RU2785773C1 - Method and setting tool intended for setting a downhole tool using two-stage explosive impact - Google Patents

Abstract

FIELD: petroleum industry.

SUBSTANCE: invention relates to the petroleum and gas industry and is intended for setting downhole tools lowered on a geophysical cable, tubing, or flexible tubing in the course of various process operations. To implement the method for setting a downhole tool using an explosive setting tool, the downhole tool is engaged with the casing pipe walls; the downhole tool is loaded in the course of a single working cycle in two stages. At the first stage, the downhole tool is loaded due to the explosive combustion of the upper charge pellet placed inside the explosive setting tool, so that the gas pressure value required for impact is reached within 1.5 seconds or faster. At the second stage, the tool is loaded so that the pressure value required for impact is reached due to the layer-by-layer combustion of the lower charge pellet also placed inside the explosive setting tool. The explosive setting tool comprises a cylindrical body divided into two sections by a divider, with a rod installed therein concentrically with sealing elements and a power charge consisting of two pellets. The upper pellet provides explosive combustion and is equipped with a longitudinal axial channel for the installation of an explosive cartridge. The lower pellet provides layer-by-layer combustion. The pellets are interconnected by a heat-resistant bandage tape located on the outer surface of the charge.

EFFECT: higher strength of engagement of the downhole tool with the casing pipe and lower wear of mechanical parts of the setting tool.

5 cl, 2 dwg

Description

The invention relates to the oil and gas industry and is intended for the installation of downhole tools descending on a geophysical cable, tubing (tubing) or flexible tubing (CT) during various technological operations.

In the process of testing and operating oil and gas wells, downhole tools are widely used, the installation location of which in the well cannot always be determined in advance. Such tools include, for example, bridge plugs, packers, patches and the like.

Fixation of the downhole tool in the wellbore can be carried out due to the forces of friction between the elastic material and the walls of the casing pipes, for example, in a cone packer, the elastic element acts as a cushion (RF patent No. well pressure of the filling medium (RF patent No. 2128279).

These devices are complex metal structures, laborious to manufacture and install them in the well.

Known methods of closing the wellbore with a solid body using the elasticity of the casing. Fixing the device in the well is provided by irreversible deformation of the solid body at the well overlap, which can occur under the action of explosion energy (for example, RF patent 107545).

Devices of this type can be lowered into the well on a cable or on pipes.

The disadvantage of such devices is that they can be used only once, and as the need to stay in the well is no longer necessary, additional difficulties are created to extract them to the surface.

Another disadvantage is that the packer element is pressed against the walls of the well due to the deformation of the metal, which always has elastic residual deformations, and as a result, when the load is removed from the metal, the force of pressing the elastic material against the walls of the wells weakens, which leads to a violation of the tightness of the packer. In addition, with a long load, the elasticity of the rubber is lost, the pressing force against the borehole walls is reduced, and the tightness of the packer is broken.

Known methods and devices for fixing downhole tools inside the well, based on the engagement of the tool with the casing. For example, described in the patent of the Russian Federation No. 2679197. Said downhole tool has a mandrel, a wedge, a slip block of rams and a pre-installed mechanism. The wedge is located near the mandrel and is slidable relative to the mandrel. The wedge can slide between an unset position and a set position. The slip slip block is connected to the wedge in such a way that when the slip wedge is in the unset position, the slip slip block is in the radial position inside and does not engage with the casing, and when the slip wedge is in the set position, the slip slip block is in the radial position. position outside and engages with the casing.

The disadvantages of the described downhole tool and method include the fact that the slip block rams have a burst clip made of cast iron alloy, and some of the rams become brittle when in contact with the casing, and the engagement area decreases, which leads to a decrease in the coupling properties of the tool with the casing.

A setting tool may be used to provide the load needed to engage the downhole tool with the casing.

Explosive slip packers (VPS) with a landing chamber are known (https://perfoterm.ru/packer_type_vpsh_explosive_packer_shlipsovy), which use a powder charge with a squib.

However, the use of powder charges leads to the need to store them in warehouses of explosive materials, as well as to the complexity of the design and to a small resource of the chamber due to a sharp blow of great force.

There is a known method for installing a downhole tool and a setting tool with a charge with a low burning rate used for its implementation, designed to install bridge plugs, packers, patches, and the like in casing pipes in wells (for example, those described on the website of JSC VNIPIvzryvgeofizika at the link: http:/ /www.vnipivg.ru/filles/news/News16.09.19.pdf).

The disadvantages of the known method and device include incomplete combustion of the charge, which is associated with a low pressure inside the chamber, and, therefore, the landing tool does not reach the specified traction load, and its resource is also reduced due to prolonged exposure to elevated pressures.

The problem to be solved by the claimed invention is to create a method and a reusable landing tool that ensures reliable engagement of the downhole tool with the casing.

The technical result, to which the claimed invention is directed, is to increase the strength of the engagement of the downhole tool with the casing and to reduce the wear of the mechanical parts of the landing tool.

The technical result is achieved by the fact that in the method of landing a downhole tool using an explosive setting tool, including engaging the downhole tool on the walls of the casing pipe, loading the downhole tool in one working cycle is carried out in two stages, at the first stage, the downhole tool is loaded due to the explosive combustion of the upper of the charge block placed inside the explosive landing tool, in which the gas pressure required for the impact is reached in a period of time not exceeding 1.5 seconds, at the second stage, loading is carried out, in which the pressure required for the impact is provided due to layer-by-layer combustion, the lower checker charge, also placed inside the explosive landing tool.

The combustion of the upper checker is initiated by the detonation of the explosive cartridge.

The spread of combustion of the lower checker occurs at a constant speed.

The technical result is also achieved by the fact that in a two-stage explosive landing tool containing a cylindrical body divided by a partition into two parts, with a rod with sealing elements and a power charge concentrically installed in it, the power charge consists of two checkers: the upper checker, which provides explosive combustion , and equipped with a longitudinal axial channel for installing an explosive cartridge, and a lower checker that provides layered combustion, which are connected using a heat-resistant bandage tape located on the outer surface of the charge.

The inventive device makes it possible to perform double loading of the downhole tool in one working cycle.

The first loading due to explosive combustion of the upper part of the charge block leads to an increase in the reliability (strength) of the engagement of the downhole tool with the casing, since a strong impact allows the slips (rams) of the tool to quickly pass through the harder outer layer of the casing. At the same time, a sharp short-term impact has a lower force than in the case of the explosive slip packer described above, which reduces the dynamic load on the mechanical parts of the device compared to known devices, and the resource of the device increases accordingly. Under instantaneous (short-term) loading, the landing tool structural elements do not have time to plastically deform.

Explosive combustion of the upper cartridge is provided by the detonation of the explosive cartridge, which almost instantly raises the pressure in the chamber of the landing tool, which enhances the combustion of the cartridge.

As a result of the faster passage of a stronger outer layer of the casing, the time during which the slips (dies) penetrate into the pipe wall increases, which leads to an increase in the engagement strength.

At a constant low burning rate of the lower plug, rubber seals are compressed, which are present in the design of the downhole tool. In this case, a better seal is achieved, because. under rapid loading, the rubber does not have time to deform (fill all the irregularities in the casing).

The invention is illustrated in the drawings.

In FIG. 1 shows a longitudinal section of a setting tool with a packer plug.

In FIG. 2 shows the design of the power charge.

The landing tool includes a housing 1 with a rod 2 concentrically mounted in it with sealing elements 3, which forms the piston system of this device. A head 4 with sealing elements 5 and a current lead 6 is installed on the rod 2. A tip 7 with sealing elements 8 is installed in the lower part of the rod 2, in which a blind threaded hole is provided for connecting the traction device 9, through which the axial force is transmitted to the downhole tool. A power charge 10 with an explosive cartridge 11 is installed in the upper sealed cavity of the device. The structure is lowered into the well on a geophysical cable, tubing (tubing) or coiled tubing (CT), which are connected through the corresponding head 4 with the indicated means of delivering the device to the place of work.

The power charge 10 (Fig. 2) consists of two checkers: the top checker 12 with a longitudinal axial channel 13 for installing an explosive cartridge 11 and the bottom checker 14, which are connected using a special heat-resistant bandage tape 15 located on the outer surface of the charge 10.

The upper block 12 is made of a material that provides explosive combustion, accompanied by an extremely rapid release of a large amount of energy, causing heating of the combustion products to high temperatures, and a sharp increase in pressure.

The bottom checker 14 is made of a material that provides layer-by-layer combustion, propagating at a constant speed (10 ^-1 -10 ³ cm/s), a constant profile of temperature and concentration. The mechanism of energy transfer and propagation of the process is determined by molecular thermal conductivity: the resulting gases heated to high temperatures as a result of the combustion of a narrow layer of matter heat the next layer and the process is transferred from layer to layer.

The method using the inventive landing tool can be implemented as follows.

Further, the operation of the setting tool will be considered using the example of installing a packer plug in the well.

When the proposed setting tool with a packer plug is lowered into the well to a predetermined depth, an electric current pulse is supplied through the cable, from which the explosive cartridge 11 is detonated, installed in the upper part of the power charge 10, followed by the destruction of the upper block 12 and the explosive combustion of this charge block. Due to this action, in a short period of time, a large amount of gases is released, which pass through the radial holes in the stem 2 of the tool and act on the sealing elements 3 mounted on the stem 2, which in turn move the stem 2 of the tool. Due to this action, the elements of the tool are rapidly moved, which is transferred to the downhole tool (packer-plug) through the traction device 9. Due to the fast loading, a better and more reliable connection of the downhole tool with the wall of the casing occurs. This initial impact is necessary because all casing pipes are seamless and their manufacturing technology produces a thin crust of hardened metal on the inner surface of the pipe, and a good initial impulse is needed to pass it and gain a foothold in the body of the pipe. The amount of pressure required to load the tool, which ensures the penetration of the slips (dies) of the tool through the outer layer of the inner surface of the pipe, is calculated or determined experimentally for each type of pipe.

The burning time of the upper checker is determined by its design (the main indicators are the density of the checker and its mass). It was experimentally found that the maximum value of the burning time of the upper block, the excess of which will lead to a decrease in the efficiency of the method and the landing tool, is 1.5 seconds.

At the second stage of the tool operation, the rod 2 is slowly loaded due to the ignition of the lower checker 14 of the power charge 10 from the combustion products of the upper checker 12 of the power charge 10 and its further layer-by-layer combustion, which has a significantly lower burning rate compared to the volumetric one, at which the same occurs the release of excess gases, which load the tool rod 2, and in which there is a smooth finishing of the downhole tool, which is necessary for compressing the rubber seals of the downhole tool.

Due to the impact of explosive combustion, the elements of the downhole tool (packer-plugs) are rapidly moving, which act on the cone rams. High-strength material is installed in the plug rams, which exceeds the strength of the casing string. Due to the rapid radial loading, the slips penetrate into the body of the casing pipe. At the second stage of the tool operation, when the rod is slowly loaded due to the ignition of the lower plug and its layer-by-layer combustion, the rubber collar of the packer plug is compressed with simultaneous smooth radial movement of the tool rams. Further, at a certain maximum force, the pins are sheared and the plug is detached from the tool. With further free movement of the rod, pressure is released into the internal cavity of the casing string.

Claims (5)

1. A method of landing a downhole tool using an explosive setting tool, including engaging the downhole tool on the walls of the casing, characterized in that the loading of the downhole tool in one working cycle is carried out in two stages, at the first stage, the downhole tool is loaded due to the explosive combustion of the upper checker a charge placed inside an explosive landing tool, at which the gas pressure required for exposure is reached within a period of time not exceeding 1.5 seconds, at the second stage, loading is carried out, at which the pressure required for exposure is provided due to layer-by-layer combustion of the lower charge block, also placed inside the explosive landing tool. 2. The method according to p. 1, characterized in that the combustion of the upper checker is initiated due to the detonation of an explosive cartridge. 3. The method according to p. 1, characterized in that the spread of combustion of the lower checker occurs at a constant speed. 4. Explosive landing tool containing a cylindrical body, divided by a partition into two parts, with a concentrically mounted rod with sealing elements and a power charge, characterized in that the power charge consists of two checkers: the upper checker, which provides explosive combustion and is equipped with a longitudinal axial a channel for installing an explosive cartridge, and a bottom checker that provides layered combustion, which are connected using a heat-resistant bandage tape located on the outer surface of the charge. 5. Explosive landing tool according to claim. 4, characterized in that the lower block ensures the spread of combustion at a constant speed.

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