RU2049908C1 - Method for placing cement bridging plugs in wells and device for its realization - Google Patents

Abstract

FIELD: well drilling. SUBSTANCE: method for placing cement bridging plugs in wells includes forced removal of drilling mud from zone of placing cement bridging plug by swabbing with simultaneous cleaning of well walls from mud cake and injection of grouting mortar into formed zone of drilling mud separation. Well is swabbed by self-sealing collar which is fastened to circular piston in the lower part of bailer by means of releasable connection. EFFECT: higher strength and sealing of installed bridging plugs in oil and gas wells. 2 cl, 2 dwg

Description

 The invention relates to the oil and gas industry, to engineering and technology for work in oil and gas wells.

 A known method of installing bridges in wells, according to which a portion of the grouting material is delivered to the interval of installation of the bridge with a grouting shell, lowered on the cable into the well under the drilling fluid, and create a pressure in the grouting shell that exceeds the pressure in the well with a slowly burning charge, which extrudes the grouting material downhole [1] The disadvantages of this method include the need to use special charges to obtain excess pressure, which should be individual flax be selected for each operation to install the bridge and which require the organization of their production, storage and delivery to the place of performance of works.

 Therefore, it is used in limited cases.

 There is also a method of installing bridges in wells, which consists in delivering a portion of the grouting material into the interval of installing the bridge by cable down into the well under the drilling fluid with a grill, with the next creation of artificial bottom by pushing the elastic plug by the hydrostatic pressure of the liquid column in the well and emptying a portion of the grouting raising the cement shell above the artificial face [2] This method allows you to abandon the use of slow grief charges to push the cement material, which greatly simplifies the installation of bridges. The disadvantage of this method is that the cementing material delivered to the bridge installation interval when it is emptied above the artificial face is in contact with the drilling fluid of the well, mixing with it.

 In addition, there is usually a clay peel layer on the wall of the well string that prevents the cement material from adhering to the wall. These factors significantly reduce the efficiency of the bridge installation process.

A device for installing bridges in wells is known, comprising a housing, a head, an air chamber with a piston and a pusher, a baffle bounded by upper and lower baffles with axial and radial openings, having a separator piston in the upper part and an elastic plug filled with grouting material installed under the lower septum [3]
Such a device allows delivering grouting material to the installation area of the bridge, pushing the elastic plug into the casing of the well and emptying the baffle from the grouting material to the artificial bottom from the elastic plug. The disadvantage of this device is that the grouting material flowing out of the device’s borehole is in contact with the drilling fluid in the well and mixed with it, and a layer of clay cake remains on the wall of the casing of the well, which prevents adhesion of the grouting material to the casing of the well, which significantly reduces the strength and tightness of the resulting bridge.

 The aim of the invention is to increase the efficiency of the installation of cement bridges.

 This is achieved by the fact that in the method of installing bridges in the wells, including the delivery of a portion of the grouting material into the interval of installing the bridge by cable down into the well under the drilling fluid with the grouting shell, followed by the creation of an artificial face by pushing the elastic plug by hydrostatic pressure of the liquid column in the well and emptying on it portions of the grouting material by raising the grungy shell over the artificial bottom, carry out piston wells with the formation of a zone the length of the mud column in the interval of installation of the bridge with the simultaneous filling of the separation zone with grouting material.

 The method is implemented by a device comprising a housing, a head, an air chamber with a piston and a pusher, in a chute bounded by upper and lower baffles with axial and radial holes, having a separator piston in the upper part and an elastic plug filled with grouting material, installed under the lower baffle, equipped with a self-sealing a cuff placed above the elastic stopper and connected by a discontinuous connection with an annular piston, which is located in the lower baffle of the baffle.

 The invention consists in the following. The process of installing a bridge in a well includes several stages. At the beginning, a portion of the grouting solution is lowered into the well located beneath the drilling fluid on the cable, during which part of the drilling fluid is displaced by a volume equal to the volume of the grouting shell.

 A portion of the grouting material reaches the installation site of the bridge without mixing with the drilling fluid during transportation due to the baffle, which protects the grouting material from contact with the drilling fluid.

 To ensure accurate installation of the bridge in the required interval of the well, artificial casing is installed in the casing, which prevents the cementing material from lowering if its specific gravity exceeds the weight of the drilling fluid.

 Artificial slaughtering also prevents the mixing of grouting material with drilling fluid during its displacement from the chute. However, the diameter of the cement slurry is less than the diameter of the well casing, therefore, in the gap between the casing and the wall of the well, the drilling fluid is not displaced.

 In addition, the grouting material flows from the choke into a glass of drilling fluid with a jet diameter much smaller than the grouting shell and its further movement will depend on its properties and the properties of the drilling fluid. The grouting material should displace the drilling fluid above the artificial bottom and take its place with reaching contact with the wall of the well. Why cementing material, obviously, should be significantly heavier than the drilling fluid and have such physico-chemical properties that would preclude its mixing with the drilling fluid. Obviously, it is very difficult to comply with these conditions when using widely used materials, such as clay-based drilling mud and cement-based grouting material. When using these materials in this case, mixing of the cement material with the drilling fluid always takes place to a greater or lesser extent.

 This significantly reduces the strength and tightness of the resulting bridge.

 In addition, there is still such a very significant factor as the formation of a clay crust falling on the wall of the well, which is a barrier preventing the contact of grouting material with the wall of the well.

 Obviously, it is not possible to remove the clay crust by simply replacing the drilling fluid with grouting material. In this case, the bridge installed in the well, even if it has a solid internal structure, will not withstand the load from the pressure drop and ensure the tightness of the separation of the well. Therefore, when using the known method of installing bridges in wells, it is necessary to repeatedly increase the height of the installed bridge, but this also does not always guarantee the efficiency of well separation.

 According to the proposed method, after installing artificial slaughter in the process of displacing cement slurry from the borehole of the cement slurry, the well is pistoned to form a zone of separation of the mud column in the interval of installation of the bridge into which the grouting material is fed. Pistoning provides not only the formation of a material interface, but also mechanically cleans the borehole wall from clay cake or other deposits. It excludes not only the possibility of mixing the grouting material with the drilling fluid, but also the contacting of the media with each other. In this case, the natural strength of the stone after hardening of the grouting mortar and full adhesion to the wall of the well over the entire contact surface are ensured.

 This allows you to reduce the requirements for the properties of the grouting material used to install the bridge and the borehole of the working fluid from the point of view of preventing their mutual influence on the quality of the installation of the bridge, there is also no need for an auxiliary operation to prepare the wall of the well for the installation of the bridge in order to reduce the influence of the clay cake on the quality of the installation the bridge.

 In addition, the required installation height of the bridge is significantly reduced from the conditions of its strength and tightness, which allows not only to reduce the consumption of grouting material, but also to provide a higher quality of the study of the geological section, especially when testing reservoir formations, including low-power interlayers.

 The design of the device for implementing the method is also simplified, its length is reduced. This helps to reduce the metal consumption, simplify operation and improve the patency of the device in the well, during the descent in the interval of installing the bridge or lifting it to the surface.

 In FIG. 1 shows a diagram of a device for implementing the method; figure 2 the position of the elements of the device at the initial moment of pistoning of the well and injection of grouting material into the zone of separation of the liquid column in the well.

 The device consists of a head 1, in which an explosion chuck 2 is mounted, connected to a logging cable 3 embedded in the head 1. The head 1 is connected in a known manner to a body 4 having an air chamber 5 in which a finger 6 with a deep hole 7 and a piston are placed 8 with a pusher 9. The housing 4 is connected to the choke 10 having a radial hole 11. In the choke 10 there is a piston-separator 12 with a valve 13. The choke 10 has an upper baffle 14, a lower baffle 15, in which an annular piston 16 is installed and filled with grouting material 17.

 The annular piston 16 in the upper part has a seat 18, and in the lower part a hollow rod 19 on which a self-sealing sleeve 20 with a ring 21 is installed. The sleeve 20 is fixed on the rod 19 by a discontinuous connection with a pin 22. The lower part of the rod 19 abuts against an elastic tube 23, installed under the cuff 20, in the sealing lower end of the choke 10. Above the cuff 20 there is a radial hole 24. The device is lowered into the casing 25 of the well, filled with drilling fluid 26.

 The device operates as follows. The device is lowered on a wireline 3 into the casing 25 under the drilling fluid 26 in the lower part of the installation interval of the bridge. During the descent, the radial holes 11 and 24 provide pressure equalization in the cavity of the device above the piston 12 and under the piston 16. Then, an electric impulse is supplied via cable 3, which causes the explosion cartridge 2. The finger 6 is destroyed by the explosion and the air chamber communicates through the hole 7 with well space.

 The hydrostatic pressure of the mud column 26 affects the piston 8, under which atmospheric pressure remains. The piston 8 moves down and pusher 9 presses on the separator piston 12, which moves the grouting material 17 downward. Moving the grouting material 17 causes the annular piston 16 to move downward until it stops against the lower baffle 15. The hollow rod 19 pushes the elastic plug 23 and simultaneously carries down and self-sealing cuff 20, which is mounted on the rod 19.

 In this case, the elastic plug 23 and the sleeve 20 exit from the bottom of the choke 10 and are installed in the casing 25. Then, the wireline cable 3 is tensioned, which causes the device to move upward. In this case, the self-sealing cuff 20 also moves upward, and the elastic plug 23 remains in place, acting as an artificial slaughter, and cuts off the drilling fluid 26 from below. The movement of the self-sealing collar 20 provides piston wells, while a pressure drop is created above and below the collar 20, which enhances its interaction with the casing string 25, ensures that the casing 25 is cleaned from the mud core 26, when the collar 20 is dragged along the casing string 25, at the same time, the drilling fluid 26 enters the cavity of the device above the piston by the separator 12 through the hole 11, causing the piston 12 to be forced downward, which leads to the extrusion of the cement material 17 from the choke 10 through the hollow rod 19 and pumping it under a self-sealing cuff 20, where the mud section 26 is formed.

 In the process of extruding the grouting material 17 from the choke 10 under the self-sealing collar 20, when lifting the device and moving the collar 20 in the casing 25, the tension force of the logging cable 3 remains constant.

 When the grouting material 17 is completely extruded from the choke 10, the valve 13 of the piston 12 sits on the seat 18 and blocks the bore of the annular piston 16, while the tension force of the cable 3 increases due to an increase in the resistance to movement of the device in the casing 25. This causes the pin 22 to be cut off and disconnected cuffs 20 with a ring 21 and a rod 19. As a result, the tension force of the logging cable 3 drops sharply, which allows us to judge the end of the installation of the bridge and the transition of the device to the transport position.

 After lifting the device to the surface, it is flushed from the drilling fluid and the remains of grouting material.

 Before re-installing the bridge in the well, the blast cartridge 2, finger 7 are replaced, the piston 8 is raised to the upper position, a new cuff 20 with a ring 21 and a pin 22 is mounted on the rod 19 and pressed into the lower part of the bobbin 10 together with the plug 23. Then the flap is filled with grouting material 17, the piston-separator 12 is installed and connected to the housing 4.

 As an example of the implementation of the method, we can cite the experimental data on the installation of bridges in the well produced during the testing of a gas object represented by several layers of small power within 3-15 m, separated by impermeable tires with a height of 3 to 5.5 m.

 The sampling interval was at a depth of 3887-4138 m.

An exploratory well with 140 mm casing was filled with clay-based drilling mud weighted with barite to a density of 1.93 g / cm ³ .

 After opening the casing of the well in the interval 4134-4138 m and causing inflow through the tubing string, it was necessary to install bridges based on cement Portland cement with a height of not more than 3 m.

When installing a bridge of cement material with a density of 1.98 g / cm ^{3 in a} known manner with a height of 3 m, and loading it with a string of tubing, it was found that it does not withstand the load from the weight of the pipes. This suggests that the bridge has no adhesion to the well string.

 After removing this bridge, work was done to install a new bridge in a known manner with a height of 10 m. However, when testing the newly installed bridge for strength, it was found that with a load of 5.5 tons it also began to move, which indicated its unsatisfactory strength.

 After removing it from the well, the bridge was installed according to the proposed method with a height of 2.5 m from the same grouting material. Testing this bridge for strength showed that it can withstand a load of 12 tons of tubing string and a pressure drop of 10 MPa. Further work on testing the facility in the aforementioned well was carried out with the installation of bridges of the proposed method. In the process of testing, 17 bridges with a height of 1.2-3.5 m were installed. All bridges were installed in one run of a cement slurry and had satisfactory parameters for strength and tightness.

 The installed bridges provided the technical ability to test the facility and obtain the required geological information.

The technical and economic advantages of the proposed method are composed of the following factors:
70-80% reduction in the cost of grouting materials when installing bridges;
increase in the well stock where installation of bridges is possible in the process of testing 50-60%
20-30% reduction in time spent on installing a bridge in a well
40-50% reduction in the metal consumption of cement

Claims (2)

 1. A method of installing bridges in wells, including the delivery of grouting shells lowered on the cable, grouting material in the interval of installation of the bridge in the borehole filled with drilling fluid, with the subsequent creation of artificial face by pushing the elastic plug with hydrostatic pressure of the column of borehole fluid and extruding portions of the grouting material on it raising the cement shell above the artificial face, characterized in that in order to increase efficiency by eliminating the mixing of cement of drilling mud and improving its adhesion to the casing of the well, after the creation of artificial bottom hole, the pistoning of the well is carried out with the formation of a separation zone of the mud column in the interval of installation of the bridge with simultaneous filling of the separation zone with grouting material.  2. A device for installing bridges in wells, comprising a housing, a head, an air chamber with a piston and a pusher, located below the chipper, filled with cement material with axial and radial holes and a piston-separator in the upper part, a partition in the lower part with an axial hole for the rod and an elastic stopper located under the partition, characterized in that it is provided with an annular piston located at the bottom of the choke, connected to a rod installed in the transport position with the possibility of interaction with elastic stopper and made hollow, and a self-sealing cuff placed above the elastic stopper and fixed relative to the hollow stem.

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