RU2422617C1 - Procedure for closure of borehole intervals - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: procedure for closure of borehole intervals consists in lowering expendable pipe into borehole. The pipe is equipped with plugging composition on its external surface. This composition expands under influence of external medium into an interval of isolation with successive expansion by means of pressure. Plugging composition is made out of swelling elastomer on base of rubber or poly-urethane and is arranged on sections of the pipe, non-expandable with pressure, while on the expandable sections this composition is applied with thickness not preventing this section complete strengthening. Also, in sections of the pipe, not-expandable with pressure, elastomer does not come out of external radius of the pipe. Prior to expansion by pressure well fluid is replaced with fluid facilitating more efficient elastomer swelling. Upon pressure expansion the expandable pipe is finally expanded mechanically.

EFFECT: simplification of procedure and upgraded quality of closure of reservoirs and leaky sections of casing string.

2 dwg

Description

The invention relates to the oil industry, in particular to methods for overlapping well intervals during the construction and repair of a well.

A known method of local overlapping of the formations, which consists in tightly pressing the expandable pipes to the walls of the well by flaring, after preliminary straightening due to the creation of internal overpressure (G. Abdrakhmanov, Fixing wells with expanded pipes. Training manual. - Samara: ROSING Publishing House, 2003, p. 81-96). In this method, it is possible to increase the efficiency of formation separation by applying a sealing compound based on synthetic rubber or laying raw rubber into the hollows of the profile part of the pipes, followed by pouring with bituminous mastic. In addition, packing elements of oil-, gas-resistant and heat-resistant rubber are applied to the outer surface of the expanded pipes.

The disadvantage of this method is that reliable separation of layers by packer elements is achieved only when they are installed in dense non-cavernous rocks. The use of raw rubber and compounds based on synthetic rubber for sealing is ineffective, since their volume embedded in the hollows of the profile part of the pipe is insufficient to overlap the entire annular space between the open borehole and the expanded pipe after straightening it.

The closest analogue to the proposed technical solution is a method of uncoupling the layers when attaching the wellbore, including lowering the expanded pipe into the fixing interval and straightening it by creating internal overpressure (patent RU No. 2288346, IPC E21B 33/13, published on November 27, 2006 . Bull. No. 33). Airtight chambers are created in the cavities of the hollows of the profile part of the expanded pipe with a radius of the outer shell equal to the radius of the circle described around the expanded pipe, and a quick-setting expanding cement slurry composition is poured into the chambers, which is capable of curing upon interaction with the well fluid.

The disadvantage of this method is that the creation in the cavities of the cavities of the profile of the expanded pipe filled with grouting composition of sealed chambers that would be destroyed when the expansion pipe expanded by pressure is a technically difficult task. Sealing the cavity of the cavity of the expanded pipe by welding a thin metal shell may interfere with the straightening of the expanded pipe by pressure. Plastic containers with grouting that are fixed in the cavity of the cavity of the profile part of the expanded pipes may collapse when the expanded pipe is lowered due to friction against the well walls. In addition, it is difficult to choose the formulation of the cement composition, which, expanding when interacting with the well fluid, is guaranteed to be distributed from the cavity cavities along the entire circular section of the space between the open wellbore and the expanded pipe, and therefore there is a possibility of incomplete sealing of this space and the flow of fluids into vertical direction.

The technical objectives of the proposal are to simplify the method and improve the quality of overlapping formations and leaky sections of the casing by sealing the space between the wellbore (or production string) and the expanding pipe with a swelling elastomer based on rubber or polyurethane.

The technical problem is solved by the method of overlapping intervals of the well, including the descent into the well of the expanded pipe, equipped with a grouting composition on the outer surface, expanding under the influence of the external environment in the isolation interval, followed by pressure expansion.

New is the fact that the grouting composition made of a swelling elastomer based on rubber or polyurethane is placed on non-expandable sections of the pipe, and on expandable sections - with a thickness that does not prevent the full straightening of this section, and non-expandable sections of the pipe are structurally designed so that the elastomer did not extend beyond the outer radius of the pipe; before expanding with pressure, the borehole fluid is replaced by a liquid for the most effective swelling of the elastomer, after the expansion of pressure m ekspandiruemuyu tube extend completely mechanical action.

Figure 1 shows the expandable pipe in the transport position, figure 2 - expandable pipe in the working position.

The essence of the invention is the sealing of the space between the wellbore 1 (or production casing - not shown in FIGS. 1 and 2) and the expanding pipe 2 with an elastomer swelling in the wellbore fluid and reducing the likelihood of fluid flows behind the expanded pipe in the vertical direction. The method is implemented as follows. An expanded pipe 2 is lowered into the planned interval of the well, which has expandable 3 and non-expandable 4 pressure sections (see FIG. 1). After straightening the expandable section 3, the cross section of the expanded pipe 2 takes the form of a circle. Before lowering into the well on the surface of the expanded pipe 2 place a grouting composition of swelling elastomer. The grouting composition of a swellable elastomer is made on the basis of rubber or polyurethane and give it the shape of belts 5 (see figure 1). Belts 5 of the swellable elastomer can be applied in different sizes and configurations. The size, number of belts 5 from the swellable elastomer and the distance between them on the expanded pipe 2 are determined depending on the existing conditions (diameter of the well 1, dimensions of the expanded pipe 2, etc.). Attachment of belts 5 from a swellable elastomer to the expandable pipe 2 is carried out by gluing or vulcanization. The pressure-expandable sections 4 of the pipe 2 are structurally designed so that the elastomer attached to them does not extend beyond the outer radius of the pipe 2. This is done to prevent abrasion and tearing of the belts 5 due to friction against the walls of the well 1 (or production casing - in FIG. 1 and 2) during the descent of the expanded pipe 2. On expandable sections 3 of the expanded pipe 2, belts 5 are attached with a thickness that does not impede the full straightening of these sections.

Existing varieties of elastomer belts 5 selectively swell in a hydrocarbon or aqueous liquid. Belts 5 of an elastomer swelling in a hydrocarbon fluid are used if hydrocarbon fluids are mainly produced through well 1. If the production of the well 1 is substantially watered, use belts 5 of elastomer swelling in a water-based fluid. When producing a water-oil emulsion in the proposed method, it is possible to use an expandable pipe 2, to the surface of which belts 5 of a water-swelling elastomer and an elastomer capable of swelling in a hydrocarbon liquid are simultaneously attached. The choice of the type of elastomer can also be determined by the type of fluid coming from the interval that is blocked by the expansion pipe 2, for example, from a leak in the production string. As belts 5 of an elastomer swelling in a liquid based on water, it is possible to use, for example, belts 5 of a hydrophilic polyurethane, as belts 5 of an elastomer swelling in a hydrocarbon liquid, it is possible to use, for example, belts 5 of rubber compounds based on isoprene rubber. The borehole fluid in the installation interval of the expanded pipe 2 prior to the descent of the latter is replaced with the optimal one for swelling of the elastomer belts 5. For example, if belts 5 of an elastomer swellable in a water-based fluid are used, the wellbore fluid is replaced with fresh water. This is done in order to reduce the swelling time and achieve the maximum degree of swelling of the elastomer belts 5. After the descent into the well 1 in the interaction with the well fluid, a gradual swelling of the elastomer belts 5 occurs. Next, the expansion of the expanded pipe 2 is performed due to the creation of internal overpressure (see Fig. 2). When straightening the expanded pipe 2, the section of the latter takes the form of a circle and is pressed against the walls of the well 1 (or production casing - not shown in Figs. 1 and 2). Belts 5 from a swellable elastomer are subjected to tension simultaneously with the straightening of the expanded pipe 2 and they are pressed against the walls of the well 1 (or production casing - not shown in Figs. 1 and 2). After that, a flare tool is lowered into the well (not shown in FIGS. 1 and 2), with the help of which the expanded pipe 2 is expanded and calibrated along its entire length. The belts 5 from the swellable elastomer continue to swell and cover the remaining gaps in the space between the walls of the well 1 (or the production string — not shown in FIGS. 1 and 2) and the expanded pipe 2. In this case, the probability of overflow of well fluids in the vertical direction in the indicated space reduces to to a minimum. The use of belts 5 from a swellable elastomer greatly simplifies the method, in comparison with the closest analogue, where sealed chambers are used in the cavities of the hollows of the profile part of the expanded pipe filled with grouting composition, in addition, the need to select grouting compounding is eliminated.

An example of practical application in the wellbore.

When drilling a well with a diameter of 215.9 mm at a depth of 380 m in cavernous rocks, a mud absorption zone was identified. Planned overlap of the absorption zone of the expanded pipe 2. The well fluid in the installation interval of the expanded pipe 1 is replaced with fresh water. Expandable pipe 2 was lowered into the well 1 on drill pipes in the interval of the absorption zone. Before being lowered into the well, the surface 5 of the expanded pipe 2 was glued to the surface of the pipe 2 every 0.3 m and glued 5 from the Plow sealing gasket manufactured in accordance with TU 5775-003-96657532- 2008 LLC NPK STREAM (Moscow). Belts 5 are glued with BF-4 glue according to GOST 12172-74. The gasket is a tight tourniquet 26 mm wide and 4 mm thick in gray. The sealing gasket is made of hydrophilic polyurethane, the manufacture of a gasket from the specified material provides swelling upon contact with water. An increase in gasket volume in contact with water for 48 hours is at least 250%. After the descent into the well 1 during interaction with the well fluid, a gradual swelling of the Plow sealing gasket occurs. The expansion pipe 2 is straightened by creating a pressure of 12 MPa in it by pumping the drilling fluid. When straightening the expanded pipe 2, the cross section of the latter takes the form of a circle and is pressed against the walls of the well 1. When straightening the expanded pipe 2, the Plow sealing gaskets are stretched and pressed on the expandable section 3 of the expanded pipe 2 to the walls of the well 1. After that, a flare is lowered in the well 1, by means of which the expanded tube 2 is flared and calibrated along its entire length. In this case, additional stretching and pressing of the belts 5 from the Plow sealing gasket to the walls of the well 1 occurs. The 5 belts of the Plow sealing gasket continue to swell and overlap the remaining gaps in the space between the walls of the well 1 and the expanded pipe 2. At the same time, the probability of downhole overflows fluids in the vertical direction over the specified space is minimized.

Case study example.

During repair of a water injection well with a production casing with a diameter of 168 mm and a perforation interval of 1250-1258 m, leakage of the production casing was revealed. During the repair work, fresh water was used as a process fluid. Geophysical studies have established that the production string is leaking in the interval 1130-1132 m. They planned to block the absorption zone of the expanded pipe 2. Into the leak pipe of the production string 2, the expanded pipe 2 was lowered into tubing 1 in the leakage interval of the production string 2. Before going into the well 1 on the surface of the expanding pipe 2 and every 0.3 m, glue 5 belts from the Plow sealing gasket manufactured in accordance with TU 5775-003-96657532-2008 NPK STREAM LLC (Moscow). Belts 5 are glued with BF-4 glue according to GOST 12172-74. The belts 5 of the sealing gasket are a tight rope 26 mm wide. On expandable sections 3 of the expanded pipe 2, belts 5 are attached with a thickness of 2 mm, on non-expandable sections 4 of the expanded pipe 2, belts 5 are attached with a thickness of 4 mm. After the descent into the well in contact with water, a gradual swelling of the belts 5 from the plow sealant occurs. The expansion pipe 2 is straightened by forcing water into the tubing and creating a pressure of 12 MPa. When straightening the expanded pipe 2, the cross section of the latter takes the form of a circle and is pressed against the production string. When straightening the expanded pipe 2, the belts 5 are stretched and pressed from the Plow sealing gaskets attached on the expandable part 3 of the expanded pipe 5 to the production string. After that, a flare tool is lowered into the well 1, with the help of which the expanded pipe 2 is flared and calibrated along its entire length. In this case, an additional stretching and pressing of the belts 5 from the sealant "Plow" to the production casing occurs. The belts 5 from the Plow sealing gasket continue to swell and cover the remaining gaps in the space between the production string and the expanded pipe 2. At the same time, the probability of downhole fluid flow in the vertical direction along the specified space is minimized.

Thus, in this proposal, the result is achieved — a simplification of the method and an increase in the quality of overlapping of the strata and leaky sections of the casing by sealing the space between the wellbore (or production casing) and the expanding pipe with a swelling elastomer based on rubber or polyurethane.

Improving the quality of sealing the space between the wellbore (or production string) and the pipe being expanded increases the effectiveness of the method by 20-40%. Most significantly, the effectiveness of the method increases when it is used in wells with a run-down production string, where when installing expanded pipes using known technologies, the most often negative result is obtained. The increase in the effectiveness of the application of the method contributes to a reduction of 10-30% in material costs for repeated measures to overlap formations and leaking sections of the casing, which are required when initially receiving a negative result.

Claims (1)

A method of overlapping intervals of a well, including the descent into the well of an expandable pipe equipped with a grouting composition expanding under the influence of the external medium into the isolation interval, followed by pressure expansion, characterized in that the grouting composition made of a swelling elastomer based on rubber or polyurethane, they are placed on pipe sections that are not expandable by pressure, and on expandable sections - by a thickness that does not impede the full straightening of this section, and which are not expandable by pressure ASTK pipe structurally operate so that the elastomer does not go beyond the outer radius of the pipe before expanding pressurized wellbore fluid is replaced on the liquid for the most effective swelling of the elastomer, after expansion pressure ekspandiruemuyu tube extend completely mechanical action.

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