the bottom-hole zone of the reservoir, containing a column of sealed tubing, above which is located with the possibility of transmitting the impact into the depth of the column, a water hammer generator, and at the lower end there is a deflecting device, a reservoir with working fluid, a pump, an inlet which is connected to the reservoir, and the outlet with the cavity of the column, a means of sealing the well, a means of sealing the upper part of the column, according to the utility model, further comprises means for communicating the cavity to the reservoir well, and the deflection device is designed as a hollow body of revolution, on the lateral surface of which there are longitudinal, through slots, which equals the largest length of the projection on the vertical axis

wells of the minimum distance between two nearby perforation slots, while a conical reflector is installed inside the cavity in the lower part of the body of revolution. A conical reflector, according to a utility model, can be fixedly connected to the body of rotation, and can be installed in it with the possibility of adjusting the gap between the inner side surface of the body of rotation and the cone of the reflector. This clearance adjustment allows you to change the angle of deviation of the acoustic pulse, adapting the deflecting device to the perforation zone of the well being processed. According to a utility model, the reservoir of the device comprises a measuring means installed with the ability to display the level of the working fluid in it. The body of revolution, according to the invention, can be made in the form of a hollow cylinder or a hollow hyperbolic paraboloid, the radius of curvature of which ensures the focusing of acoustic waves in the depth of the perforation cracks, and depends on the depth of the perforation zone in the well, the strength characteristics of the processed rocks, and the length of the perforation cracks . For each well, the parameters of the deflecting device are selected individually by calculation and based on preliminary results of the geophysical survey of the well. If the density of the rocks is large, and the perforation cracks are long, that is, go far into the thickness of the formation, it is necessary that the acoustic effect spread over a large distance along the gap and have a large intensity of impact, while the rotation body is in the form of a hyperbolic paraboloid with a large radius of curvature; if the density of the rock is large and the perforation cracks are shallow, the enhanced focused influence of acoustic waves must be applied shallow from the surface of the well, the radius of curvature of the paraboloid is less. If the reservoir rocks have initial permeability, and focusing of the acoustic waves by the side surface of the paraboloid is not required, the body of revolution may have a cylindrical shape.

so that the opening of the groove on the outer surface of the body of revolution is smaller than the opening of the groove on its inner surface. This embodiment of the grooves allows you to create additional ejection of the working fluid when it flows from the tubing.

The drawing shows a schematically claimed device for bottom-hole treatment of a reservoir with a deflecting device in the form of a hyperbolic paraboloid.

The device comprises a tubing string 1, consisting of separate interconnected pipes. Above the column is installed with the possibility of transmitting its action inside the column of the hammer generator. As a hammer generator, any percussion instrument 2 capable of generating a shock, for example, a hydraulic hammer, can be used. The percussion instrument is provided in its upper part with a suspension device 3 and is connected to the column through an adapter 4 and a gate valve 5. At the lower end of the column there is a deflecting device 6. The deflecting device 6 can be fixed one-piece or detachably, for example, by means of a threaded connection. The deflecting device 6 consists of a rotation body 7 and a conical reflector 8. A conical reflector 8 is installed inside the cavity, in the lower part of the rotation body 7. The conical reflector can be made integral with the body of revolution, and can be installed with the possibility of regulating the gap between the inner side surface of the body 7 of rotation and the cone of the reflector 8. Due to the implementation of the body of rotation 7 in the form of a hollow hyperbolic paraboloid, the deflecting device is simultaneously deflecting and reproducing the impact of water hammer on the side surfaces of the well, and also concentrates the impact of water hammer in the depth of the cracks 9 perforation. The rotation body 7 is made with longitudinal, through grooves 10 on its lateral surface, the length of which 8 is equal to the projection onto the vertical axis of the well 11 of the minimum distance between two adjacent perforation slots 9. The distances between the perforation cracks are determined as a result of preliminary geophysical studies. The device also contains a reservoir 12 with a working

liquid pump 13, the inlet pipe of which is connected to the reservoir 12, and the outlet to the cavity of the column 1. The pump flow should be selected so that it is greater than the current injectivity of the formation. A measuring means is installed in the tank, for example, a measuring ruler 14, installed with the ability to display the level of the working fluid in the tank. The device also comprises means 15 for sealing the well and means 16 for sealing the upper part of the column. In this case, the cavity of the well is connected to the reservoir through the pipe 17. The device is mounted and used as follows. In the lower part of the column 1, a deflecting device is mounted 6. The percussion instrument 2 is suspended with the column using a suspension device 3 to the tower of the overhaul unit, lower the column into the well and increase it with standard pipes to the level of the perforation zone. The pipe joints are reinforced with special mastic and sealed with FUM insulating tape. Percussion instrument 2 is mounted on top of column 1 from above. Percussion instrument 2 is connected through adapter 4 and valve 5 to tubing string 1. Install the column so that its lower end with a deflecting device 6 is located on the initial segment of the perforated formation. The well 11 is sealed, and the cavity of the well with the reservoir 12 is connected by a pipe 1 / to return the liquid overflowing the well back to the reservoir. The cavity of the column 1 is connected to the inlet of the pump 13. Fill the well with a working fluid, for example, produced water. The produced water of the developed reservoir is often used as a working fluid, taking into account its low cost and assuming that the internal vibrations of the particles of the produced water, coinciding with the vibrations of the inclusive rocks, lead to additional resonant vibrations affecting the equilibrium zones. Through the column 1, the working fluid from the reservoir 12 is continuously pumped into the well by means of a pump 13, maintaining its constant flow rate. The excess liquid not absorbed by the reservoir is displaced from the well back to the reservoir and again flows from the reservoir to the well according to the scheme: reservoir — pump — tubing string — well — reservoir. The gauge line 14 installed in the tank 12 allows continuous

measure the absorption of the working fluid and thus indirectly determine the current injectivity of the reservoir. The change in the current injectivity of the formation can be determined and recorded automatically, equipping the device for processing the bottom-hole zone with an automatic control system (ACS), as well as light or sound signaling devices. Systems of this type are well known, they do not concern the essence of the utility model, and therefore are not described in detail. They increase the pressure in the system and create excessive static alternating pressure. The amount of overpressure is changed from the minimum value that ensures constant pressure of the working fluid to the percussion instrument 2, to a maximum value not exceeding the repression pressure, taking into account the pressure of the working fluid column. Advantageously, the maximum pressure is selected within the range of 0.3 to 0.5 MPa / s. Impulses of force from a hydraulic shock are applied to a wave of variable static pressure, which generate with a frequency within (25 - 35) s and transmit impulses along a column of fluid deep into the well. The acoustic waves arising from the impact also propagate along the column of the working fluid. Since the speed of propagation of sound waves is higher than the speed of propagation of power waves, they reach the deflecting device 6 earlier, change the direction of movement, reflecting on the conical reflector 8, are reproduced on the side surfaces of the well 11 and, due to the shape of the body 7 of rotation, focusing in the beam, fall into the slots 9 perforation. The operator directly or through the control device of the ACS controls the change in the intensity of sound vibrations. If the sound wave does not fall into the equilibrium zone, the sound intensity does not change. Column 1 with a deflecting device 6 is moved downward along the section of the perforated layer of the well to a distance of 5. Again, the impact is repeated with a water hammer and the presence of an equilibrium zone is again determined. Thus, a sequential effect on all perforation cracks is carried out throughout the thickness of the reservoir, revealing the maximum possible number of equilibrium zones. Focused acoustic impact on these zones leads to their unloading with the formation of microcracks, and the pulsed impact of water hammer further leads to

avalanche cracking. The impact on the collector of a sound wave of a variable nature is supplemented by the effect of acoustic cavitation resulting from this. Acoustic cavitation additionally contributes to the occurrence and development of cracks. Having recorded a hit in the equilibrium zone, the operator, directly or through the ACS executive body, continues to influence the formation with a pulsating power load of a hydraulic shock. The cracks arising at the same time avalanche pass into the echelons of normal fracture cracks directed deep into the reservoir, combining with each other and opening closed cracks, i.e. turning the passive porosity of the layer into active. When additional injectivity is fixed, the hydro-wave treatment of the formation layer is carried out until the injectivity is stabilized, but at the same time, the absorption of fluid by the formation should be, at least, at least 10 m for each treated area.

After hydro-shock wave treatment and obtaining stable results of pumping working fluid into the reservoir, an increase in the permeability of the layer is observed by the inflow of previously unselected reserves to the well. Since 1997, a device for processing the bottom-hole zone of a productive formation has been tested on productive formations of various fields. All wells treated with this device received positive results. Production from all processed abandoned wells was obtained, and existing wells after treatment increased production, which is confirmed by the following examples.

Example 1. Well No. 81 of the Bogdanovskoye field. The production rate is 1.3 tons per day. After treatment, the flow rate of the well increased to 7.103 tons per day. Over the period from October 1997 to the present, the well produced an additional 3 thousand tons of oil.

Example 2. Well No. 86 of the Bogdanovskoye field. The production rate before processing is 0.1 tons per day. After treatment, the flow rate of the well increased to 5.2 tons per day. The well has been operating since October 1997. to December 1998 and was lost in connection with an attempt to re-increase well productivity by using hydraulic fracturing in combination with acid treatment.

Example 3. Well No. 9 of the South Afanasyevsky field. The production rate before treatment is occasionally up to 0.73 tons per day. After processing from February 1, 1999 to October 1, 1999, it yielded an additional 292 tons of oil and 201 thousand meters of gas.

Example 4. Well No. 6 of the South Afanasyevsky field. The flow rate before processing is 0.84 tons per day. After processing from February 1, 1999 to October 1, 1999, it produced an additional 1,856 tons of oil and 957 thousand m of gas.

Example 5. Well No. 181 of the South Afanasyevsky field. Before treatment, the well did not work. After processing in June 1999. well on 01.10.99 yielded about 104 tons

oil and 58 thousand meters of gas.

As can be seen from the examples, the device allows you to convert passive porosity containing minerals not mined from the reservoir into active porosity, and thus increase their production in rocks of any composition.

List of references

1. The author's certificate of the USSR No. 1819989, MKI E21B 43/26, 1993.

2. Patent of Ukraine No. 25244, IPC ЕВВ 43/28, 43/25, 1998 (prototype).

Director of public organization QiJ promoting mountain art

Tarasenko

Claims (6)

1. A device for processing the bottom-hole zone of the reservoir, containing a column of sealed tubing, above which is located a hydraulic shock generator installed with the possibility of transmitting the impact into the depths of the column, and in the lower part there is a deflecting device, a reservoir with working fluid, a pump, the input of which connected to the reservoir, and the outlet with the cavity of the column, a means of sealing the well, a means of sealing the upper part of the column, characterized in that it contains means for communicating the floor STI wellbore with the reservoir, and the deflection device is designed as a hollow body of revolution with longitudinal through slots on the side surface, the length of which is equal to the projection of the vertical minimum distance of the borehole axis between the two closest slits perforations and inside bottom of the conical rotation body mirror installed.  2. The device according to claim 1, characterized in that the rotation body is a hyperbolic paraboloid, the radius of curvature of which provides focusing of acoustic waves in the depth of the perforation slots.  3. The device according to claim 1, characterized in that the rotation body is a cylinder.  4. The device according to claim 1, characterized in that the conical reflector is installed with the possibility of adjusting the gap between the inner side surface of the body of revolution and the cone of the reflector.  5. The device according to claim 1, characterized in that the reservoir contains a measuring tool installed with the ability to display the level of the working fluid. 6. The device according to claim 1, characterized in that the inner side surface of the through longitudinal grooves is located at an acute angle to the side surface of the body of revolution so that the opening of the groove on the outside of the body of revolution is smaller than the opening of the groove on its inner surface.