RU2734193C1 - Shear pressure valve - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to oil industry, in particular to valve devices used for process operations carried out on wells, and can be used to arrange annular space and inner cavity of tubing in well layouts using packer systems during chemical treatment of bottomhole formation zone, as well as in order to inspect tightness of used tubing lifts. Shear pressure valve comprises a body, a working chamber, flushing holes, a valve seat, a shutoff element made in form of a ball, glands, and pins retaining the valve seat. Valve seat is equipped with internal through channel, providing passage of geophysical instruments, and external through channels, which after creation of excess pressure, cutting of pins and movement of valve seat into working chamber together with working chamber and open flushing holes provide fluid circulation between under-packer and above-packer spaces of valve.

EFFECT: wider range of valve devices, allowing for leveling of under-packer and above-packer pressure after carrying out in process operations wells, as well as reduced volume of used killing fluids and reduced duration of performance of technological operations for checking tightness of used tubing lifts prior to treatment of bottomhole zone of well.

1 cl, 3 dwg

Description

The invention relates to the oil industry, in particular to valve devices for technological operations carried out in wells and can be used to organize communication between the annular space and the inner cavity of tubing, technological tubing with wear-resistant locks (TNKT) in wells assemblies using packer systems when carrying out chemical treatments of the bottomhole formation zone of wells, as well as for testing the tightness of the tubing and TNKT lifts used.

The shear pressure valve (KOS), depending on the place of installation in the tubing strings, TNKT is designed to equalize the pressure in the under-packer and above-packer spaces of the well after processing the bottomhole zone (BHT) of the well, enabling technological operations to flush the tubing elevator, TNCT from unused acid composition (CS), replacement of the kill fluid in the well before the packer breaks down, shortening the duration of operations to discharge the wells, facilitating technological operations for the disruption of the used packer equipment after the well completion in cases where there is no injectivity of the treated formation of the well with the valve located above the packer zone, as well as in order to reduce tripping and lifting operations (ROP) in order to check the tightness of the used tubing, TNKT elevator before performing BHT on wells with low reservoir pressure and high reservoir injectivity with a valve located at the lowest point or ft of tubing, TNKT, in under the packer zone.

Known borehole blowout device according to the patent for invention No. 2100570 with a priority of 03.14.1996, consisting of a housing in which a saddle and a cage are installed, having the ability to reciprocate relative to the housing. The cage is made in the upper part with racks and has an axial groove on its outer side. A locking element with a central axial channel and a rotation limiting unit in the form of fingers interacting with the struts is installed on the trunnions. The shut-off element itself has the shape of a ball, from which two lateral ball segments are cut off. These side planes are mutually parallel and equidistant from the central axis of the shut-off element channel.

This device is designed to seal the pipe channel when the design critical flow rate of liquid or gas is reached and does not allow equalizing the above-packer and below-packer pressure after technological operations in oil wells.

Known flush ball valve according to patent No. 2654111 with priority from 30.06.2017, containing a cylindrical body with a stepped hole and a radial outlet (flush) hole. There can be several radial holes. In the bore of the body there is a yoke made in the form of a segment, in which a cylindrical cavity is made for the passage of the flushing fluid with the possibility of connecting to the tubing cavity located above the valve. A saddle is installed in the cavity, a locking element made in the form of a ball, a return spring installed between the adjusting screw and the ball, pressing the ball to the seat. The seat is installed in the cavity bore and is clamped by a threaded bushing. A threaded radial hole is made in the cage coaxially with the radial hole of the housing for the flushing fluid outlet. A screw with a hole for flushing fluid is screwed into the cage through the radial opening of the housing. The screw holds the ferrule radially and axially.

But this device is designed to pass the flushing fluid from the tubing string into the annular space to wash out hydrate plugs and does not allow equalizing the above-packer and below-packer pressure after technological operations in oil wells.

The closest in technical essence is the KCG hydraulic circulating valve known from the Internet source located at https://npf-paker.ru/catalog/type/klapany/ktsg. This valve is designed to organize communication between the annular space and the inner cavity of the tubing tubing in well packer assemblies during the extraction and pumping of fluids and well operation, as well as for equalizing the pipe and annular pressure in the packer equipment assemblies. The KCG valve contains a body, flushing holes, a valve seat, a shut-off element made in the form of a ball. After releasing the ball and creating pressure in the tubing, the seat is lowered, opening the flushing holes through which the fluid is circulated between the pipe and annular spaces.

This device does not allow equalizing the above-packer and below-packer pressures, since the circulation holes are located above the shut-off element made in the form of a ball and with open flushing holes, liquid circulation is possible only in two directions in the upper part between the pipe and annular spaces, and does not allow alignment of the above-packer and below-packer pressures after technological operations in the case when the sub-packer pressure is lower than the above-packer pressure.

The technical result of the claimed invention is to expand the arsenal of valve devices that allow equalizing the above-packer and below-packer pressures after carrying out technological operations in the wells, as well as providing a reduction in the duration of technological operations to check the tightness of the tubing and TNKT elevators used before the BOP.

The claimed technical result is achieved due to the fact that a pressure-testing shear valve containing a body, a working chamber, flushing holes, a valve seat, a shut-off element made in the form of a ball, glands, pins holding the valve seat, and the valve seat is equipped with an internal passageway providing the passage of geophysical instruments, and external flow channels, which, after creating excess pressure, cutting the pins and moving the valve seat into the working chamber, together with the working chamber and open flushing holes, ensure the circulation of liquid between the under-packer and above-packer spaces of the valve. After running the packer assembly, valve on tubing, TNKT into the well and installing the packer in a given interval, the required reagent is injected into the well through the tubing, and geophysical studies are carried out. After injecting a reagent into the well for the purpose of BHT and carrying out the necessary geophysical studies, to prevent the release of the reagent, as well as oil, gas and formation water from the well to the wellhead (surface), it is necessary to create back pressure. In order to create back pressure, well killing fluids of design density are used. Pumping the kill fluid into the well in order to equalize the pressures between the under-packer and annular above-packer spaces as a single system is not possible. For this, the pins holding the valve seat are made in such a way that when the overpressure created by the kill fluid through the shut-off element onto the seat, the valve seat will cut them down, opening the flushing holes. The execution of channels on the lower part of the valve seat and the design of the working chamber with a larger diameter than the outer diameter of the valve seat, provide a gap between the walls of the working chamber and the valve seat, which allows the liquid to circulate freely between the under-packer and annular over-the-packer spaces, providing the necessary result for equalizing the pressures in the above-mentioned spaces ... Installation of a shear pressure test valve under the packer instead of a plug or a pressure test unit provides a reduction in the number of trips or a reduction in the duration of work and a reduction in the volume of well killing fluids used in order to check the tightness of the tubing, TNKT used lift in wells with low formation pressure and high injectivity.

The essence of the technical solution is illustrated by drawings, where figure 1 shows a shear pressure valve 1, valve seat 2, shut-off element 3, oil seals 4, shear pins 5, flushing holes 6, external channels 12, working chamber 13, internal passage channel 14. In figure 2 schematically depicts the installation of a pressure shear valve above the packer, packer 7, the sub-packer space 8, the annular above the packer space 9, the inner cavity of the tubing pipes NTK 10, the lift of the tubing pipes NTK 11. Figure 3 schematically shows the installation of the pressure testing shear valve under the packer , packer 7, sub-packer space 8, annular above-packer space 9, inner cavity of tubing pipes NTK 10, lift of tubing pipes NTK 11.

The device works as follows. With the help of the tubing elevator, TNKT 11, a packer 7 is lowered into the well with a pressure shear valve 1 installed (Fig. 2). Through the internal cavity of the tubing, TNKT 10, the reagent is injected into the well, while the glands 4 ensure tightness and prevent contact of the reagent with the pins 5, and also prevent the reagent from flowing into the annular above the packer space 9 through the flushing holes 6, then, if necessary, into the sub-packer space 8 through the inner cavity of the tubing, TNKT 10 and through the internal passageway 14 of the valve seat 2, geophysical instruments are lowered. After pumping a reagent into the well, and conducting geophysical studies into the inner cavity of the tubing, TNKT 10 is thrown in a shut-off element 3, which, under the action of gravity, is lowered onto the seat 2, blocking the movement of fluid from the inner cavity of the tubing 10 into the sub-packer space 8 through the inner passageway 14 of the valve seat 2, after which a design overpressure is created in the inner cavity of the tubing 10 to shear the pins 5 holding the valve seat 2. Under the action of the overpressure, the pins 5 holding the valve seat 2 are sheared, then the valve seat 2 with the shut-off element 3 moving down to the working chamber 13, opening the flushing holes 6. After moving the valve seat 2 to the lower position, into the working chamber 13, the external channels 12, as well as the gap between the walls of the working chamber 13 and the valve seat 2, ensure the circulation of liquid between the under-packer space 8 and the annular above-packer space 9 ensuring the necessary operations for jamming and flushing the well, thereby ensuring equalization of pressures in the below-packer and above-packer zones and trouble-free retrieval of packer equipment on the tubing lift, TNKT from the well. When installing a pressure shear valve 1 under the packer 7 instead of a plug or a pressure testing unit, (Fig. 3) in this case, the shut-off element 3 is placed in the valve seat 2 and in the process and / or at the end of running the tubing 11 into the well, the tightness of the tubing is checked , TNKT 11 by creating a pressure in the inner cavity of the tubing 10 that does not exceed the design shear pressure of the pins 5 of the valve 1. At the end of the operations to check the tightness in the tubing 11 elevator, excessive pressure is created, due to which the pins 5 holding the valve seat 2, the valve seat are sheared 2 moves into the working chamber 13, opening the flushing holes 6 and thereby makes it possible to carry out treatments of the well formation without additional tripping for removing the plug or pumping the kill fluid into the well in order to push the valve of the pressure testing unit to the surface from the tubing elevator assembly, TNKT 11, which provides a reduction duration and volumes of applied fluids deep sheniya for the purpose of carrying out technological operations to check the tightness of the used tubing elevators before the OPZ.

Claims (1)

Shear pressure valve, containing a body, a working chamber, flushing holes, a valve seat, a shut-off element made in the form of a ball, glands, pins holding the valve seat, characterized in that the valve seat is equipped with an internal passageway that ensures the passage of geophysical instruments, and external through channels, which, after creating excessive pressure, cutting the pins and moving the valve seat into the working chamber, in conjunction with the working chamber and open flushing holes, ensure the circulation of liquid between the under-packer and above-packer spaces of the valve.

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