EA032471B1 - Complex for geophysical and hydrodynamic exploration of producing horizontal wells - Google Patents

Abstract

A complex according to the invention is designed as an assembly lowered along tubings (1) connected by collars (2), comprising a logging cable (3), a propeller (4), a fastening device (5) for fastening the propeller to the logging cable, an extension cord (6), an electric connection device (7) connected to a surveying instrument (8). Mounted between the propeller fastening device (5) and the upper collar (9) of the propeller (4) is a tube tension preventer (10) including a protective element (11) and an emergency withdrawal coupling (12). An emergency withdrawal funnel (13) is mounted in the bottom part of tubings (1). The destroyable protective element (11) is designed so as to become destroyed in case of reaching axial forces that are 20-25 kN lower than the breaking load of the logging cable (3) used. The emergency withdrawal coupling (12) has a cross-like cross-section with a rib diameter exceeding the inside cross-section of the emergency withdrawal funnel (13). The tubular part of the electric connection device (7) includes a circulation valve (18) to provide pumping of borehole fluid through a contact cable head (19) fixed on the logging cable (3). The technical result of the invention is broadening of functional capabilities due to elimination of emergency situations with tubings, the instrument and the cable and related to withdrawal of the devices - the logging cable, the instrument and the tubings - in case any emergency occurs.

Description

The invention relates to the oil and gas industry and can be used for the delivery of logging tools and other devices to the faces of drilled, producing and injection horizontal wells for geophysical and hydrodynamic studies.

State of the art

Known systems with a rigid geophysical cable, combining the necessary flexibility for winding it on standard drums of winch logging hoists, as well as on winches of increased diameter and sufficient rigidity to push devices to the bottom of a horizontal well. Recent cable designs to increase pushing ability include a larger number of steel wire armor braids, an increased thickness of the outer polymer coating layer and, as a result, an increased outer diameter [1].

The disadvantage of this solution is the large diameter of the cable, which can lead to the inability to effectively seal the cable at the mouth at excessive pressures during research. In addition, to work with a large-diameter cable, it is necessary to use special hoisting equipment with a large-diameter drum, which also ensures guaranteed delivery of devices to the faces only in small-diameter wells.

Known geophysical cable, which in addition to current-carrying conductors located in the bulk of the polymer composite material of cylindrical section, is reinforced with glass or carbon fibers located inside the outer shell. Additionally, a steel cable can be located inside the cable, and the outer sheath can be made of a polymer material or gelcoat [2].

This design to create a pushing force requires the additional use of a logging elevator with a rigid geophysical cable, the imperfections of which were mentioned above. In addition, the implementation of the descent and ascent of a piece of polymer cable involves the use of a special injector. These shortcomings will lead to a significant complication and rise in the cost of equipment and the technological process in well surveys, while restrictions on the delivery to the bottom of existing horizontal wells remain, since they ultimately depend on the properties of the rigid geophysical cable.

Known technological complex for geophysical research of deviated and horizontal wells, consisting of a downhole tool, docking nodes of various designs and geophysical cable. Docking nodes, which act as a mover and extension cord, are made respectively of thick-walled and thin-walled pipes, the lower and upper parts of which end with electrical connectors that perform the functions of mechanical and electrical connection of the pipes and the cable passed through them. The complex includes sealing equipment for the wellhead, which also ensures the descent of the device and the connecting units into the well in the presence of excessive wellhead pressure [3].

The main disadvantage of this complex is the low probability of providing reliable electrical communication with the geophysical instrument due to the need to assemble a large number of docking nodes in high humidity conditions at the wellhead. The number of electrical connections in the study of wells with a conventionally horizontal section of the order of 500 m can be 100 or more. In addition, these connectors must be subject to increased requirements for transportation and storage.

Closest to the proposed solution is a complex for the delivery of geophysical instruments according to the patent of the Russian Federation for utility model No. 42062, IPC ЕВВ 47/00, publ. November 20, 04, BI No. 32. The complex contains a geophysical cable, mover and extension cord, a device for carrying out electrical communication in a conductive medium, a device for attaching the mover to the geophysical cable, a container, the mover and extension cord consisting of steel seamless tubing with a diameter of 33 mm, which are lowered into the well by standard technologies, and the container consists of pipes made of non-conductive material.

The disadvantage of this complex is the lack of sealing connected to the cavity of the pipes of small diameter of the housing of the electrical communication device, which does not allow tripping operations of the propulsion and extension cord in wells with excessive pressure at the wellhead.

The specified complex structurally does not allow to exclude breaks in the geophysical cable in the form of puffs and tacks of the geophysical instrument and a string of pipes of small diameter in case of complications in the well during the study. There is also no solution for raising the left suspension from the extension cord and mover with the device using elevator pipes. This can lead to difficult to eliminate accidents due to the abandonment of a geophysical instrument in the well with pipes and a piece of geophysical cable.

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SUMMARY OF THE INVENTION

The technical problem solved by the invention is to eliminate the disadvantages of the prototype, namely the expansion of functionality by eliminating emergency situations with pipes, device and cable and related to the extraction of device elements - geophysical cable, device and pipes in case of emergency.

The above problem is solved using the features specified in claim 1 of the claims common to the prototype, such as a complex for geophysical and hydrodynamic studies of production horizontal wells in the form of an assembly lowered through elevator pipes connected by couplings, including a geophysical cable, mover, mover mounting device to the geophysical cable, an extension cord, an electrical communication device connected to the geophysical instrument, and distinctive salient features, such as between the device For the heating of the propulsion unit and the upper coupling of the propulsion device, a pipe fuse of tension is installed, comprising a safety element and an emergency extraction coupling, while an emergency extraction funnel is installed in the lower part of the lift pipes.

According to claim 2, the collapsible calibrated safety element is structurally designed so that upon reaching axial forces, the values of which are 20-25 kN less than the breaking load of the geophysical cable used, it is destroyed.

According to claim 3 of the invention, the emergency extraction coupling has a cross-section, the diameter of the ribs of which exceeds the internal section of the emergency extraction funnel.

According to claim 4 of the invention, the tubular part of the electric communication device comprises a circulation valve for allowing the borehole fluid to pump a cable contact tip fixed to the geophysical cable.

The above set of essential features allows you to get the following technical result: expansion of functionality due to the elimination of emergency situations with pipes, device and cable and related to the extraction of device elements - geophysical cable, device and pipes in case of emergencies.

List of figures, drawings

The invention is illustrated by a drawing, which shows a diagram of equipment designed for trouble-free performance of geophysical and hydrodynamic studies in production horizontal wells in the presence of overpressures at the wellhead.

The following is information confirming the possibility of carrying out the invention.

The complex for geophysical and hydrodynamic studies of production horizontal wells in the form of an assembly lowered through elevator pipes 1 connected by couplings 2 includes a geophysical cable 3, mover 4, a fastener 5 for the mover to the geophysical cable, an extension cord 6, an electrical communication device 7 connected to the geophysical device 8 (drawing).

Between the attachment device of the mover 5 and the upper clutch 9 of the mover 4, a pipe fuse of tension 10 is installed, comprising a safety element 11 and an emergency extraction clutch 12. An emergency extraction funnel 13 is installed at the bottom of the elevator pipes 1. The collapsing calibrated safety element 11 is structurally designed that when axial forces are achieved, the values of which are 20-25 kN less than the breaking load of the used geophysical cable 3, its destruction occurs. The emergency extraction sleeve 12 has a cross-section, the diameter of the ribs of which exceeds the internal section of the emergency extraction funnel 13.

The complex for geophysical and hydrodynamic studies of production horizontal wells (drawing) includes an electrical communication device 7 in the flushing fluid, the pipe part of which in its upper part is attached to the lower pipe of the extension 6 and contains a check valve 18 in its body. The lower part of the device contains a tip with a threaded connection (not shown in the drawing) and provides a mechanical and electrical connection with the geophysical instrument 8.

As a mover 4 and an extension 6, standard tubing pipes with a nominal diameter of 33 mm are used, the connection of which with each other, an electrical communication device 7 and a pipe fuse for cable tension 10 is made using couplings 12. The mover 4 is mounted above the extension 6 and is designed to create axial forces exceeding the frictional forces arising on inclined and semi-horizontal sections of the wellbore during the movement of the geophysical instrument 8 and extension 6.

The cable part of the electric communication device 7 - the cable contact tip 19 is used for electrical communication with its pipe part and, accordingly, with the geophysical device 8. For this purpose, when tilting the wellbore with zenith angles not exceeding 50 °, the cable contact tip 19 under its own the weight is delivered on the geophysical cable 3 to the reciprocal (pipe) part of the electrical communication device 7. At zenith angles exceeding the specified values, the electrical connection of the contacts of the parts of the device oystva produced by pumping the washing liquid contact tip 19 of the cable.

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The suspension of tubing, consisting of an extension 6 and a mover 4, by means of a mover 5 mounting device, the lower section of which is screwed into the sleeve connection of the pipe strain relief of cable 10, is mechanically attached to the geophysical cable 3. The pipe strain relief of cable 10 serves to release and subsequent rise from the well of the geophysical cable 3 in case of emergency in the form of tacking of the geophysical device 8, mover 4 and extension 6. The design of the pipe fuse the tension of the cable 10, the key element of which is a collapsing calibrated safety element 11, ensures the release of the geophysical cable 3, the upper part of the fuse and the fastening device of the mover 5 when efforts are reached whose values are 20-25 kN less than the breaking load of the geophysical cable 3. parts of the pipe fuse for cable tension 10 emergency extraction couplings 12 of cross-section, the diameter of the ribs of which exceeds the internal section of the emergency extraction funnel eniya 13 is screwed onto the bottom of the lift pipe 1, instead of the coupling 2, can extract propulsion device 4 with an extension 6 and geophysical instrument 8 by lifting the tubing 1.

Installed between the geophysical instrument 8 and the extension cord 6, the tubular part of the electrical communication device 7 includes a circulation valve 18 to allow the borehole fluid to pump the cable contact tip 19 mounted on the geophysical cable 3.

Geophysical studies of producing wells using the present invention are performed in the following sequence. After the installation of the equipment for sealing the mouth 14 and the descent of the elevator pipes 1 connected by the couplings 2, with the start valves installed on them to cause fluid flow with the help of the compressor and the emergency extraction funnel 13, is completed, the preventer 15 and the sealing head 16 are installed (drawing). The preventer 15 contains pipe as well as cable plates designed to seal the pipes of the mover 4 and extension 6, as well as the geophysical cable 3, respectively, the sealing head 14 allows hoisting operations of the mover 4 and extension 6 in the presence of excess pressure on the mouth, including using a special pushing device (not shown in the drawing).

Next, the pipe part of the electrical communication device 7 with the geophysical instrument 8 is connected to the lower pipe of the extension cord 6, after which the device and pipes are lowered into the well using standard technologies. The estimated total pipe length of the mover 4 and extension 6, necessary for delivering the geophysical instrument 8 to the bottom of a particular well, as well as the calculation of the axial forces arising on the geophysical cable 3 when lifting, is determined using the Lateral Calculation - 2007 software product. After the instrument reaches the calculated of depth into the clutch 9 of the upper pipe of the mover 4 mounted on the elevator, the pipe fuse of the cable tension 10 is screwed, and inside the pipes of the mover 4 are placed the geophysical pipe previously passed through the sealant 17 of the cable logging cable 3 cable pin tip 19.

Two methods are provided for electrically coupling the nodes of the cable contact tip 19 and the tubular part of the electric communication device 7, electrically connected to the geophysical device 8, one of which is realized by the weight of the cable contact tip 19 with the geophysical cable 3 and is used in wells with zenith angles, not exceeding 50 °. In cases of work in wells filled with high-density liquid, as well as with trunks with large zenith angles, the descent of the cable contact tip 19 and docking can be carried out by pumping it with the liquid. The circulation is ensured by the circulation valve 18 located in the casing of the tubular part of the electric communication device 7. Operations to lower the geophysical cable 3 with the cable contact tip 19 are performed with a speed limit, the control of which, like the depth measurement, is performed using standard logging station registration systems .

After ensuring electrical connection with the geophysical instrument 8, the pipe string, mover 4 and extension cord 6 are attached to the geophysical cable 3 using the mover 5 mounting device, on which geophysical instrument 8 is lowered to the bottom of the well using standard geophysical equipment and a series of hoisting operations are carried out to produce geophysical research for a given program. Logging data can be recorded both at the descent of the geophysical instrument 8 and during its ascent using standard logging equipment of the logging station.

Studies are completed by lifting using a geophysical cable 3 pipe suspensions with a geophysical device 8 and installing the upper pipe of the mover 4 on the elevator of the coupling 9, after which the device for fastening the mover 5 is detached from the geophysical cable 3 and it is removed from the well with the cable contact tip 19. Next, the pipe fuse of the cable tension 10 is dismantled, after which the mover 4, the extension 6 and the geophysical instrument 8 rise from the well.

In cases of emergencies caused by tacking of the geophysical instrument 8 and pipes, an axial load on the geophysical cable 3 is created using the logging station winch, exceeding the tensile strength of the safety element 11 of the pipe fuse for cable tension 10. After the destruction of the safety element 11, the geophysical cable 3 with the upper part

- 3 032471 of the pipe fuse for cable tension 10, the fastener device 5 and the cable contact tip 19 are removed from the lift pipes 1, as well as from the pipes of the mover 4 and extension 6.

The extraction of the mover 4, the extension cord 6, the tubular part of the electric communication device 7 and the geophysical instrument 8 from the well is carried out by lifting them with lift tubes 1 due to the fixation of the emergency extraction clutch 12 in the emergency extraction funnel 13 remaining in the well.

The pipe fuse for cable tension 10 serves to release and subsequently lift the geophysical cable 3 from the well in case of emergency in the form of tacking of the geophysical device 8, mover 4 and extension 6. The design of the pipe fuse for cable tension 10, the key element of which is a collapsing calibrated safety element 11, provides the release of the geophysical cable 3, the upper part of the fuse and the fastening device of the mover 5 when efforts are reached, whose values are 0-25 kN less than the breaking load of the used geophysical cable 3. The presence in the lower part of the pipe fuse of the cable tension 10 of the emergency extraction sleeve 12 of a cross-section, the diameter of the ribs of which exceeds the internal section of the emergency extraction funnel 13, screwed onto the lower elevator pipe 1 instead of the connecting sleeve 2, allows you to remove the mover 4 with an extension 6 and a geophysical instrument 8 by lifting the elevator pipes 1.

From the description and practical application of the present invention, other particular forms of its implementation will be apparent to those skilled in the art. This description and drawings are considered as material illustrating the complex, the essence of which and the scope of patent claims are defined in the following claims, a combination of essential features and their equivalents.

Information sources:

1) Kryuchatov D.N., Khalilov D.G., Savich A.D., Budnik D.A. Improving the technology of geophysical exploration of horizontal wells // NTV Karotazhnik. - Tver: Ed. AIS, 2016. - Issue. 10 (268), p. 16-29.

2. RF patent for the invention No. 2585655, IPC Н01В 7/04, publ. 06/10/16, BI 16.

3. RF patent for the invention No. 2491422, IPC ЕВВ 47/01, publ. 08/27/13, BI 24.

Claims (4)

CLAIM 1. Complex for geophysical and hydrodynamic studies of production horizontal wells, lowered through elevator pipes (1) connected by couplings (2), including a geophysical cable (3), mover (4), attachment device (5) of mover to geophysical cable, extension cord ( 6), an electrical communication device (7) connected to a geophysical instrument (8), characterized in that between the fastener of the propulsion device (5) and the upper coupling (9) of the propulsion device (4) a pipe fuse for cable tension (10) is installed, containing its composition before a safety element (11) and an emergency extraction coupling (12), while an emergency extraction funnel (13) is installed in the lower part of the lift pipes (1), and the emergency extraction coupling (12) is capable of fixing in the emergency extraction funnel (13). 2. The complex according to claim 1, characterized in that the safety element (11) is a collapsible calibrated safety element and is designed so that upon reaching axial forces, the values of which are 20-25 kN less than the breaking load of the applied geophysical cable (3), its destruction. 3. The complex according to claim 1, characterized in that the emergency extraction coupling (12) has a cross-shaped cross section, the diameter of the ribs of which exceeds the internal section of the emergency extraction funnel (13). 4. The complex according to claim 1, characterized in that the tubular part of the electric communication device (7) contains a circulation valve (18) to ensure that the well fluid pumped a cable contact tip (19), mounted on a geophysical cable (3). - 4 032471 .zh l®в®а. ’· Ν" φ>, "<|" · - · 41ι. > ’> C ' X ‘,.,