RU2686761C1 - Method for delivering geophysical instruments into zone for examination of horizontal section of well shaft and device for direct connection for realizing said method - Google Patents

Abstract

FIELD: physics.SUBSTANCE: group of inventions relates to geophysical investigations of inclined and horizontal wells by instruments. Method involves delivery of geophysical instruments to the zone of exploration of the horizontal section of the well shaft using a special "rigid" design cable in the lower part of the suspension for pushing the device. According to the invention, the depth suspension is equipped with an additional pushing facilitating material, in form of a bundle consisting of pipes (drilling string or drilling wells) available on the investigated well, they are preliminary lowered into the well and kept on the wellhead by an elevator, and then lowering through them into the well device on the piece of "hard" cable length exceeding the sum of the length of the horizontal section of the well and the bundle of lowered pipes, and the upper end of the "hard" cable is connected simultaneously to the upper end of these pipes and to the cable tip of the logging cable of the elevator, which delivers this suspension to the examination area, by means of device of hinged connection, wherein pipes-weighting agents are simultaneously and guarantor of withdrawal of "hard" cable with device from horizontal section during emergency separation of logging cable. Hinged connection device for method implementation consists of two cable junctions for various geophysical cables structures, combined in one housing, wherein said separate pipe connection assembly is arranged thereat and has fishing neck in its upper part with grooves for releasing pipe catcher.EFFECT: technical result consists in improvement of reliability of geophysical instruments delivery into the study area.4 cl, 2 dwg

Description

The invention relates to the oil and gas industry, and in particular to devices for conducting geophysical surveys and repair work in inclined and horizontal oil and gas wells with instruments on a geophysical cable.

A technological complex is known based on a continuous flexible metal pipe wound on a lift drum, inside of which a geophysical cable is passed, to which a downhole tool is connected. This complex allows geophysical downhole tools to be delivered to the necessary zones of horizontal wells by pushing them into the wellbore using a lift drum on which a pipe is wound (see, for example, A.G. Molchanov et al. "Underground repair and drilling using flexible pipes ". P. 182-183 M., Publishing House of the Academy of Mining Sciences, 1999).

The disadvantage of such a complex is the high cost of work due to the need to use expensive tripping equipment and components, as well as significant restrictions on the depth of the existing wells under study.

Known technological complex for geophysical studies of inclined and horizontal wells "Lateral" (see, for example, A.D. Savich "Geophysical studies of horizontal wells. Status and problems" Scientific - Technical Gazette "Logic" Issue 2 (191) p. 28- 31 Tver 2010), which allows the study of wells with overpressure at the mouth. The Lateral complex consists of ground equipment, the main units of which are the preventer with pipe and cable dies, sealing head, lubricator, packing cable cleaner, device for forced descent (pushing through) of pipes and downhole equipment: tubing columns (tubing) small diameter, ruggedized geophysical cable, cable clamp for connecting the tubing string to the cable and the device for the implementation of electrical communication between the downhole tool and ground equipment (“wet contact”).

The disadvantage of the complex “Lateral” is the complexity of the design, reduced reliability of the electrical communication node of the downhole tool with surface equipment, the possibility of emergency situations when working using a pushing device, a limited pressure range at the mouth of the existing well, high material costs during the operation of the complex.

A known method of delivering geophysical instruments to horizontal wells, in which the geophysical instrument is lowered into the well and moved in a horizontal wellbore in a protective container for geophysical methods, mounted on the lower end of the drill string. At the same time, drill pipes are used as a propulsion device for moving the geophysical instrument. The method provides high reliability of geophysical surveys of horizontal wells. However, for its implementation it is necessary to carry out the tripping of the drill string, which requires considerable time and material costs. In Russia, this system and its other modifications are known under the name “Horizontal - 1, 2, 3, 4, 5” (see, for example, technology of field-geophysical surveys of horizontal wells. Prospectus NPF “Horizontal”. Ufa).

A known method of delivery of geophysical instruments using cargo suspended on the logging cable above the geophysical instrument (US patent No. 4082144, class EV 21/00, publ. 04.04.1978). The load is made in the form of sections consisting of tubular nozzles interconnected by means of detachable locking elements in such a way that the load sections are freely mounted on the logging cable and, together with the geophysical instrument, are lowered into the open borehole to a predetermined depth. Due to the rigidity attached to the cable, the geophysical instrument moves in the horizontal and curved part of the well. The advantage of the method compared with the known method of delivering instruments on drill pipes is in higher productivity, since no pipe run-up is required, and all operations for the delivery of a geophysical instrument to a horizontal wellbore are carried out using logging equipment.

The disadvantage of this method is low reliability, due to the possibility of sticking cargo with a geophysical instrument in a horizontal wellbore, because the load has a significant mass and requires considerable effort to move it along a horizontal trunk.

Known technological complex for the study of horizontal and inclined wells, removable weighting agent for the geophysical complex (options) and the method of research of horizontal and inclined wells (RF patent №2242034 from 12.01.2004).

The disadvantage of this complex is its complexity and individuality.

A known method of delivery of geophysical instruments in a horizontal well (RF patent No. 2148167 dated 12.26.1997). To deliver geophysical instruments to a horizontal well, a logging cable is strung on a wireline in the form of tubular tips resting on the device, which stiffens the cable, and a load fixed on the cable above the pusher and developing the necessary force to push the instruments along the horizontal shaft. In this case, the pusher and the load is fixed motionless on the cable with clips. Moreover, the tension of the cable between adjacent clips does not exceed the weight of the cut cable, enclosed between these clips.

The disadvantage of this method is low reliability when returning from a horizontal section and the lack of guarantees for the extraction of scattered equipment in the event of a cable break.

There is a method of studying inclined and horizontal wells using a cable of a special "rigid" construction, with the help of which devices are pushed to the bottom of a well (patents of the Russian Federation No. 2105326 dated 01/20/1997 and No. 13888834 dated 12.25.1998). And also known constructions of special geophysical cables for the study of inclined and horizontal wells (RF patents №2087929 from 12.03.1996, №2105326 from 01.20.1997, №2138834 from 12.25.1998, and №2248594 from 27.08.2003 g .) having a multi-layer armored coating and sheaths of polymeric material.

Closest to the claimed inventions are "Geophysical cable for the study of inclined and horizontal wells and method of its use," described in the patent of the Russian Federation No. 2087929 from 12.03.1996. A cable of the proposed “rigid” construction is connected to a serial cable wound on a geophysical lift. Its length should be 30-40% more than the length of the horizontal section of the wellbore. The cable plays the role of an information channel of communication, a load-and-dry and pushing role. If necessary, additional weights may be installed above the reinforced piece of cable.

The disadvantage of the method chosen as a prototype and other known similar methods and devices, is the insufficient strength of the cable to remove the device from the horizontal section of the trunk. It is determined by the strength of the weakest section in the instrument's suspension system, in this case it is the upper thin section or the upper separate piece of cable. It is necessary to take into account the factor that in cable sealing strength is artificially weakened by 25% according to the Regulations for the operation of geophysical cables, because the cable should never be torn along the “body”, i.e. stay above the device and cable lugs to prevent them from blocking access to the fishing instrument.

The objective of the invention is to improve the performance and reliability of studies of inclined and horizontal wells.

The task is achieved by the fact that in the method of delivery of geophysical instruments in a horizontal section of the wellbore, a certain piece of “hard” pushing cable is used in the lower part of the suspension, attaching its upper end to the pipes with the highest possible strength. The weight of the bundle of these pipes is a pushing force, as they advance in the vertical section of the wellbore. These pipes are also the guarantor of reliable pulling out of the “hard” cable with the device from the horizontal section, in case of a break in the geophysical cable in the termination of the tip, on which the instrument-cable-pipe suspension was launched using the “Attachment Device”. Before delivering a geophysical instrument to a horizontal section of the wellbore being repaired, first, drill pipes or tubing pipes located on this well are lowered into the well before installing the liner on them from below. Pipes in the estimated amount of suspended at the elevator. Then, through these pipes, the geophysical instrument is lowered into the well on a piece of “hard” cable that is longer than the sum of the lengths of the horizontal section of the well and the bundles of lowered pipes. The upper end of the cable, where the hinged connection device is filled, is first fixed on a special cable elevator, and then attached to the logging cable. Having lifted the device with a “hard” cable on this cable, they remove the cable elevator, and then the device is attached to the pipes. Thus, the prepared suspension is freed from the pipe elevator and studies are performed. After completion of work, dismantling is performed in the reverse order.

If problems arise during the return stroke of the device in a horizontal section, the standard cable is torn off at the cable lug and lifted. And then on pipes lower, included in a set of research equipment, a pipe catcher and remove the suspension with the device. At the same time, the device and the suspension system do not lose their performance.

In the proposed hinged device, where the joining of two cables and pipes used as cargo, a special node is made to interact with the released pipe catcher. The upper cable to the device is connected via a normal cable connection: cable lug - instrument bridge. For the upper end of the lower cable - reinforced and "hard" and its connection is made as strong as possible, using for this purpose two or more sealing cones with adjustable retaining elements between them. The pipe connection unit is made with the possibility of free rotation with respect to cable transitions to protect cables from kinks and for ease of mounting and dismounting the suspension. At the same time, to improve the reliability of rotation used ball bearing bulk type.

Comparative analysis with the prototype shows that the inventive method differs from the well-known one in that the cable used to push the device, a special “rigid” construction, is first passed through the pipes used as a weighting agent with the device. And then, the upper end, joins the pipes with the greatest possible strength. And only then it joins the hoist cable, on which the instrument suspension is lowered into the study zone of the horizontal section of the wellbore. This solves the technical problem of increasing the reliability of research, ensuring that the instrument with a “hard” cable is pulled out of the horizontal section on these pipes, with a possible breakage of the logging cable. For the implementation of these compounds using a hinged connection device. Thus, the proposed technical solutions meet the criterion of "novelty."

The applicant is not known technical solutions containing similar features that distinguish the proposed solutions from the prototype, which allows to make a conclusion on the compliance of the proposed solutions to the criterion of "inventive step".

The invention is illustrated in the drawing.

FIG. 1 is a diagram illustrating the proposed method. Geophysical instrument 1 into the horizontal section of the bore 2 of the bore 3 is pushed by the “hard” cable 4. The upper end of the “hard” cable 4 is attached as firmly as possible to the hinged connection device 5, which, in turn, is connected via a normal connection: instrument bridge 6 - cable tip 7 on the logging cable 8. Attachment 5 also has a rotating connection node to the pipes 9 and a special fishing neck 10, for a released standard pipe breaker (not shown in the drawing). Tubes 11 are wrapped to the junction 9, used as a load to create a pushing force on a “hard” cable 4, as pipes 11 move along the vertical section of the barrel 12. Moreover, cable 4 with the device 1 is passed through pipes 11 after their installation at the wellhead 3. On the pipes 11, from the lower end, the shank-fairing 13 is installed protecting the cable 4 from damage, and the entire suspension from hooks during descent into the well 3 on a serial logging hoist (not shown) on its cable 8.

FIG. 2 shows the device of the hinged connection in the composition of the deep suspension. The device consists of an instrument bridge 6, from the standard cable lug 7, the continuation of which is the transition 14 to the cable seal housing 15 for the upper end of the "hard" cable 4. The cable fitting housing 15 is made elongated to accommodate two or more rear end cones 16 its nuts 17. Between the sealing cones 16, spacer elements 18 are installed, consisting of a nut-bolt pair with through central holes for the cable cores. The cable seal housing 15 at its lower end has a tapered crackers 19 and a nut 20 for additional fixation of the cable sheath 4 and to protect its lived from twisting. And from the outside, this cable embedment housing 15 has an annular groove 21, which serves as the inner race of the bearing. The role of the outer ring is played by the gap 22 left when connecting the junction of pipes 9 and its fishing neck 10. This connection is made so that the possibility of putting the balls 23 into the bearing, thus built, which serves to give the possibility of mutual rotation of the bundle of cables 4, 8 and pipes 11.

Example of work on the well.

Several mastered tubing workers are lowered into the well, having previously installed, at the lower end, a shank-fairing. The number of pipes depends on the length of the horizontal section of the trunk and the strength of the lift with a cable. Through these pipes, when they are suspended in a state at the elevator, geophysical instruments on a piece of “hard” logging cable are lowered into the well. The length of the "hard" cable must be greater than the sum of the lengths of the horizontal inclined section of the well and the lowered pipes. Then, securing the upper end of the “hard” cable, on which the hinged connection device is embedded, on the cable elevator (not shown in the figure), attach the cable lug from the logging cable. Lift the device on two cables, remove the cable elevator, and attach the attachment to the pipes. Suspension is ready for research. After removing the pipe elevator, the device is delivered to the research area and produce it in normal mode. Dismantling is performed in the reverse order. In case of complications during the reverse course of the device, increasing the load, the cable is cut off at the cable termination and the instrument suspension is lifted on the pipes. Then, installing the suspension pipes on the elevator, complete the instrument lifting on the “hard” cable.

The use of additional pushing force, as well as the use for these purposes of existing (finished) well pipes, allowing them to be installed quickly and without costly, reliable and easy connection of these pipes with cable suspension using a hinged connection device, increase productivity in delivery. devices into a horizontal section of the wellbore.

Thus, the advantage of the proposed method in comparison with the prototype is to increase the reliability and performance of the delivery of geophysical instruments in a horizontal wellbore, thereby increasing the efficiency of their research using methods of field geophysics.

The technical result from the use of the invention is the elimination of emergency situations in the study of inclined and horizontal wells; increased operational reliability; the ability to study inclined and horizontal wells with serial instruments and equipment.

Claims (4)

1. A method of delivering geophysical instruments to the zone of investigation of a horizontal wellbore section using a special “rigid” construction cable in the lower part of the suspension for pushing the device, characterized in that the deep suspension is equipped with an additional weighting agent that facilitates pushing, composed of the test well pipes (tubing or drill), pre-lower them into the well and hold at the mouth of the Elevator, and then lower through them into the well The selection of a piece of “hard” cable longer than the sum of the lengths of the horizontal well section and bundles of lowered pipes is on the piece, and the upper end of the “hard” cable is attached simultaneously to the upper end of these pipes and to the cable lug of the logging cable of the lift that delivers this suspension to the study zone, the aid of the hinged connection device, and the weighting pipes are at the same time the guarantor of pulling out the “hard” cable with the instrument from the horizontal section during an emergency break of the logging cable. 2. A hinged device for carrying out the method according to claim 1, consisting of two cable junctions for various structures of geophysical cables, combined in one housing, characterized in that it also has a separate connection assembly to the pipes, which has a fishing neck in its upper part with grooves for releasing the pipe catcher. 3. The device according to p. 2, characterized in that the node of accession to the pipes has an additional degree of freedom with respect to cable transitions as rotation around their common vertical axis on the thrust ball bearing of a bulk type. 4. Device according to any one of paragraphs. 2, 3, characterized in that the upper end of the "hard" cable to the cable transition is connected to the maximum possible strength using two or more sealing cones with retaining elements installed between them, which are adjustable in length to evenly distribute the perceived load on these sealing cones .

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