RU2515669C2 - Slot perforator (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: slot perforator contains a body, a hydraulic cylinder placed in the body, a working unit placed over the working hydraulic cylinder with at least one operating tool and a mechanism transferring efforts from the hydraulic cylinder to the working unit. According to the invention the perforator is equipped with an additional hydraulic cylinder and a mechanism transferring efforts from the hydraulic cylinder to the working unit which are placed in the body below the working unit so that this lower hydraulic cylinder is capable to create additional effort to the working unit directed in the upward opposite direction to the effort generated by the hydraulic cylinder placed above the working unit. The effort generated by the lower hydraulic cylinder is ensured by the action of pressurised liquid coming to it through one or several hydraulic channels made in the perforator body or through a hydraulic system made in the perforator in another way. Invention versions are suggested which include additional working units providing delivery of individual effort to each working unit.

EFFECT: improving operational efficiency and reliability of the perforator.

19 cl, 7 dwg

Description

The proposed group of inventions relates to the field of drilling and operation of wells, in particular to the design of hydromechanical perforators for opening productive formations, and can be used in the construction and repair of wells for various purposes.

There are a large number of hydromechanical devices for perforating wells, the method of operation of which is based on the transformation of the pressure of the working fluid supplied to the device through tubing, into mechanical energy aimed at extending working tools (punches, cutters, cutting discs, etc. ), opening the production casing (RU 2069741 C1, IPC E21B 43/112, 11/27/1996; RU 2274732 C1, IPC E21B 43/112, 04/20/2006; RU 2348797 C1, IPC E21B 43/112, 03/10/2009; RU 115407 U1, IPC E21B 43/114, 04/27/2012). During the operation of these devices, as a rule, problems arise associated with solving the following technical problems: saving the life of pumping units, increasing the productivity of perforators, increasing the reliability of perforators, and reducing wear on parts. The proposed group of inventions is aimed at solving these technical problems.

A device for creating perforation channels in the casing of a well according to patent RU 2395671 C1, IPC E21B 43/112, 07/27/2010, taken as a prototype. The device includes a tubular and supporting housing, a cylinder connected to the supporting housing, in which a working piston with a return spring and a wedge pusher is equipped with working cutters that are capable of longitudinal movement relative to the wedge pusher under the action of the supporting housing, a spool mechanism with a housing installed above cylinder, and an additional return spring, and the tubular body is connected to the piston with the possibility of limited longitudinal movement, characterized in that then the cylinder above the support housing is provided with an annular stop inside, the piston has an outer annular protrusion, and a return spring is installed between the outer piston protrusion and the cylinder annular stop, the tubular body is equipped with an abutment above the piston annular protrusion, and an additional return spring is installed between the emphasis and the piston inside the cylinder , while the housing of the spool mechanism is rigidly connected to the tubular body and provided with a valve seat on top and an unpressurized internal stop at the bottom, and the valve is pressed against the seat to rpusa slide mechanism of the internal lock spring, designed to hold a liquid column, acting on the valve at the perforations.

For ease of assembly and disassembly, the connection of the valve body and the tubular body can be made detachable (for example, on threads). The number of cylinders and their corresponding working pistons is selected from the necessary effort to open the casing of the well: the thicker the wall of the casing is, the more cylinders with working pistons must be used. Unauthorized fluid flows in the device are eliminated by seals.

The prototype device has a high piercing ability, sufficient power and effectively opens the column, however, it has the following disadvantages:

1. The performance of the device in one working cycle is limited to two perforations.

2. If it is necessary to use a large number of hydraulic cylinders with pistons to develop a larger opening force, the wear of the parts on which the force generated by the hydraulic cylinders is concentrated is accelerated, the likelihood of deformation and fracture of the mechanism for transmitting force to working tools is increased, and the reliability of the hammer drill is reduced.

3. When the device is operating at elevated pressures, an increased service life of pumping units is required, which leads to a rise in the cost of perforation.

4. When working at elevated pressures, the load on the tubing also increases, which can lead to depressurization of the tubing and to create an emergency.

The proposed group of inventions can significantly eliminate these disadvantages. The technical result of the proposed group of inventions includes:

1. Improving the performance of a hydromechanical hammer drill without increasing the load on the pumping units and tubing.

2. Saving the resource of pumping units without reducing the performance of the punch.

3. Improving the reliability of the hydromechanical punch by reducing the wear rate of the punch parts, in particular parts that transmit the force generated by the hydraulic cylinders, to working tools, such as wedge pushers, reducing the likelihood of deformation and breakage of these parts.

The specified multifaceted technical result in the proposed group of inventions is achieved by improving the distribution systems of the forces supplied to the working tools of the perforator.

The hydromechanical drill includes a housing, a working hydraulic cylinder located in the housing with a mechanism for transmitting force to the working site of the hammer with working tools located below it. Hereinafter, the description of the coordinates of the "top-bottom", "above-below" are determined based on the vertical position of the drill, which the device usually receives in a vertical well, being lowered there on the tubing string.

According to the invention, the perforator is equipped with an additional hydraulic cylinder and a mechanism for transmitting force to the working unit located in the housing below the working unit with the possibility of creating by this lower hydraulic cylinder an additional force directed upward opposite to the force created by the hydraulic cylinder located above the working unit. In this case, the force created by the lower hydraulic cylinder is ensured by the action of a liquid on it, which flows to it under pressure through a hydraulic system made in a perforator.

Thanks to the additional hydraulic cylinder and the mechanism for transferring force to the working unit located in the housing below the working unit, creating an opposed force on the working unit from below, an increase in the power of the perforator without increasing the load on the pump unit and tubing is provided, while the force on the working unit is distributed and leveled, absence increased concentration of effort on the upper parts of the working unit leads to an increase in the service life of the parts, to a decrease in their wear. The distribution of effort allows you to increase the number of working tools of the working unit, thereby increasing the performance of the punch, or with the same number of working tools to reduce the load on the pump unit and, accordingly, reduce the cost of perforation.

According to a second proposed embodiment of the invention, a hydromechanical hammer drill comprising a housing, at least two working hydraulic cylinders, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinders to the working unit, is provided with an additional working unit with one or more working tools located opposite the first one, and hydraulic cylinders with mechanisms for transmitting force to the working units are placed in the housing opposite each other above the upper work of which of the unit and lower than the lower working unit with the possibility of creating opposed forces by the hydraulic cylinders on the working units, while the force created by the lower hydraulic cylinder (s) is ensured by the action on it (them) of the fluid supplied to it (them) under pressure through a hydraulic system made in the punch.

The second embodiment of the invention also allows you to distribute and even out the forces supplied to the working units, with the achievement of the same technical result as in the first embodiment, and also allows to increase the productivity of the hammer drill by supplying it with additional working units.

According to a third of the proposed embodiments of the invention, a hydromechanical rotary hammer, comprising a housing, at least two working hydraulic cylinders, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinders to the working unit, is provided with at least at least one additional working unit with a mechanism for transmitting forces to it, while the additional working unit is located sequentially under the first working unit, and the hydraulic cylinders are placed in the casing above each of the working units with the possibility of creating individual efforts by the hydraulic cylinders on the working units, while the force created by the hydraulic cylinders is ensured by the action of the liquid on them, which flows to them under pressure through a hydraulic system made in a perforator.

The third embodiment of the invention allows to increase the performance of the perforator by supplying it with at least one additional working unit and at the same time distribute the forces supplied to the working units, to increase the reliability of the perforator by placing an individual hydraulic cylinder above each working unit. In contrast to the prototype, which assumes a sequential arrangement of hydraulic cylinders one below the other and the location of the working unit under the combination of hydraulic cylinders, the third of the proposed variants of the invention, due to the hydraulic system for communicating hydraulic cylinders, makes it possible to place hydraulic cylinders under the working unit and, therefore, makes it possible to place additional working units under additional hydraulic cylinders with the submission to each of them an individual effort. The number of hydraulic cylinders and their corresponding working units can be any; it is limited only by the resource of the pump units used and the strength characteristics of the tubing used. The performance of the punch is in direct proportion to the number of working nodes of the punch.

According to a fourth of the proposed embodiments of the invention, a hydromechanical hammer drill comprising a housing located in the housing of at least one working unit, including a hydraulic cylinder, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinder to the working unit, is equipped with at least two additional working units located below the first working unit opposite to it or opposite to each other with the possibility of creating individual efforts by hydraulic cylinders on side nodes, while the force created by the hydraulic cylinders is ensured by the action of liquid on them, which flows to them under pressure through a hydraulic system made in a perforator.

The fourth embodiment of the invention also allows to increase the performance of the punch by supplying it with at least two additional work units, while it is possible to distribute and equalize the forces supplied to the work units, as well as to further increase the reliability of the punch by applying an individual force to each work unit. It is assumed that the number of working units, including a hydraulic cylinder, a working unit with one or more working tools, and a mechanism for transferring force from the hydraulic cylinder to the working unit, can be any, it is limited only by the resource of the pump units used and the strength characteristics of the tubing used.

The device according to any of the options for execution may have working tools of various configurations: cutting discs, cutters, punches (punches). In particular, working tools in the form of punches well proved themselves.

To ensure centering the perforator in the well when performing perforation, as well as to ensure the depth of penetration of the working tool into the column during opening, the working unit of the device according to any of the four embodiments of the invention may contain at least one stop located diametrically with respect to the working tool or diametrically to the vector of the sum of the forces of several working tools.

The device according to any of the embodiments, due to the presence of a hydraulic system, can be equipped with hydromonitor nozzles, which allows immediately after perforation to carry out hydromonitor processing of the bottom-hole formation zone (PZP).

In the second, third and fourth embodiments of the invention, containing at least two working nodes, the working tools of the working nodes can be located one under the other or at an angle to each other, which is achieved, for example, by various phasing of the working nodes.

The inventive device in some possible types of its execution is presented in figures 1-7:

Figure 1 - a possible view of the device according to the first embodiment of the invention in longitudinal section in the working position, where:

1 - building 1,

2 - working hydraulic cylinder,

3 - mechanism of transmission of effort,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator.

Figure 2 - a possible view of the device according to the second embodiment of the invention in longitudinal section in the working position, the working nodes are equipped with stops located diametrically with respect to the working tools, where:

1 - building 1,

2 - working hydraulic cylinder,

3 - mechanism of transmission of effort,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator,

7 - stops.

Figure 3 - a possible view of the device according to the third embodiment of the invention in longitudinal section in the working position, each working node contains two working tools in the form of diametrically oriented punches, there are hydraulic nozzles, where:

1 - building 1,

2 - working hydraulic cylinder,

3 - mechanism of transmission of effort,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator,

8 - hydraulic nozzles.

Figure 4 is a possible view of the device according to the fourth embodiment of the invention in longitudinal section in the working position with the location of the cutting tools at an angle of 180 degrees to each other, where:

2 - working hydraulic cylinder,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator,

9 - work unit.

Figure 5 is a possible view of the device according to the fourth embodiment of the invention in longitudinal section in the working position with the location of the cutting tools at an angle of 180 degrees to each other, where:

2 - working hydraulic cylinder,

3 - mechanism of transmission of effort,

5 - working tools

6 - hydraulic system made in a perforator,

9 - work unit.

6 is a possible view of the device according to the fourth embodiment of the invention in longitudinal section in the working position with a one-sided oriented arrangement of cutting tools, where:

2 - working hydraulic cylinder,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator,

9 - work unit.

7 is a possible view of the device according to the fourth embodiment of the invention in longitudinal section in the working position with a unilaterally oriented arrangement of cutting tools, where:

2 - working hydraulic cylinder,

4 - the working site of the punch,

5 - working tools

6 - hydraulic system made in a perforator,

9 - work unit.

The hydromechanical drill according to the first embodiment (Fig. 1) comprises a housing 1, a working hydraulic cylinder 2 located in the housing 1 with a mechanism 3 for transmitting force to the working assembly 4 of the drill with working tools 5 located below it. The hammer has an additional hydraulic cylinder 2 located in the housing 1 below the working node 4 with the possibility of creating this lower hydraulic cylinder 2 of an additional force directed upward opposite to the force created by the hydraulic cylinder 2 located above the working node 4. In this case, creating emoe lower cylinder 2, is provided by the action of an fluid supplied thereto under pressure through the hydraulic system 6 formed in the punch.

The hydromechanical drill according to the second embodiment (Fig. 2) comprises a housing 1, located in the housing 1, at least two working hydraulic cylinders 2, a working unit 4 with one or more working tools 5, and also a mechanism 3 for transmitting force from the hydraulic cylinders 2 to work unit 4. The rotary hammer is equipped with an additional work unit 4 with one or more working tools 5 located opposite under the first, and hydraulic cylinders 2 with mechanisms 3 for transmitting force to the working units 4 are placed in the housing 1 opposite each other above the upper working node 4 and below the lower working node 4 with the possibility of hydraulic cylinders 2 creating opposing forces on the working nodes 4, while the force created by the lower hydraulic cylinder (s) 2 is ensured by the action on it (them) of the fluid supplied to it (him) under pressure through the hydraulic system 6, made in a perforator. The working nodes 4 can be equipped with stops 7 located diametrically with respect to the working tools 5.

The hydromechanical drill according to the third embodiment (Fig. 3) comprises a housing 1, located in the housing 1, at least two working hydraulic cylinders 2, a working unit 4 with one or more working tools 5, and also a mechanism 3 for transmitting force from the hydraulic cylinders 2 to working unit 4. The hammer is equipped with at least one additional working unit 4 with a mechanism 3 for transmitting force to it, while the additional working unit 4 is located in series under the first working unit 4, and the hydraulic cylinders 2 are placed in the housing 1 sequentially over each of the operating units 4 to generate hydraulic cylinders 2 individual efforts to working nodes 4, wherein the force exerted by the hydraulic cylinders 2, is provided on the action of liquid is supplied thereto under pressure through the hydraulic system 6 formed in the punch. The hammer can be equipped with hydraulic nozzles 8.

The hydromechanical rotary hammer according to the fourth embodiment (Figs. 4-7) comprises a housing 1, located in the housing 1, at least one working unit 9, including a hydraulic cylinder 2, a working unit 4 with one or more working tools 5 and a force transmission mechanism 3 from the hydraulic cylinder 2 to the working unit 4. The hammer is equipped with at least two additional working units 9 located below the first working unit 9 opposite to it or opposite to each other with the possibility of creating hydraulic cylinders 2 of individual efforts on the working units 4, and the force created by the hydraulic cylinders 2 is ensured by the action of liquid on them, which flows to them under pressure through a hydraulic system 6, made in a perforator. Working tools 5 of the working nodes 4 can be located one below the other (Fig.6-7) or at an angle to each other (Fig.4, 5), which is achieved, for example, by various phasing of the working nodes 4.

Claims (19)

1. Hydro-mechanical perforator, comprising a housing, a working hydraulic cylinder located in the housing, a working unit located under the working hydraulic cylinder with at least one working tool, and a mechanism for transmitting force from the hydraulic cylinder to the working unit, characterized in that the rotary hammer is equipped with an additional hydraulic cylinder and a mechanism for transferring forces to the working unit located in the housing below the working unit with the possibility of creating this lower hydraulic cylinder of additional force on the working unit directed upward This is due to the force created by the hydraulic cylinder located above the working unit, while the force created by the lower hydraulic cylinder is ensured by the action of the liquid supplied to it under pressure through a hydraulic system made in a perforator. 2. The hydromechanical hammer drill according to claim 1, characterized in that the working tools are made in the form of punches. 3. The hydromechanical hammer drill according to claim 1, characterized in that the working unit contains at least one stop located diametrically with respect to the working tool, or diametrically with the sum vector of the forces of several working tools. 4. The hydromechanical drill according to claim 1, characterized in that it is equipped with hydraulic nozzles. 5. A hydromechanical drill, comprising a housing, at least two working hydraulic cylinders, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinders to the working unit, characterized in that the puncher is equipped with an additional working unit with one or more working tools located opposite under the first, and hydraulic cylinders with mechanisms for transmitting force to the working nodes are placed in the case opposite each other above the upper working node and below the lower working of a node with the ability to create opposing forces by hydraulic cylinders on the working nodes, while the force created by the lower hydraulic cylinder (s) is ensured by the action on it (them) of the fluid, which flows to it (them) under pressure through a hydraulic system made in a perforator. 6. The hydromechanical drill according to claim 5, characterized in that the working tools are made in the form of punches. 7. The hydromechanical drill according to claim 5, characterized in that at least one working unit contains at least one stop located diametrically with respect to the working tool or diametrically with the sum vector of the forces of several working tools. 8. The hydromechanical drill according to claim 5, characterized in that it is equipped with hydraulic nozzles. 9. The hydromechanical drill according to claim 5, characterized in that the working tools of the work units are located one at a time or at an angle to each other. 10. A hydromechanical drill, comprising a housing, at least two working hydraulic cylinders, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinders to the working unit, characterized in that the puncher is provided with at least , one additional working unit with a mechanism for transmitting forces to it, while the additional working unit is located sequentially under the first working unit, and the hydraulic cylinders are placed in the housing sequentially above each of the working unit in with the possibility of hydraulic cylinders creating individual efforts on the working units, while the force generated by the hydraulic cylinders is provided by the action of the liquid on them, which flows to them under pressure through a hydraulic system made in a perforator. 11. The hydromechanical drill according to claim 10, characterized in that the working tools are made in the form of punches. 12. The hydromechanical drill according to claim 10, characterized in that at least one working unit comprises at least one stop located diametrically with respect to the working tool or diametrically with the sum vector of several working tools. 13. The hydromechanical drill according to claim 10, characterized in that it is equipped with hydraulic nozzles. 14. The hydromechanical drill according to claim 10, characterized in that the working tools of the work units are located one below the other or at different angles to each other. 15. A hydromechanical rotary hammer, comprising a housing located in the housing of at least one working unit, including a hydraulic cylinder, a working unit with one or more working tools, and a mechanism for transmitting force from the hydraulic cylinder to the working unit, characterized in that the rotary hammer is provided with at least at least two additional working units located below the first working unit opposite to it or opposite to each other with the possibility of creating individual efforts by the hydraulic cylinders on the working units, while this creates washing with hydraulic cylinders is ensured by the action on them of a fluid flowing to them under pressure through a hydraulic system made in a perforator. 16. The hydromechanical drill according to claim 15, characterized in that the working tools are made in the form of punches. 17. The hydromechanical drill according to claim 15, characterized in that at least one working unit comprises at least one stop located diametrically with respect to the working tool or diametrically with the sum of the forces of several working tools. 18. The hydromechanical drill according to claim 15, characterized in that it is equipped with hydraulic nozzles. 19. The hydromechanical drill according to claim 15, characterized in that the working tools of the work units are located one at a time or at an angle to each other.

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