CN111287657A

CN111287657A - Rotary steering tool for drilling

Info

Publication number: CN111287657A
Application number: CN202010259457.XA
Authority: CN
Inventors: 周跃云; 范翔宇; 谢炜; 汪丹; 强瑜; 陈林
Original assignee: Sichuan Haist Energy Technology Co Ltd
Current assignee: Sichuan Haist Energy Technology Co Ltd
Priority date: 2020-04-03
Filing date: 2020-04-03
Publication date: 2020-06-16

Abstract

A rotary steering tool for drilling well is composed of a pair of hollow joints with screw head and light tube, and a rolling bearing with a sleeve on its periphery; three hollow windows which are circumferentially arranged are arranged on the outer sleeve, each hollow window is provided with a supporting block, each supporting block is provided with a hydraulic cylinder, and the hydraulic cylinders drive the supporting blocks to extend out along the hollow windows and lean against the well wall by taking the mud pressure difference between the inside and the outside of a drill string as power; when the mud inside and outside the drill stem has no pressure difference, the return spring of the hydraulic cylinder retracts the supporting block; a mud channel is arranged at the connecting part of the upper hollow joint and the lower hollow joint, so that mud in the tool enters the hydraulic cylinder, and the piston is driven to push the supporting block to extend out; the hydraulic cylinder of one of the supporting blocks is also provided with a reversing valve for connecting the hydraulic cylinder of the supporting block with mud in the drill string or mud outside the drill string; the stable inclined drilling mode, the rotary steering mode, the full-closed-up mode and the down-drilling mode can be selected and realized.

Description

Rotary steering tool for drilling

Technical Field

The invention belongs to the field of petroleum drilling tools, and relates to a rotary steering tool for drilling.

Background

The rotary steering drilling system is an advanced directional well and horizontal well trajectory control system developed in the last century abroad, is a technology which must be adopted for high-difficulty well trajectory control such as shale gas horizontal wells and the like, and is an indispensable basic platform for future intelligent drilling (closed-loop drilling). Since this century, rotary guide systems have been extensively developed in various domestic oil fields and institutions, and a series of achievements have been achieved, and many products have passed the identification and acceptance, but no formal products have been put into commercial use because of simple imitation, complex structure, poor reliability and high price.

The implementation of guided drilling mainly depends on guiding tools which are divided into two categories:

1. sliding type guiding tool

The sliding type guiding tool is characterized in that a drill string does not rotate during guiding operation, and the drill string is pushed forwards along a drill bit and slides along a well wall. Sliding guides have a number of disadvantages: the torque and the friction resistance of the drill stem are large; wellbore cleanout is not thorough; slow rate of penetration, etc., but currently predominate.

Directional drilling mostly uses downhole power drilling tools, and the main sliding type guiding tool has: a bent housing motor, an adjustable bent joint, a variable diameter stabilizer and the like. Sliding type guiding tool combination mode: drill string + MWD/LWD + power drill + drill bit.

2. Rotary guide system (RSS)

The rotary steerable tool directly guides the drill bit to drill along a desired trajectory, thereby preventing the drill string from sliding while lying on the borehole wall, allowing the borehole to be cleaned well, while allowing the selection of the appropriate drill bit depending on the formation. This can significantly alleviate or eliminate the disadvantages of sliding guide tools.

The rotary guiding tool mainly comprises: VDS automatic vertical well drilling system, SDD automatic vertical well drilling system, ADD automatic directional drilling system, RSD rotary steering drilling system, RCLS rotary closed-loop drilling system, etc.

At present, the rotary guide tool used in the shale gas market in China is basically monopolized by a few foreign companies such as Schlumberger, Beckhous, Haributton and the like, the tool has excellent performance and high automation degree, but the structure is very complex and the price is very expensive. With the rapid development of the petroleum industry in China, the oil and gas drilling scale is larger and larger, the consumption of drilling tools is very large, and the development of rotary steering tools with independent intellectual property rights to replace imports is urgent.

Disclosure of Invention

The invention aims to develop a rotary guiding tool which has the basic functions of foreign rotary guiding tools, has simple structure, reliable performance and low price to replace import, and the technical scheme is as follows:

a rotary steering tool for drilling comprises a pair of upper and lower concentrically arranged and butted hollow joints, wherein the hollow joints are provided with thread head sections and plain pipe sections which are of an integral structure, the thread head sections of the upper and lower hollow joints are reversely arranged, namely the thread head of the upper hollow joint is arranged above and used for connecting a drill string, and the thread head of the lower hollow joint is arranged below and used for connecting a drill bit; the light pipe sections of the upper hollow joint and the lower hollow joint are respectively provided with a rolling bearing, the periphery of the rolling bearing is provided with an outer sleeve, and the outer sleeve is supported on the rolling bearing; the outer sleeve is provided with three hollow windows which are uniformly arranged in the circumferential direction, each hollow window is provided with a supporting block, each supporting block is provided with a hydraulic cylinder, and the hydraulic cylinders take the mud pressure difference between the inside and the outside of the tool as power and can drive the supporting blocks to extend out along the hollow windows to be attached to the well wall; when the pressure difference between the inner and outer mud of the tool is not generated after the drill is stopped, the return spring of the hydraulic cylinder can enable the supporting block to retract; a mud channel is arranged at the connecting part of the upper hollow joint and the lower hollow joint, so that mud in the tool can enter the hydraulic cylinder to drive the piston to further push the supporting block to extend out; the hydraulic cylinder of one of the supporting blocks is also provided with a reversing valve for connecting the hydraulic cylinder of the supporting block with slurry in the tool or slurry outside the tool, and the hydraulic cylinder provided with the reversing valve is called a controllable hydraulic cylinder; under the drilling working condition, if the reversing valve of the controllable hydraulic cylinder is communicated with slurry in the tool, the three supporting blocks are all in an extending state, the tool is centered, and a steady-slope drilling working mode is realized; if the reversing valve of the controllable hydraulic cylinder is communicated with slurry outside the tool, the supporting block controlled by the hydraulic cylinder is in a contraction state, the other two supporting blocks are in an extension state, the tool deflects in a borehole, and a rotary steering working mode is realized, wherein the deflection direction is the direction of a tool face; under the working condition of stopping drilling, the pressure difference of slurry inside and outside the tool is avoided, and the three supporting blocks are all in a contraction state, so that the fully-closed drill-tripping working mode is realized.

The butt joint end of the upper hollow joint and the lower hollow joint adopts a jaw matching structure, and the upper end of the light pipe section of the lower hollow joint is of a jaw structure; the periphery of the light pipe section of the upper hollow joint is sleeved with a coupling sleeve, the coupling sleeve is tightly matched with the light pipe of the upper hollow joint, an axial key is arranged on a matching surface, the lower end of the coupling sleeve is of a jaw structure and is meshed with a jaw of the light pipe section of the lower hollow joint, and a gap of a meshing part forms a slurry channel leading to the hydraulic cylinder.

A radial positioning pin is arranged on the outer sleeve and points to the upper hollow joint optical pipe section along the radial direction, a limiting shoulder is arranged at the upper end of the upper hollow joint optical pipe section coupling sleeve, and a positioning groove matched with the positioning pin is arranged on the shoulder surface; the upper hollow joint light pipe section is movably matched with the inner ring of the bearing.

The direction of the positioning pin is consistent with the direction of the supporting block driven by the controllable hydraulic cylinder, and represents the tool surface direction of the tool; the shoulder surface of the coupling sleeve of the optical pipe section of the upper hollow joint is provided with a positioning groove matched with the positioning pin, and the direction of the positioning groove is adjusted to be consistent with the direction of a tool surface scribing line in MWD (measurement while drilling) positioned at the upper part of a drill string on the ground before the tool is driven into a well. When the alignment pin is coupled to the alignment key, the tool face orientation measured by the upper MWD is the alignment pin orientation.

The reversing valve is an electromagnetic reversing valve.

The tool is also provided with a pressure sensor for detecting the pressure of the underground slurry as a trigger signal for reversing the electromagnetic reversing valve.

The tool is also provided with a circuit module which comprises a mud pressure detection and data transmission unit and an electromagnetic directional valve execution circuit unit.

And a filter plug is arranged at a slurry inlet of the hydraulic cylinder, so that solid matters in the slurry are prevented from entering a cavity of the hydraulic cylinder.

The rolling bearing is provided with a back cap and a sealing packing, so that the pressure in the drill string is prevented from leaking from the bearing.

The invention has the beneficial technical effects that:

(1) with the drill string rotating, the steering capacity is provided; the system can be matched with a full series of standard formation parameter and drilling parameter detection instruments LWD/MWD to perform required guiding drilling operation, and can send an instruction from the ground to change the control mode of the well track under the condition of not pulling out the drill according to data measured while drilling by the MWD, thereby realizing the conversion of deflecting and stabilizing, realizing rotary guiding by adopting artificial orientation and ensuring smooth well track.

(2) The technical scheme has ingenious conception, simple structure, reliable performance and wide applicable working condition on the premise of having the basic function of the guiding tool, and can be used in a high-temperature well with the temperature of more than 150 ℃. The tool design and manufacture is modularized and integrated, the batch production is facilitated, the price is low, the price is less than one tenth of that of imported tools, the tool is economical and applicable, the defect is that the operation of guide switching is slightly complicated, compared with the great price advantage, the tool is beneficial to overcoming the defect, the expensive imported rotary guide tool is expected to be replaced, the tool not only meets the domestic market demand, but also has wide international market prospect.

Drawings

FIG. 1 is a view showing a structure of the rotary steerable tool

FIG. 2 is a view showing the structure of the upper coupling sleeve and the upper hollow joint in the tool

FIG. 3 is a top view of FIG. 2

FIG. 4 is an enlarged view of the hydraulic system of the controllable hydraulic cylinder

The reference numbers in the figures mean:

1-upper hollow joint; 2-light pipe (light pipe section) of upper hollow joint; 3-upper bearing back cap; 4-upper bearing packing; 5-an upper bearing; 6-positioning pins; 7-a pressure sensor; 8-a circuit module; 9-an electromagnetic directional valve; 10-a hydraulic cylinder body; 11-a piston; 12-a support block; 13-a jacket; 14-a lower bearing; 15-lower bearing packing; 16-lower bearing back cap; 17-light pipe of lower joint; 18-lower joint; 19-positioning shoulder of upper coupling sleeve; 20-upper coupling sleeve; 21-assembling a groove cover plate on the hydraulic cylinder; 22-cover plate screw; 23-the jaw of the upper coupling sleeve; 24-the jaw of the lower joint; 26-a positioning groove; 27-axial key; 28-return spring of hydraulic cylinder; 29-plug of outer mud channel; 30-a pressure transfer hole of the reversing valve; 31-sealing ring of the reversing valve; 32-plug of the inner mud channel.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.

See fig. 1, 2, 3, 4.

The tool comprises an upper hollow joint 1, a threaded head and a light pipe section 2, wherein the threaded head and the light pipe section are of an integral structure, and the threaded head faces upwards and is used for connecting a drill column; the periphery of the light pipe section 2 is sleeved with a coupling sleeve 20, the coupling sleeve 20 and the light pipe section 2 are in interference fit, a matching surface is provided with an axial key 27, and the lower end of the light pipe section 2 is provided with a jaw 23.

The lower hollow joint 18 has a screw head of an integral structure and a light pipe section 17, the screw head faces downwards and is used for connecting a drill bit, and the upper end of the light pipe section 17 is provided with a jaw 24 which is meshed with a lower jaw 23 of the light pipe section 2 to transmit torque.

An outer sleeve 13 is provided around the upper and lower hollow joints 1, 18 and is supported on the light pipe sections 2, 17 by a pair of bearings 5, 14, the upper bearing 5 being provided with a back cap 3 and a packing 4, and the lower bearing 14 being provided with a back cap 16 and a packing 15, to prevent pressure in the tool from leaking out of the bearings. It should be noted that the inner race of the upper bearing 5 is in movable engagement with the light pipe section 2, and relative displacement can occur between the two.

Three hollow windows which are uniformly distributed in the circumferential direction (at intervals of 120 degrees) are arranged on the outer sleeve 13, a supporting block 12 is arranged in each hollow window, each supporting block 12 is provided with a hydraulic cylinder which is used as a driver of the supporting block 12, the hydraulic cylinder extends out or retracts along the hollow window by taking mud in the drilling tool as a pressure medium and utilizing the pressure difference of the mud in the drilling tool and mud outside the drilling tool as power, the supporting block 12 is driven to extend out through a piston 11 of the hydraulic cylinder, and when the mud in the drilling tool and the mud outside the drilling tool have no pressure difference (under the condition of pump stopping), a return spring 28 of the hydraulic cylinder drives the. In addition, the three hydraulic cylinder assembly grooves on the outer sleeve 13 are provided with cover plates 21, and are fixed by bolts 22.

The following description focuses on a specific structure for realizing the guiding function, which is the gist of the present invention.

Of the three cylinders, one is provided with a solenoid directional valve 9, which is referred to as a controllable cylinder. Referring to fig. 3, two mud channels leading into the hydraulic cylinder are arranged on the cylinder body 10 of the hydraulic cylinder, one is communicated with the inside of the tool, the inlet is provided with a filter plug 32, the other is communicated with the outside of the tool, the inlet is provided with a filter plug 29, and the

filter plugs

29 and 32 are used for filtering solid matters in the mud and preventing the solid matters from entering the pressure chamber of the hydraulic cylinder and wearing the piston. The electromagnetic directional valve 9 is a cock structure, a sealing ring 31 is arranged on the matching surface of the valve body and the valve core, and the pressure transfer hole 30 of the electromagnetic directional valve 9 is alternatively communicated with mud in the drilling tool or mud outside the drilling tool by operating the electromagnetic directional valve, so that the supporting block is in an extending or retracting state. This is the first structural point.

The second structural point is that as shown in fig. 1, a radial positioning pin 6 is arranged on the outer sleeve 13, the direction of the positioning pin 6 is consistent with the direction of a support block driven by a controllable hydraulic cylinder from the radial direction, namely, the direction of the positioning pin 6 is the direction of a tool face, and then, referring to fig. 2 and 3, a positioning shoulder 19 is arranged at the top end of the coupling sleeve 20, a positioning groove 26 matched with the positioning pin is arranged on the shoulder face, the direction of the positioning groove 26 is adjusted to be consistent with the direction of a tool face scribing line in the MWD at the upper part of the drill string at the surface before the tool is put into a well, when the positioning pin 6 falls into the positioning groove 26, the outer sleeve 13 and the upper joint 1 are directionally coupled, the relative position between the two is locked, and the direction of the tool face measured by the MWD at the upper part is the direction of the positioning pin.

The tool is further provided with a control circuit module 8 and a pressure sensor 7.

The pressure sensor 7 is used to detect the mud pressure downhole. The control circuit module 8 mainly comprises a mud pressure detection and signal data transmission unit and an electromagnetic directional valve execution circuit unit.

The method of use of the tool is described below. There are three modes of operation. The following are distinguished:

one-drilling and full-closing working mode

A drill bit is arranged on a lower connector 18 of the tool, an upper connector 1 of the tool is connected with a drill string, and the tool is put into a well while drilling the drill string, at the moment, a hydraulic cylinder of the tool has no pressure difference, all three supporting blocks 12 are in a contraction state, and an outer sleeve 13 is hung on the table surface of a positioning table 19 of a coupling sleeve 20 through a positioning pin 6; the jaw 23 of the coupling sleeve 20 is engaged with the jaw 24 of the lower connector for partial stroke; until the bit is down to the bottom of the well, the tool is fully retracted with all three support blocks 12 in the retracted state, before no pumping cycles are initiated.

Second, guide drilling working mode

The guide drilling working mode is the main working mode of the tool and is the key point of the invention, and the specific steps are as follows:

1. a pressure transfer hole of the electromagnetic directional valve is communicated with a slurry channel outside the tool in advance, then the tool is drilled to the bottom, a pump is started to circulate, the controllable hydraulic cylinder is communicated with annular slurry and cannot act, a supporting block driven by the controllable hydraulic cylinder is still in a contraction state, the other two supporting block hydraulic cylinders are communicated with slurry in the tool, the supporting block extends out, and the tool deflects until the three supporting blocks are attached to the wall of the well;

2. and lifting the drill string, wherein the upper joint light pipe 2 is movably matched with the inner ring of the bearing 5, the drill string and the outer sleeve 13 are subjected to relative vertical displacement, and after the travel of the drill string exceeds Y1, the outer sleeve 13 is hung on the shoulder surface of the positioning shoulder 19 of the coupling sleeve 20 by the positioning pin 6, and the outer sleeve 13 and the drill string synchronously ascend.

3. The tool is stopped and the drill string is manually rotated at the surface, when the locating groove 26 on the shoulder 19 is aligned with the locating pin 6, and then the outer sleeve 13 (including the hydraulic cylinder and the support) is rotatedBlock, drill bit), the positioning pin 6 automatically falls into the positioning key groove 26, and at the moment, the outer sleeve 13 and the upper joint 1 realize positioning coupling; it is necessary to explain the following two points, i.e. the lifting stroke y of the coupling of the outer sleeve 13 with the upper joint 1₁Is much smaller than the engaging stroke y of the upper and

lower jaws

23, 24_2，That is, the jaws 23 of the coupling sleeve remain engaged with the jaws 24 of the lower coupling. Secondly, as the three supporting blocks are tightly attached to the well wall during pump starting circulation, the friction force is far greater than that of the positioning pin 6 on the surface of the shoulder 19, and the outer sleeve 13 cannot rotate along with the drill string when the drill string is rotated; the friction force between the supporting block and the well wall is not enough to overcome the gravity of the outer sleeve 13 (including the hydraulic cylinder, the supporting block and the drill bit), and the positioning pin 6 is not influenced to fall into the positioning groove 26.

4. When the positioning coupling is performed, the relative position of the outer sleeve 13 and the drill string is locked, and the positioning pin 6 is consistent with the tool face line of the MWD positioned at the upper part of the drill string, namely, the tool face line of the MWD represents the tool face direction; the pump continues to circulate the slurry and the tool face direction is measured by the MWD.

5. And then manually rotating the drilling tool on the ground to orient, and rotating the direction of the tool face to a position needing orientation.

And 6, after the drilling tool is oriented, continuing to start the pump to circulate, lowering the drill column, enabling the drill bit to slowly contact the bottom of the well, then rotating the drilling tool, and gradually pressurizing to carry out rotary steering drilling. At this point, the locating pin has disengaged from the locating coupler and the MWD has no toolface orientation. During drilling, the outer sleeve 13 slides downwards along the well wall through the supporting block and is synchronous with the downward movement of the drill string, but the friction force between the supporting block and the well wall is far greater than that of the bearing, so that the outer sleeve 13 cannot rotate all the time, namely, after the direction of the tool face is set, the outer sleeve cannot change in the drilling process.

7. And after drilling a single, stopping the pump to connect the single, then starting the pump to circulate, repeating the operation, and continuing to rotate and guide the drilling.

Three-stable-inclination drilling working mode

The steady drilling mode is converted from the pilot drilling mode. The method is realized by starting and stopping the pump twice in a short time on the ground, and comprises the following specific steps of:

1. when the stable-inclination drilling is needed, two pump starting and stopping operations are carried out on the ground within a short time, the pressure sensor 7 in the tool detects the pressure change signal, the direction change is carried out on the electromagnetic directional valve through the control of the execution circuit unit, the pressure transmission hole 30 of the adjustable supporting block is communicated with a mud channel in the tool, and the supporting block extends out. At the moment, the three supporting blocks are all in an extending state, so that the three supporting blocks on the outer sleeve uniformly support the well wall, and the tool is in a centered state;

2. and then a rotary drilling tool is put down to drill, so that a stable inclination working mode is realized.

3. After each single is drilled, the pump is required to be restarted after the single is connected, and the process is repeated to realize continuous steady drilling.

Four, drill-out full-closing mode

And (3) stopping the drilling by turning off the pump, and after the pressure difference between the inside and the outside of the tool disappears, contracting all the three supporting blocks 12, lifting the drill string upwards, and lifting the drill string out of the well hole.

Claims

1. A rotary steering tool for drilling is characterized by comprising a pair of upper and lower concentrically arranged and butted hollow joints, wherein the hollow joints are provided with thread head sections and smooth pipe sections which are of an integral structure, the thread head sections of the upper and lower hollow joints are reversely arranged, namely the thread head of the upper hollow joint is arranged upwards and is used for connecting a drill string, and the thread head of the lower hollow joint is arranged downwards and is used for connecting a drill bit; the light pipe sections of the upper hollow joint and the lower hollow joint are respectively provided with a rolling bearing, the periphery of the rolling bearing is provided with an outer sleeve, and the outer sleeve is supported on the rolling bearing; three hollow windows which are uniformly arranged in the circumferential direction are formed in the outer sleeve, each hollow window is provided with a supporting block, each supporting block is provided with a hydraulic cylinder, and the hydraulic cylinders drive the supporting blocks to extend out along the hollow windows by taking the pressure difference of slurry inside and outside the tool as power and lean against the well wall; when the pressure difference between the inner and outer mud of the tool is not generated after the drill is stopped, the return spring of the hydraulic cylinder enables the supporting block to retract; a mud channel is arranged at the connecting part of the upper hollow joint and the lower hollow joint, so that mud in the tool enters the hydraulic cylinder, and the piston is driven to push the supporting block to extend out; the hydraulic cylinder of one of the supporting blocks is also provided with a reversing valve for connecting the hydraulic cylinder of the supporting block with slurry in the tool or slurry outside the tool, and the hydraulic cylinder provided with the reversing valve is called a controllable hydraulic cylinder; under the drilling working condition, if the reversing valve of the controllable hydraulic cylinder is communicated with slurry in the tool, the three supporting blocks are all in an extending state, the tool is centered, and a steady-slope drilling working mode is realized; if the reversing valve of the controllable hydraulic cylinder is communicated with slurry outside the tool, the supporting block controlled by the hydraulic cylinder is in a contraction state, the other two supporting blocks are in an extension state, the tool deflects in a borehole, and a rotary steering working mode is realized, wherein the deflection direction is the direction of a tool face; under the working condition of stopping drilling, the pressure difference of slurry inside and outside the tool is avoided, and the three supporting blocks are all in a contraction state, so that the fully-closed drill-tripping working mode is realized.

2. The rotary steerable tool of claim 1, wherein the abutting ends of the upper and lower hollow joints are in a jaw fit configuration, the light pipe section of the upper hollow joint is peripherally fitted with a coupling sleeve that is in tight fit with the light pipe of the upper hollow joint, the mating surface is provided with an axial key, the lower end of the coupling sleeve is in a jaw configuration that engages with the jaw of the light pipe section of the lower hollow joint, and the gap of the engaging portion forms a slurry passage to the hydraulic cylinder.

3. The rotary steerable tool of claim 1, wherein a radial positioning pin is provided on the outer sleeve and points radially toward the upper hollow joint light pipe section, the upper end of the coupling sleeve of the upper hollow joint light pipe section is provided with a limiting shoulder, and the shoulder surface is provided with a positioning groove adapted to the positioning pin; the upper hollow joint light pipe section is movably matched with the inner ring of the bearing.

4. The drilling rotary steerable tool of claim 3, wherein the orientation of the locating pin is coincident with the orientation of the support block actuated by the controllable hydraulic cylinder, representing the toolface orientation of the tool; the shoulder surface of the coupling sleeve of the optical pipe section of the upper hollow joint is provided with a positioning groove matched with the positioning pin, the direction of the positioning groove is adjusted to be consistent with the tool surface scribing direction in the MWD positioned at the upper part of the drill string at the ground before the tool is driven into a well, and when the positioning pin is coupled with the positioning key, the tool surface direction measured by the upper MWD is the direction of the positioning pin.

5. The drilling rotary steerable tool of claim 1, wherein the directional valve is a solenoid directional valve.

6. The drilling rotary steerable tool of claim 5, wherein the tool is further equipped with a pressure sensor for detecting downhole mud pressure as a trigger signal for the reversal of the solenoid directional valve.

7. The rotary steerable drilling tool of claim 5, wherein the tool is further provided with a circuit module comprising a mud pressure sensing and data transmission unit and a solenoid operated valve actuator circuit unit.

8. The drilling rotary steerable tool of claim 1, wherein the mud inlet of the hydraulic cylinder is provided with a plug to prevent solids in the mud from entering the chamber of the hydraulic cylinder.

9. The drilling rotary steerable tool of claim 1, wherein the rolling bearing is equipped with a back cap and a sealing packing to prevent pressure in the drill string from leaking out of the bearing.