RU2360102C2 - Installation for impact-depression effect onto bottomhole zone of reservoir and for cleaning bottomhole of well - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: installation consists of depression chamber, of gate element of this chamber, of catcher and of plunger. According to the invention the installation has a head for a logging cable tip with a valve for excessive pressure relief, a module of radioactive survey for connecting the installation to well profile and a slime-receiving facility. The gate element of the depression chamber is made non-destructive, and has a gate with a fusing element and a heated spiral for heating the fusing element and for opening the gate element. The catcher has slit-like vertical cuts and a cone-deflector for concentrating hydraulic impact. Also to facilitate additional thermal influence onto bottomhole zone of the reservoir a powder charge can be secured to the installation. Insulated current conducting elements are installed in the plunger of the depression chamber and in the gate element.

EFFECT: increased reliability of installation operation and its expanded functions.

1 dwg

Description

The present invention relates to devices for shock and depressive effects on the zone of perforation of oil and gas wells and cleaning the bottom of the wells, may find application in the oil and gas industry.

In practice, the impact on the perforation zone of oil, gas and injection wells, in order to increase production or injectivity, have found application of the device based on the following methods: hydraulic and gas fractures, thermal, acoustic, electromagnetic, chemical, explosive, implosive (depressive) and their possible combinations. In practice, cleaning the bottom of the wells have found application for the following methods: drilling, hydromonitor (flushing the bottom of the wells through the tubing string), mechanical (traps, screw devices, etc.) and implosion methods. Of the above methods of processing the perforation zone, hydraulic fracturing, chemical, thermal and implosion methods are most widely used. When cleaning the bottom of the wells, flushing of the bottom of the wells through the tubing string, mechanical and implosion traps for catching foreign objects at the bottom are most widely used.

Of the many designs using the implosive (depressive) effect, the typical ones are:

Device by A.S. No. 2158363 [1] for implosion and thermoimplosion, launched on a geophysical cable, includes an implosion chamber, an inlet valve, a heating coil, a charge with an ignition unit connected by electrical wires to a ground control panel. The internal cavity of the inlet valve is equipped with a cylindrical stop made of an insulating thermoplastic material stitched with a first heating coil connected to a ground control panel. The charge with the ignition unit is placed in a fireproof protective casing having side openings. The ignition unit consists of a gasket stitched with a second heating coil connected to a ground control panel. Outside, around the circumference of the implosion chamber, plates adjacent to each other are installed, the upper part of which is beveled towards the implosion chamber, the lower one is attached to its body. The number of plates is 10-20 pieces, and the plates can be two-layer. The implosion chamber is opened by melting a cylindrical stop made of a thermoplastic material when an electric current is supplied from the surface via a geophysical cable. The disadvantage here is the need to make a disposable cylindrical stop from a thermoplastic material, designed for significant pressure, and it is not a fact that the section opened during its melting will be necessary.

A device is also known for A.S. No. 2097531 [2] for cleaning the face during the repair of wells in the oil industry. The essence of the invention: when reaching an implosion chamber, lowered on a geophysical cable, with a diaphragm as a shut-off element in the lower part of the bottom of the well, electric current is supplied to the electric motor drive via a wireline cable. As a result, the load falls down, a spring-loaded striker is activated. The diaphragm is destroyed, the borehole fluid fills the air chamber, dragging along the slurry and various objects located at the bottom into the receiving chamber-trap. The petal shutter is wrung out. In this case, part of the sludge is sucked into the air chamber. At the end of the suction process, the hole in the diaphragm is blocked briskly under the action of a spring, preventing the loss of the outgoing sludge. The disadvantage of this device is the unreliability of opening the implosion chamber in deviated wells.

The closest to the proposed one is a device that very effectively uses depression and shock effects with an implosion effect, called a pressure hydrogenerator and described in [3] (p. 47).

The pressure hydrogenerator (GGD) consists of a body (implosion or depression chamber), a membrane (as a shut-off element of the implosion chamber), a plunger (for impact) and a trap (for guiding the water hammer). The pressure generator is lowered into the well to the required depth on the tubing string so that the middle of the trap windows is against the interval of the treated formation. After that, the annular valves are closed and by increasing the pressure at the mouth due to the injection of the working agent into the well, the membrane is ruptured. Then, the borehole fluid at a speed of 100-150 m / s fills the implosion chamber and pushes the plunger into the trap, creating a hydraulic shock with a pressure exceeding the mountain pressure (it can be several times higher) in the treated zone of the formation (at the level of the windows of the trap). This, in turn, ensures the formation of artificial or expansion of existing residual cracks in the bottomhole formation zone, which, due to irreversible processes of rock deformation, do not completely close under the influence of rock pressure.

Thus, the basis of the method is that improving the filtration characteristics of the bottom-hole zone of the formation and, consequently, increasing the production rate and injectivity of injection wells is achieved by using the energy of the hydraulic shock of the falling column of the borehole fluid, the height of which is equal to the depth of the treated formation. A simple calculation shows that the change in the potential energy of a falling liquid column at a formation depth of 2000 m, a column diameter of 127 mm, an implosion chamber length of 10 m and its diameter 60 mm is 560 kJ (155 kW · h or 133.4 kcal). In comparison with the values of the energy delivered to the face by powder pressure generators (1000 kcal / kg), this is not a very significant value, but since almost all the energy of the shock-impact effect is converted into mechanical energy, this mechanical effect is very significant. For example, in [3] (p. 86), calculations are made according to which the pressure of a water hammer in a well reaches 250 MPa, which significantly exceeds the rock pressure in oil and gas reservoirs.

Despite the undoubted advantages of this method and device, there are also disadvantages to which the author of the method points out in [3]:

- A long time for the implementation of one operation of shock-depressive effects on the reservoir due to the descent of the device on the tubing string. According to the proposed technology, the first descent of the device is carried out without a plunger in order to clean the treated area, and the second descent is carried out with a plunger for additional impact. If the thickness of the treated formation is more than 2 m, one operation is clearly not enough and the number of device launches will increase significantly;

- It is quite difficult to implement and unreliable way to open the shutter element of the implosion chamber (the manufacture of a membrane that is destroyed by the pressure of the pump unit from the surface is a rather complicated and demanding operation, there have been cases of premature destruction of the membranes during the descent of the device, and cases of the impossibility of membrane destruction);

The aim of the invention is to reduce the production time of one operation, increase the reliability of the device and expand the functionality of the device (for example, use for operations to clean the face before and after exposure to the bottomhole zone of the formation and use in operations of thermal implosion).

The inventive device for shock-depressive effects on the bottom-hole zone of the formation (hereinafter PZP) and cleaning the bottom of the wells (see drawing) contains a radioactive logging module 1 with bore wires for linking to the well section, a head 2 with a valve 3 for overburden relief and a device for passage of current-carrying conductors 4, a trap (tubing pipe section with slit-like vertical slots) 5 for guiding a water hammer into a formation zone with a cone-reflector 6 for shock concentration, a plunger 7 for creating a water hammer with a device for live conductor passage 8, an implosion chamber 9, an implosion chamber valve 10, including a piston device 11 (upper 12 and lower 13 pistons, rod 14, a device for passing a live conductor 15), a cylinder 16 with hydraulic fluid, plug 17, an electric shutter with a heating a spiral 18, a fusible element 19, a holding element 20, and a replaceable nozzle 21. As a replaceable nozzle, a guide pipe (a tubing section with slit-like vertical slots and a blanked lower end) can be installed to receive fluid and colmati uyuschih elements from the formation, shlamopriemnoe device 21 for the selection of sludge or downhole sub for fixing any type of propellant charge for the heat treatment. To supply electric current to the shutter and powder charges from the geophysical head are electric wires 22 and 23.

When implementing the methods of exposure to the PPP [3], the device operates as follows:

- To produce a depressive effect on the perforation interval or to clean the bottom of the well, the device is equipped, lowered into the well without a trap 5 and plunger 7. After binding to the section of the well, using the radioactive logging module 1, the guide pipe of the device is installed opposite the perforation interval or to the bottom located in the bottom of the sludge receiving device 21. In this case, the pressure outside the device is equal to the borehole pressure at the achieved depth (up to 40 MPa at depths up to 3000 m), in the cavity of the implosion chamber 9 and the valve body 10, the pressure is atmospheric (equal to the wellhead when the device is equipped), in a cylinder with hydraulic fluid 16, limited by the upper piston 12 of the piston device and the plug 17, the pressure can be found from the formula:

Where

P is the pressure in the cylinder;

P _with - pressure in the well;

S _in - the area of the upper piston;

S _n - the area of the lower piston.

Thus, the lower piston 13 is a locking element of the implosion chamber 9, supported through the rod 14, hydraulic fluid in the cylinder 16, the plug 17 and the retaining element on the valve body 10. The cylinder 16 is pressed into the jumper of the valve body 10 and leaves a message between the body of the implosion chamber 9 ( tubing) and a cavity below valve 10. When an electric current is supplied from the surface through a geophysical cable to the heated coil 18, it heats the fusible element 19 (polyethylene ring), which, when broken, releases the holding the sealing element 20 and, accordingly, the plug 17. In this case, the borehole pressure, acting on the lower piston 13, moves the upper piston 12 through the rod 14, and the hydraulic fluid in the cylinder 16 pushes the plug 17. The result of the movement of the lower piston 13 is the opening of the valve cavity 10 and the implant chamber 9. The downhole fluid, moving up the implosion chamber 9 with high speed, creates an implosion effect, which consists in creating a region of depression in the region of the perforation interval through the guide pipe 5. Elements, colmati those who perforate the formation perforation zone, can be sucked in and deposited in the guide pipe. In the implosion chamber, shock pressure arises, which turns into alternating, damping pressure fluctuations.

When the device is installed on the bottom with the sludge receiving device 21, when the valve 10 is opened and an implosion effect occurs, the sludge located on the bottom is sucked into the implosion chamber 9. The petal structure at the bottom of the sludge receiving device 21 will keep the sludge inside the device when it is lifted. When clogging the implosin chamber 9 with sludge and possibly preserving the excess pressure inside it, the valve 3 in the geophysical head 2 is used. With it, the excess pressure will be released after the device is lifted from the well.

- To produce a shock-depressive effect on the perforation interval, the device is equipped, lowered into the well with trap 5 and plunger 7. After binding to the well’s section, using the radioactive logging module 1, the device trap 5 is set opposite the perforation interval. After opening the implosion chamber 9, the borehole fluid moving in it at high speed creates shock pressure on the plunger 7 located in the upper part of the implosion chamber. In turn, the plunger 7 through the trap 5 transmits shock pressure into the treated zone of the formation. Cone 6 is used to concentrate the transmitted pressure in the horizontal plane.

- For the production of thermoimplosive effects on the PZP, the device can be used in accordance with existing methods of thermoimplosive effects and an adapter for attaching the corresponding powder charge.

In the manufacture of the above device, the following conditions are met:

- The cross-sectional area of the entrance to the implosion chamber (cross-sectional area of the piston 13), the annular cross-section of the passage between the valve body 10 and the cylinder with hydraulic fluid 16, the cross-section of the fluid passage in the bridge with the cylinder 16 inside the valve body 10, the cross-sections of the implant chamber are the same;

- The material and diameter of the cylinder 16, the thickness of its walls, the annular rubber seals of the pistons (12 and 13) and the plugs 17 are selected capable of withstanding the pressure arising in it (according to formula (1) up to 50 MPa with a depth of the processed seams up to 3000 m), which is quite feasible.

- The fusible element 19 withstands the force (in our case no more than 2000 N) exerted on it by a stopper 17 and a holding element 20.

The use of this device for shock-depressive, thermoimplosive impact on the bottomhole formation zone and cleaning of the bottom of the wells will allow you to quickly and effectively perform work on the impact on the bottomhole zone of oil and gas wells and clean the bottom of the wells with minimal time, materials (flushing water) and, accordingly, minimal environmental pollution Wednesday.

Based on the foregoing, we believe that the claimed design of the device for shock-depressive effects on the bottomhole formation zone and cleaning the bottom of the wells is new, industrially applicable, i.e. complies with patentability conditions.

Information sources

1. Copyright certificate No. 2158363. Device for processing bottom-hole zone of a well. Mukhametdinov N.N., Kuznetsov A.I., Kneller L.E. 2000 year

2. Copyright certificate No. 2097531. Device for cleaning the bottom of the well. Fakhreev I.A., Kamalov F.Kh., Krivoplyasov A.M. 1997 year

3. Impact effects on the bottomhole zone of wells. A.A. Popov. M .: "Nedra", 1990

Claims (1)

A device for shock and depressive effects on the bottom of the formation and cleaning the bottom of the wells, containing a depression chamber, a locking element of this chamber, a trap and a plunger, characterized in that it contains a head under the tip of the geophysical cable with a valve for overpressure relief, a radioactive logging module for device binding to the well section and sludge receiving device, the locking element of the depression chamber is made indestructible, has a shutter with a fusible element and a heating coil For heating the fusible element and opening the locking element, the trap has slit-like vertical slots and a cone-reflector for the concentration of water hammer, while to provide additional thermal influence on the bottom-hole zone of the formation, the device has the ability to attach a powder charge to it, and in the plunger, depressive the chamber and the locking element are insulated conductive elements.