RU197643U1 - Hydraulic Fracturing Coupling - Google Patents

Abstract

Fracking clutch (hydraulic fracturing), consisting of a hollow cylindrical body with circulation holes made in it, in which a differential movable sleeve with radial holes is installed, blocking the housing circulation holes in the initial position and fixed relative to the latter by a latch, characterized in that for internal separation coupling cavities and cavities between the sleeve and the housing for axial movement of the sleeve in order to open the circulation holes, at least one bursting disc is installed in it, and ring ledges are made on the inner surface of the differential movable sleeve for axial movement with a key with dies containing grooves for ring ledges.

Description

The utility model relates to the oil industry, namely to the rigging of casing strings. The hydraulic fracturing coupling is part of the suspension equipment string (liner) and can be used in the construction of wells for oil production.

The coupling is designed to carry out hydraulic fracturing of an oil reservoir to increase inflow and oil recovery and should provide communication between the annular space and annular space when creating the required pressure in the internal cavity.

Well-known hydraulic fracturing couplings in which the opening of radial circulation holes is carried out by balls or a switching tool from the surface (patent RU 2531407 C2 IPC Е21В 43/26, Е21В 34/06, published on October 20, 2014 Bull. No. 6).

The device includes a housing and a movable sleeve, which, depending on the position in the housing, blocks or provides a radial fluid flow between the inner and outer parts of the coupling.

The disadvantage of this technical solution is the impossibility of cementing the annulus of the well, which requires annular packers to separate fracturing intervals.

Known coupling for cementing, comprising a housing with circulation holes, in which a movable differential sleeve is installed, overlapping the circulation holes of the housing and fixed relative to the latter by a shear pin (patent RU 46296 U1 IPC ЕВВ 33/14, published June 27, 2005).

The disadvantage of this technical solution is that when cementing the annulus, cement will fill the control cavity to move the sleeve, which will not allow the coupling to be opened during hydraulic fracturing.

Hydraulic fracturing couplings are known in which plugs with bursting membranes and covers blocking the flow of fluid to the outer side of the membrane are installed in the radial holes of the housing. A cavity is formed between the membrane and the cover, in which there is a liquid or gas under a certain pressure (patent US 2012/0111566 AI IPC ЕВВ 43/11, ЕВВ 17/14, ЕВВ 34/00, Е21В 43/26, Е21В 43/28, Е21В 33/12, published May 10, 2012).

The opening of radial channels for hydraulic fracturing fluid is carried out by raising the pressure inside the coupling to the pressure of the destruction of the membrane, the destruction of cement on the outside of the coupling and the removal of the blocking cover.

The disadvantage of this technical solution is that to ensure minimum resistance on the circulation holes, their number is set on demand to ensure their area equal to the area of the inner cavity of the coupling. These are more than 15 membranes. It is difficult to ensure the destruction of all membranes at the same pressure.

Also in this coupling there are no elements for closing the coupling if necessary, for example, the flow of water from this interval.

The claimed utility model gives a technical result, which is expressed in the guaranteed response of the hydraulic fracturing sleeve from excessive pressure inside the liner after cementing, the opening of all circulation holes and the possibility of their repeated closures and openings with a key with dies.

Devices with the claimed combination of distinctive features in the patent and scientific literature are not identified. This determines the compliance of the utility model with the criterion of "novelty."

The invention and the principle of operation of the proposed utility model is illustrated by the drawings of Fig. 1, Fig. 2 which shows the hydraulic fracturing coupling.

The hydraulic fracturing coupling includes: an upper sub 10, a hollow cylindrical body 1 with radial holes 2 made therein, annular grooves 3 and 4 for fixing in the position of closed and open circulation holes, a latch 5 made in the form of a split elastic ring, a differential movable sleeve 6 with radial holes 7 and annular ledges 8 for closing the circulation holes with a key with dies. To fix the differential movable sleeve from circumferential movements, a groove is made in the sleeve, and a screw 20 is installed in the housing. The differential movable sleeve forms two closed airtight cavities A and B with the housing with air at atmospheric pressure. To separate the cavity A from the inner cavity of the coupling, a rupture disk 9 with an o-ring 19 is installed in the differential movable sleeve, and for sealing the cavity A, rubber O-rings 11, 12, 13 are installed. To seal the cavity B, rubber O-rings 13 are installed, 14, 15. O-ring rubber rings 16, 17, 18, separate the internal cavity of the coupling from the well.

The hydraulic fracturing clutch operates as follows. The hydraulic fracturing sleeve in the casing string descends to a predetermined interval of the wellbore. Cementing annular space of the wellbore. When selling cement, the inner cavity of the shank is cleaned with a cleaning plug. After cement hardens into the well, the cuff packer is lowered to the installation site of the hydraulic fracturing sleeve on the tubing or coiled tubing. The packer cuffs provide an airtight cavity in the area of the hydraulic fracturing sleeve. A hydraulic fracturing port (pipe with radial holes) was made between the cuffs. A pressure is created in the pipe, which destroys the membrane plug 9. Fluid under pressure (hydrostatic pressure at the coupling installation site plus excess pressure on the mouth) enters cavity A. The pressure acts on the annular area S (the area limited by diameters D and D1) of the differential movable sleeve, creating an axial force exceeding the holding force of the retainer 5. The cavity A is filled with a working fluid, and in the cavity B the air is compressed to a pressure of 0.5 ... 0.8 MPa. The differential movable sleeve 6 is shifted in the direction of the bottom, combining the radial holes 7 of the sleeve 6 and the circulation holes 2 of the housing 1. The axial force from the hydrostatic pressure of the liquid column in the well, acting on the annular area S, even without excess pressure, will fix the differential movable sleeve in the open position the circulation holes of FIG. 2. For additional fixation from axial movements in the position of open circulation holes 2, the differential movable sleeve 6 is fixed with a retainer 5 in the annular groove 4 of the housing 1. When the holes are aligned, the cement stone outside the coupling is destroyed and the message of the inner channel of the coupling opens with the interval where it is necessary to carry out hydraulic fracturing. The calculated volume of hydraulic fracturing fluid (proppant) is pumped through the circulation openings under a given pressure. After hydraulic fracturing in this interval, the packer moves to the next interval, in which the next hydraulic fracturing sleeve is installed, for hydraulic fracturing, or rises to the surface.

If during operation it is necessary to close the circulation holes in the coupling, for example, water entering from the reservoir in this interval, then a key with dies containing grooves for annular ledges that engage with annular ledges 8 of the differential movable sleeve 6 and axial displacement is lowered into the well key with dies towards the mouth, overcoming the retaining force from hydrostatic pressure and the retaining force of the retainer 5, shifts the differential movable sleeve 6 all the way into the ledge of the sub 10, blocking the circulation holes 2 in the housing 1, ensuring separation of the inner cavity of the coupling and annular space. In this position, the differential movable sleeve is held by the retainer 5 in the annular groove 3 of the housing 1, the holding force of which is 1 t more than the force from hydrostatic pressure. This force is sufficient to, if necessary, check the closure of the circulation openings 2. If necessary, to conduct repeated hydraulic fracturing on a closed coupling, a cuff packer is lowered into the well to the installation location of the hydraulic fracturing coupling. The packer cuffs provide an airtight cavity in the area of the hydraulic fracturing sleeve. Pressure is created in the insulated cavity of the pipe. The liquid under pressure enters the cavity A. The pressure acting on the annular area S (the area limited by the diameters D and D1) of the differential movable sleeve 6 creates an axial force exceeding the holding force of the retainer 5. The cavity A is filled with a working fluid, and the air in the cavity B is compressed to a pressure of 0.5 ... 0.8 MPa. The differential movable sleeve 6 is shifted towards the bottom, combining the radial holes 7 and the circulation holes 2 of the housing 1, and is fixed from axial movement by the retainer 5 in the annular groove 4 of the housing 1, after which the proppant is pumped.

This technical solution allows you to re-open the circulation holes without releasing the key.

The implementation of the hydraulic fracturing sleeve with a differential movable sleeve with hermetic cavities filled with air under atmospheric pressure allows cementing the annulus of the well, opening all the circulation holes and closing and opening the circulation holes many times if necessary.

The hydraulic fracturing coupling has passed factory tests and has shown its performance.

Claims (6)

1. Clutch for hydraulic fracturing (hydraulic fracturing), consisting of a hollow cylindrical body with circulating holes made in it, in which a differential movable sleeve with radial holes is installed, in the initial position it covers the circulation holes of the body and is fixed relative to the latter by a latch, characterized in that for at least one bursting disc is installed in the separation of the inner cavity of the coupling and the cavity between the differential movable sleeve and the housing for axial movement of the sleeve, and annular ledges are made on the inner surface of the differential movable sleeve for axial movement with a key with dies containing grooves for engagement with the annular ledges. 2. The hydraulic fracturing sleeve according to claim 1, characterized in that for guaranteed movement of the differential movable sleeve, even after cementing the well, the cavity above the membrane and the cavity for axial movement of the differential movable sleeve are sealed to each other and filled with air under atmospheric pressure. 3. The hydraulic fracturing sleeve according to claim 1, characterized in that the retainer of the differential movable sleeve is made of a split elastic ring with predetermined bias forces to open and close the circulation holes. 4. The hydraulic fracturing clutch according to claim 1, characterized in that after opening the circulation holes and installing the differential movable sleeve on the retainer, the air cavity to move the differential movable sleeve remains tight, which allows multiple opening and closing of the circulation holes of the coupling, and the remaining volume provides the specified air pressure for damping the stroke of the differential movable sleeve when opening and a predetermined additional force for shifting the differential movable sleeve when closing. 5. The hydraulic fracturing sleeve according to claim 1, characterized in that the annular groove for fixing the differential movable sleeve and the latch in the closed position of the circulation holes are made in an airtight cavity. 6. The hydraulic fracturing sleeve according to claim 1, characterized in that the re-opening of the circulation holes is carried out by increasing the pressure inside the liner, and closing is performed with a key with dies containing grooves for engagement with the annular ledges in the differential movable sleeve.

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