EA038450B1 - Method to survey horizontal and directional wells (embodiments) and device to implement it - Google Patents

Abstract

The invention relates to oil and gas production from drilling wells, in particular to methods and means of geophysical survey of horizontal and directional wells. The invention is aimed to improve performance of well surveying, reduce accident rate during its realization, and also increase the device reliability. The technical result is the increase of survey quality due to optimal delivery of well logging equipment to the well, and ensuring device functionality at working fluid pressures that exceed the test pressure of production string, and reliable installation of sealing assembly in the body of the jet pump by fixing it at the end of coiled tubing to run the device downhole. If the survey method for horizontal and directional wells is used, prior to the device running, in order to realize the method, it shall be installed on TBG as a part of the jet pump and the packer. Next, the device is run downhole to predetermined depth and set there. A packer is installed within the prepared interval of the production string and the sealing assembly and the logging tool with a sealed cell is run to the coiled tubing, the cell rigidly connecting the tool to the lower end of the coiled tubing to push it until the sealing assembly seats in its seating position in the body of the jet pump. After that the coiled tubing is run further to push the logging tool with a sealed cell to the well to be surveyed. Next working fluid is fed into the cavity between the tubing and coiled tubing to create a depression of needed level against the formation using the jet pump; simultaneously the working fluid is injected to coiled tubing to generate back-up pressure that prevents the damage of coiled tubing; borehole parameters are recorded. Upon finishing the survey, the sealing assembly and the logging tool are extracted from the well. The device to survey horizontal wells contains the body of the jet pump with internal tapering, the packer installed to the coiled tubing and the sealing assembly run to the coiled tubing and connected with it, and the logging tool connected with it through the sealed cell. The jet pump body contains at least one channel with a diffuser and a nozzle located in it, and at least one channel with a backflow valve installed in it which prevents pressure equalization in the annular space divided by the packer. The channel with its diffuser and nozzle is connected with the cavity between the TBG and the coiled tubing. Fixation of the sealing assembly with the coiled tubing is carried out during the device run by breakable attachment to it or to the sealed cell of the logging tool.

Description

The invention relates to the production of oil and gas from boreholes, in particular to methods and means for carrying out geophysical research of horizontal and directional wells.

Known downhole jet installation and its method of operation when logging horizontal wells (patent for invention No. 2239729, publ. 10.11.2004, bull. No. 31).

In the known method, a jet pump with a stepped bore in its housing and a packer with a bore located below the jet pump is lowered into the well on the tubing. When the specified depth is reached, the packer is unpacked, which is installed above the studied productive formations. Then, on a coiled tubing with a perforated lower section passed through the sealing unit, a logging tool is placed in the zone of productive formations and installed in the zone of productive formations. During the descent, a sealing unit is installed in the flow channel of the jet pump, and the background values of the physical parameters of the near-well zone of productive formations are recorded in the wellbore by means of a logging tool. Then, a liquid working medium is fed into the nozzle of the jet pump, creating a number of drawdowns of different magnitude in the well space below the packer, and the well flow rate is measured at each drawdown value. After that, measurements are made of the physical parameters of the productive formations and the formation fluid entering the well, moving a logging tool along the latter on a coiled tubing. After completing the measurements, the logging tool is lifted to the surface, the packer is depacked, and the pipe string is lifted with a jet pump and a packer.

The method also makes it possible to carry out an additional study of productive formations, which consists in pumping through a coiled tubing through its perforated lower section into the well of a fluid with anomalous physical properties, for example, with an abnormally high thermal neutron capture cross-section, or performing chemical treatment of the near-wellbore zone of productive formations, crushing chemical reagents into productive strata. Further, a study is carried out by means of a logging tool, both when the jet pump is running and when it is not running.

To implement the method, a downhole jet installation is used, which contains a packer and a jet pump installed on the pipe string. The pump housing contains a nozzle and a mixing chamber with a diffuser, and a stepped passage channel is made and, installed in a stepped passage channel, a sealing unit with an axial channel. A flexible pipe is passed through the axial channel of the sealing unit with the possibility of axial movement relative to the sealing unit, at the lower end of which a logging tool is installed for measuring physical quantities, for example, the electrical resistivity of rocks. The jet pump is installed above the pay zones of the well at a design distance.

The jet pump is made with the following size ratios: the ratio of the diameter of the inlet section of the mixing chamber D _kc to the diameter of the outlet section of the nozzle D _c is from 1.1 to 2.4, the ratio of the mixing chamber length of 1 _hp to the diameter of the inlet section of the mixing chamber D _kc is from 3 to 7, the ratio of the length of the nozzle L _c to the diameter of its outlet section D _c is from 1 to 8, the distance L from the outlet section of the nozzle to the inlet section of the mixing chamber is from 0.3 to 2 diameters of the outlet section of the nozzle D _c , and the angle α of inclination the generatrix of the diffuser to the longitudinal axis of the diffuser is 4 to 14 °.

The flexible pipe from the side of its lower end can be made with holes in its wall, and the outer diameter of the flexible pipe D _rt can be from the outer diameter of the sealing unit D _{g a} value equal to: D _rt <(0.3-0.7) D _g ...

The known jet installation operates exclusively due to the pumping of the working fluid through the annulus, while the pressure of the working fluid in front of the nozzle is limited by the pressure of the pressure of the production string, which in most cases does not exceed 200 atm, which limits the productivity of the device and the technological efficiency of the method for logging horizontal wells.

Flexible tubing (hereinafter CT) is manufactured from specialized low-alloy steels with high bending time, i.e. has a certain elasticity and has a significant curvature when unwinding the coil, therefore, passing through a straight tubing (hereinafter referred to as tubing), due to its own elasticity, it can strongly press against the inner wall of the tubing. When friction against the tubing walls, spiral and sinusoidal bends of the coiled tubing can occur, which leads not only to damage to the coiled tubing itself, but also to damage to equipment, for example, a sealing unit, as well as to its premature stop during the run, which creates conditions for accidents and equipment damage when running coiled tubing.

The objective of the inventions is to improve the manufacturability of the method for researching horizontal and directional wells and to reduce the accident rate during its implementation, as well as to increase the reliability of the device.

The technical result is to improve the quality of research due to the creation of optimal conditions for the delivery of logging equipment to the well, as well as ensuring the operation of the device at pressures of the working fluid exceeding the pressure of the casing of the well, and reliable installation of the sealing assembly into the body of the jet pump due to its fixation at the end of the coiled tubing when the device is running.

The technical result is achieved by the fact that the method for investigating horizontal and directional wells according to the first embodiment consists in the fact that before running the device for the implementation of the method, it is mounted on the tubing. Then the device is lowered into the well to a predetermined depth and the binding is carried out. Next, the annular space in the prepared interval of the production string is sealed and the sealing unit and a geophysical device with a sealed element are lowered onto the CT, by means of which it is connected to the lower end of the CT, pushing the sealing unit to the seat in the jet pump included in the device. After that, the coiled tubing is further lowered, advancing the geophysical tool with a sealed element to the section of the well to be investigated. Then, the working fluid is fed into the cavity between the tubing and the coiled tubing, creating a depression on the formation of the required value with a jet pump, at the same time, the working fluid is injected into the coiled tubing, creating a back pressure that prevents its damage, and the well parameters are recorded. After completion of the study, the sealing assembly and the geophysical tool are removed from the well.

An umbilical cord can be used to lower the containment assembly and a geophysical instrument with a sealed element.

If necessary, after delivery of the geophysical tool to the section of the well to be surveyed, a background recording of well parameters is performed.

The need for fluid injection into the coiled tubing cavity during the operation of the jet pump is determined based on the well conditions and reservoir properties. If no plan to create high depressions working fluid discharge pressure to the jet pump _jets P NN _and from _about through a cavity between the coiled tubing and may be in the range:

Ropress of ex-casing ^ Pstrojn.pump ^ Pcamping, that is, a situation is possible when the jet pump operates at a pressure exceeding the pressure of the production casing pressure, but there is no danger of damage to the coiled tubing by this pressure.

In this case, the technical result is achieved by the fact that the method for studying horizontal and directional wells according to the second embodiment consists in the fact that before running the device for implementing the method, it is mounted on the tubing. Then the device is lowered into the well to a predetermined depth and the binding is carried out. Next, the annular space in the prepared interval of the production string is sealed and the sealing unit and a geophysical device with a sealed element are lowered onto the CT, by means of which it is connected to the lower end of the CT, pushing the sealing unit to the seat in the jet pump included in the device. After that, the coiled tubing is further lowered, advancing the geophysical tool with a sealed element to the section of the well to be investigated. Then, a working fluid is fed into the cavity between the tubing and coiled tubing, creating a depression on the formation of the required value with a jet pump. Next, the downhole parameters are recorded. After completion of the study, the sealing assembly and the geophysical tool are removed from the well.

An umbilical cord can be used to lower the containment assembly and a geophysical instrument with a sealed element.

If necessary, after the delivery of the geophysical tool to the section of the well to be surveyed, there is a background record of well parameters.

The device for implementing the method of exploration of horizontal and directional wells contains a jet pump mounted on tubing with a seat for a sealing unit, an element that seals the annulus, and a sealing unit connected to it and also connected to it through a sealed element by a geophysical device. The jet pump has at least one channel with a diffuser and a nozzle placed in it and at least one channel with a check valve installed in it, preventing equalization of pressure in the space separated by an element for sealing the annular space. In this case, the channel with the diffuser and the nozzle is connected to the cavity between the tubing and coiled tubing.

In addition, coiled tubing can be metal or polymer, and umbilicals can also be used.

The seat for the sealing unit in the jet pump can be made in the form of an annular narrowing or a narrowing of another configuration, which prevents the further exit of the sealing unit from the jet pump housing in the direction of pushing the CT.

The element that seals the annulus can be made in the form of a packer or stinger.

The connection of the sealing unit with the coiled tubing is made destructible with the possibility of limited axial movement.

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Fixation of the sealing assembly with coiled tubing is carried out when the device is lowered by a destructible fastener with it or with a sealed element of the geophysical instrument.

FIG. 1 shows a general view of a device for implementing a method for surveying horizontal wells, installed on tubing at the time of running a geophysical tool; in fig. 2 - the same, at the time of planting the sealing unit in the jet pump; in fig. 3 - the same, in the working position during the recording of geophysical parameters; in fig. 4 - the same, when supplying the working fluid to the cavity between the tubing and coiled tubing.

The device consists of a jet pump 2 lowered on tubing 1 with a through hole 3, in which a conical narrowing 4 is made in the direction from top to bottom, which is a seat for a sealing unit 6 lowered from the surface on coiled tubing 5 with outer 7 and inner 8 seals. Sealing unit 6 is fixed by means of a destructible attachment 9 on a sealed element 10 connecting the lower part of the coiled tubing 5 with a geophysical device 11 connected to the recording equipment on the surface using a cable 12 laid inside the coiled tubing 5. Geophysical device 11 is separated from the coiled tubing cavity 13 by of the seal 14 located in the hermetic element 10. In the channel 15 of the jet pump 2, the nozzle 16 and the diffuser 17 are installed so that the channel 15 directly connects the nozzle 16 with the cavity 18 formed by the inner surface of the tubing 1 and the outer surface of the coiled tubing 5. In the channel 19 of the jet pump 2 has a check valve 20, which prevents pressure equalization above and below the packer 21 installed below the jet pump 2. The jet pump 2 also has an annular channel 22 connecting the mixing chamber 23 located between the nozzle 16 and the diffuser 17 with the check valve 20. Installed in the well, a device with a packer 21, brought into the working position, forms There are several separate cavities with the borehole walls: above-packer annular space 24, below-packer space 25, cavity between tubing and coiled tubing 18, inner cavity 13 of coiled tubing 5, in which different hydraulic conditions are created during operation of the device.

The device works as follows.

Sealing assembly 6 is lowered into the device, which was lowered on tubing 1 into the well, and with packer 21 brought into working position, a sealing assembly 6 is lowered, fixed with coiled tubing using a collapsing fastener 9. In this case, the destroying fastener 9 is connected to a sealed element 10, which is fixed at the lower end Coiled tubing 5, passing inside the tubing 1. At the moment the sealing unit 6 reaches the constriction 4 in the jet pump 2 stops the sealing unit 6. With further pushing down of the CT 5 and the sealed element 10 with the geophysical device 11, connected to its lower end, the fastening 9 is destroyed (Fig. 3), the sealing unit 6 remains in the jet pump 2. Coiled tubing 5 with the hermetic element 10 and the geophysical instrument 11 is advanced further to the section of the well to be investigated, and the well parameters are recorded. When the working fluid 26 is injected into the cavity 18 between the tubing and the coiled tubing (Fig. 4), it enters the channel 15 and accelerates in the nozzle 16. The resulting ejection leads to the creation of a low pressure region in the mixing chamber 23, and the formation fluid 27 rushes into the mixing chamber 23 , passing first through the check valve 20, and then through the annular channel 22. The working fluid 26 and the formation fluid 27 are mixed in the mixing chamber 23 and, having passed through the diffuser 17, rise to the surface along the above-packer annular space 24. Due to the ejection effect, in the below-packer space 25, a reduced pressure (drawdown) is created, which is necessary for testing the well. In this case, the sealing unit 6, with the outer seal 7 and the inner seal 8, hermetically separates the sub-packer space 25 with the low pressure area from the cavity 18 between the tubing and coiled tubing with a high pressure of the working fluid 26. In addition, the inner seal 8 ensures tightness during the well survey, in which there is a multiple reciprocating movement of the coiled tubing 5 through the seal 8. Under the action of high pressure of the working fluid 26 in the cavity 13 of the coiled tubing 5 by an external pumping unit, fluid 28 is pumped, creating a back pressure supported by the seal 14 of the sealed element 10 and preventing damage to the coiled tubing 5.

The method for investigating horizontal and directional wells according to the first option is carried out as follows. Before lowering the device into a prepared well, the jet pump 2 and the packer 21 are mounted on the tubing 1 in sequence from top to bottom. When installing the device, a sealing unit 6 is fixed with coiled tubing 5 or with a sealed element 10 of a geophysical device 11 with a destructible fastener 9.

Next, the assembly is lowered into the well to a predetermined depth. After fixing the device with a geophysical batch, the packer 21 is installed in a previously prepared interval of the production string. Further, a sealing unit 6 is lowered into the tubing cavity 1, fixed by a collapsing fastener 9 on a sealed element 10. Then the coiled tubing 5 is pushed down to the stop of the sealing unit 6 in the constriction 4 in the through hole 3 of the jet pump 2.

Further, additional force is applied to the coiled tubing 5 in the direction of descent, as a result of which the fastener 9 is destroyed, and the sealing unit 6 remains stationary in the jet pump 2. Coiled tubing 5 with the sealed element 10 fixed at its lower end and the geophysical device 11 continues to move in the direction of the site wells to be investigated.

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Further, a pumping unit located on the surface serves the working fluid 26 under pressure into the cavity 18 between the tubing and coiled tubing, thereby creating a depression on the formation of the required value (Fig. 4).

At the same time, fluid 28 is pumped into the inner cavity 13 of the coiled tubing 5 and backpressure is created to prevent flattening of the coiled tubing 5 by excessive external pressure and the occurrence of an undesirable combination of cavities 18 and 25 and the loss of device operability.

Then, in the section of the well to be investigated, the well parameters are recorded. When examining a horizontal or directional well, if necessary, move coiled tubing 5 with a sealed element 10 and a geophysical device 11 along the investigated area in the required direction.

After completion of the study, the coiled tubing 5 with the sealed element 10 and the geophysical device 11 is moved upward, the sealing unit 6 is removed from the jet pump 2 and the sealing unit 6 and the geophysical instrument 11 are raised to the surface. Then the packer 21 is brought into the transport position and the entire device is raised to the surface.

In the case when the well conditions and / or properties of the formation do not require the creation of high drawdowns by the jet pump or when the jet pump operates at a pressure exceeding the pressure of the casing pressure, but there is no danger of damage to the coiled tubing by this pressure, then the method of studying horizontal and directional wells is carried out according to the second option as follows.

Before lowering the device into a prepared well, the jet pump 2 and the packer 21 are mounted on the tubing 1 in sequence from top to bottom. Next, the assembly is lowered into the well to a predetermined depth. After fixing the device with a geophysical batch, the packer 21 is installed in a previously prepared interval of the production string. Further, a sealing unit 6 is lowered into the tubing 1 cavity, fixed by a collapsing fastener 9 on a sealed element 10. Then the coiled tubing 5 is pushed down until the sealing unit 6 stops in the constriction 4 in the through hole 3 of the jet pump 2.

Further, additional force is applied to the coiled tubing 5 in the direction of descent, as a result of which the fastener 9 is destroyed, and the sealing unit 6 remains stationary in the jet pump 2. Coiled tubing 5 with the sealed element 10 fixed at its lower end and the geophysical device 11 continues to move in the direction of the site wells to be investigated.

Further, a pumping unit located on the surface serves the working fluid 26 under pressure into the cavity 18 between the tubing and coiled tubing, thereby creating a depression on the formation of the required value (Fig. 4).

When implementing the method for investigating horizontal and directional wells according to the second option, injection of fluid 28 into the inner cavity 13 of coiled tubing 5 and creating back pressure to prevent flattening of coiled tubing 5 is not required.

Then, in the section of the well to be investigated, the well parameters are recorded. When examining a horizontal or directional well, if necessary, move coiled tubing 5 with a sealed element 10 and a geophysical device 11 along the investigated area in the required direction.

After completion of the study, the coiled tubing 5 with the sealed element 10 and the geophysical device 11 is moved upward, the sealing unit 6 is removed from the jet pump 2 and the sealing unit 6 and the geophysical device 11 are raised to the surface. Then the packer 21 is brought into the transport position and the entire device is raised to the surface ...

The inventions proposed for patenting will improve the manufacturability and quality of horizontal wells logging due to accurate delivery of measuring equipment to the required sections of horizontal and directional wells, as well as reliable operation of the device, especially in conditions of high pressures.

Claims (12)

CLAIM 1. A device for exploration of horizontal and directional wells, containing a jet pump mounted on a tubing with a seat for a sealing unit, an element that seals the annular space, and lowered onto a coiled tubing (CT) connected to it is a sealing unit and a geophysical device connected to it through a sealed element, while the jet pump has at least one channel with a diffuser and a nozzle placed in it and at least one channel with a check valve installed in it, preventing equalization of pressure in space separated by an element for sealing the annular space, while the channel with the diffuser and the nozzle is connected to the cavity between the tubing and coiled tubing. 2. The device according to claim 1, characterized in that the connection of the sealing unit with the coiled tubing is made destructible. - 4 038450 3. The device according to claim 1, characterized in that the collapsing connection of the sealing unit with Coiled tubing can be made with the possibility of limited axial movement. 4. The device according to claim 1, characterized in that the CT can be metal or polymer, and an umbilical cord can also be used. 5. The device according to claim 1, characterized in that the seat for the sealing unit in the jet pump can be made in the form of an annular narrowing or a narrowing of a different configuration, preventing further exit of the sealing unit from the jet pump housing in the direction of pushing the CT. 6. The device according to claim 1, characterized in that the element sealing the annulus can be made in the form of a packer or stinger. 7. A method for investigating horizontal and directional wells, carried out using the device according to claim 1 and characterized in that, before running into the well, said device is mounted on a tubing (tubing) in sequence from top to bottom, after which said device is lowered into the well to a predetermined depth and anchoring is carried out, then the annular space in the prepared interval of the production string is sealed and a sealing unit and a geophysical device with a sealed element are lowered onto the coiled tubing (CT), by means of which it is connected to the lower end of the CT, pushing the sealing unit to the seat in the jet pump, which is a part of the device, after which the coiled tubing is further lowered, advancing the geophysical tool with a sealed element to the section of the well to be surveyed, then a working fluid is fed into the cavity between the tubing and coiled tubing, creating a depre Session to the formation of the required size, at the same time, the working fluid is injected into the coiled tubing, creating a back pressure that prevents its damage, and the well parameters are recorded, after the completion of the study, the sealing unit and the geophysical device are removed from the well. 8. The method of exploration of horizontal and directional wells according to claim 7, characterized in that an umbilical cord can be used to lower the sealing assembly and a geophysical device with a sealed element. 9. The method for surveying horizontal and directional wells according to claim 7, characterized in that after the geophysical tool is delivered to the section of the well to be surveyed, a background recording of well parameters is performed, if necessary. 10. A method for investigating horizontal and directional wells carried out using the device according to claim 1 and characterized in that, before running into the well, said device is mounted on a tubing (tubing) in sequence from top to bottom, then it is lowered into the well on a predetermined depth and the binding is carried out, then the annular space in the prepared interval of the production string is sealed and the sealing assembly and the geophysical instrument with a sealed element are lowered onto the coiled tubing (CT), by means of which it is connected to the lower end of the CT, pushing the sealing assembly to the landing places in the jet pump, which is part of the device, after which the coiled tubing is further lowered, advancing the geophysical tool with a sealed element to the section of the well to be surveyed, after which the working fluid is fed into the cavity between the tubing and coiled tubing, creating a depression by formation of the required size, and recording of well parameters is carried out, after completion of the study, the sealing unit and the geophysical device are removed from the well. 11. The method of exploration of horizontal and directional wells according to claim 10, characterized in that an umbilical cord can be used to lower the sealing assembly and a geophysical device with a sealed element. 12. The method for surveying horizontal and directional wells according to claim 10, characterized in that after the geophysical tool is delivered to the section of the well to be surveyed, a background recording of well parameters is performed, if necessary.