CN210948558U - Wireless self-orienting hydraulic integrated windowing sidetrack drilling tool - Google Patents

Abstract

A wireless self-orienting hydraulic integrated window-opening sidetracking tool comprises a hollow milling cone, an angle iron of an angle guide and a setting anchoring device which are sequentially connected, wherein the setting anchoring device comprises a cylinder sleeve, an upper conical body, a lower conical body and a limiting pipe, wherein the upper conical body and the lower conical body are arranged in the cylinder sleeve; the lower end of the inner hole of the lower conical body is provided with a setting and clamping edge; a valve core and a pressure spring are arranged between the limiting pipe and the setting clamp edge in the lower conical body, and the upper end of the valve core is in clearance fit with the inner hole of the lower conical body; a flow gap is formed between the lower end of the valve core and the setting clamping edge under the action of the pressure spring; when the drilling fluid displacement reaches or exceeds a preset value, the pressure spring is compressed, and the valve core is pressed on the setting clamping edge to close the flow gap. The windowing sidetracking drilling tool not only can circulate drilling fluid so as to be oriented by a wireless logging instrument, but also can realize pressure building and setting after the orientation is finished, and is reliable in work; the orientation operation is simplified, and the orientation time is shortened.

Description

Wireless self-orienting hydraulic integrated windowing sidetrack drilling tool

Technical Field

The utility model belongs to well workover tool, in particular to wireless self-orientation hydraulic pressure integral type sidetracking instrument of windowing.

Background

The window sidetracking tool includes a whipstock and a mill cone for performing a window sidetracking in a well. The traditional window sidetracking drilling tool is provided with two sets of independent tools, namely an inclinometer and a milling cone, and the integrated window sidetracking drilling tool is a window sidetracking drilling tool which is formed by replacing a feeder arranged on the traditional inclinometer wedge with the milling cone capable of carrying out window grinding and milling operation, namely combining the inclinometer and the milling cone together.

Since most sidetrack wells require orientation, for the sidetrack wells requiring orientation, the integrated window sidetrack tool must mount a locating sub on the mill cone before going down the well, with the aid of which sub and gyroscope the orientation of the deflector ramp in the well is determined. The positioning joint comprises a joint main body used for connecting a drilling tool and a milling cone, a hollow piston body coaxially nested in the joint main body, positioning keys inserted into the piston body along the radial direction, two groups of sealing rings arranged on the hollow piston body, two fixing bolts vertically distributed on the joint main body and used for fixing the piston body, and a special sleeve used for adjusting the angle of the piston body.

During operation, the positioning joint is required to be connected to a milling cone and screwed by manpower, the angle of the piston body is adjusted by using a special sleeve to enable the positioning key to be opposite to the central line of the inclined plane of the inclined iron of the inclination guider, and then the fixing bolt is screwed to enable the piston body to be fixed in the joint main body so as to fix the positioning key; in addition, before the slope guide goes into the well, a hydraulic tong is used for stressing and screwing the slope guide and the positioning joint at the well mouth, so that the relative position of the positioning key and the slope of the slope guide is changed, correction is needed, the operation cost is increased, and the operation efficiency is reduced.

For solving above-mentioned problem, utility model patent that publication number is CN206845130U discloses a sidetracking instrument of windowing from directional integral type, including coaxial coupling's hollow milling awl, leading sloping ware wedge and seat anchor that seals in proper order, its special character is: a positioning key is fixedly arranged on the milling cone along the radial direction, protrudes out of the inner wall of the milling cone and is aligned with the central line of the inclined plane of the inclined iron of the slope guider; the positioning key is matched with a key groove on a gyroscope used for determining the inclined plane direction of the inclined iron of the slope guider. Therefore, after the windowing sidetracking drilling tool is put into place, the gyroscope under the logging truck can be directly used for orientation, a positioning joint is not needed, the operation is reliable, the material cost and the operation cost are reduced, and the operation efficiency is also improved. However, since the gyroscope is used for wired logging, a special logging truck is required to be used for pulling up and down, the logging preparation and operation time is long, and much inconvenience is brought to sidetracking construction.

With the progress of the technology, wireless logging, i.e. logging while drilling, is becoming more and more perfect, wired logging systems are gradually replaced by wireless logging systems such as MWD and LWD, and wireless logging systems need to circulate drilling fluid to transmit logging parameters to the ground, so the precondition for orientation by wireless logging systems is that the drilling fluid must be circulated.

At present, two hydraulic fixed window-opening sidetracking tools are commonly used at home and abroad: one kind adopts and sets up the ball structure of sealing, this kind of windowing sidetracking tool can't circulate drilling fluid, as the above-mentioned self-orienting integral type windowing sidetracking tool, because this tool begins to set once circulating drilling fluid, can't adopt the wireless logging system to orient; the other type is a windowing sidetracking tool for throwing a setting ball behind, which can circulate drilling fluid but can realize setting only by throwing the setting ball, for example, an integrated windowing sidetracking tool disclosed in the publication No. CN102364029B, if a wireless logging instrument is placed in a drilling tool, the setting ball cannot be put in place, and the setting cannot be realized. Due to the structural problems of the existing hydraulic fixed windowing sidetracking tools, the application of the wireless logging instrument in the orientation of the hydraulic windowing sidetracking tools is limited.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a drilling fluid not only can circulate so that adopt wireless logging instrument directional is provided, can realize suppressing pressure in addition after accomplishing the orientation and sit to seal, the wireless self-orienting hydraulic pressure integral type sidetracking instrument of reliable operation of windowing.

The technical scheme of the utility model as follows:

a wireless self-orienting hydraulic integrated window-opening sidetracking tool comprises a hollow milling cone, an angle iron of an angle guide and a setting anchoring device which are sequentially connected, wherein the setting anchoring device comprises a cylinder sleeve, an upper conical body, a lower conical body and a limiting pipe, wherein the upper conical body and the lower conical body are arranged in the cylinder sleeve, and the limiting pipe is connected with the upper conical body and the lower conical body; the lower end of the inner hole of the lower conical body is provided with a setting clamping edge;

it is characterized in that: a valve core and a pressure spring sleeved on the valve core are arranged between the limiting pipe and the setting clamping edge in the lower conical body, and the upper end of the valve core is in clearance fit with the inner hole of the lower conical body; a circulation gap is formed between the lower end of the valve core and the setting clamp edge under the action of the pressure spring and is used for enabling the drilling fluid to flow out of the setting anchoring device to realize the circulation of the drilling fluid; when the discharge volume of the drilling fluid reaches or exceeds a preset value, the pressure spring is compressed, and the valve core is pressed on the setting clamp edge to close the flow gap, so that the pressure-built setting is realized.

Preferably, the valve core is in a stepped shaft shape, the shaft diameter of the upper end of the valve core is larger than that of the lower end of the valve core, the upper end of the valve core is in sliding clearance fit with the inner hole of the lower conical body, and the lower end of the valve core is in a semi-spherical shape or a conical shape matched with the setting clamp edge, so that the valve core is arranged along the axis of the lower conical body.

Preferably, two or more fan-shaped openings are uniformly distributed on the outer edge of the upper end of the valve core along the circumference, and are used for realizing the circulation of the drilling fluid.

Preferably, the milling cone is provided with a positioning key along the radial direction, and the positioning key protrudes out of the inner wall of the milling cone and is aligned with the central line of the inclined plane of the inclined iron of the slope guider; the positioning key is matched with a key groove on the wireless logging instrument for determining the inclined plane direction of the wedge guider, so that the positioning of the wireless logging instrument is facilitated.

Preferably, the lower part of the milling cone is pressed on the upper part of the inclined plane of the inclined iron of the slope guider, a positioning bolt is arranged between the upper end of the inclined iron of the slope guider and the milling cone along the radial direction, an auxiliary water hole is arranged on the milling cone along the radial direction corresponding to the positioning bolt, a blind hole communicated with the auxiliary water hole is formed in the positioning bolt, the auxiliary water hole is blocked by the positioning bolt when the inclined iron of the slope guider is not separated from the milling cone, when the inclined iron of the slope guider is separated from the milling cone, namely the positioning bolt is sheared, an inner hole of the milling cone is communicated with the outside through the auxiliary water hole and the blind hole of the positioning bolt, so that a pump is prevented from being blocked due to the blocking of a nozzle hole of the milling cone by stratum or cement, and sufficient drilling pressure.

Preferably, the wedge of the slope guiding device is clamped in an arc-shaped dovetail groove arranged on the outer edge of the lower part of the milling cone through a positioning block, an arc-shaped clamping edge matched with the arc-shaped dovetail groove is arranged on the positioning block, and the positioning block is clamped in the arc-shaped dovetail groove through the arc-shaped clamping edge; the positioning block and the positioning key are respectively positioned on two sides of the axis of the milling cone.

Preferably, a nozzle hole at the lower end of the milling cone and a liquid guide pipe for connecting the inner cavity of the setting anchoring device are arranged in the wedge of the slope guiding device, and the lower end of the liquid guide pipe is connected with a jet pipe in the setting anchoring device.

Preferably, slips which can extend out of the outer wall of the cylinder sleeve are uniformly distributed on the upper conical body and the lower conical body in the sitting anchor device respectively, two ends of the limiting pipe are connected with the upper conical body and the lower conical body respectively through threads, and strip-shaped holes are uniformly distributed on the limiting pipe; the upper end and the lower end of the jet pipe are respectively inserted with the liquid guide pipe and the upper conical body.

Preferably, an annular groove is formed in the lower portion of the milling cone along the circumferential direction, one side of the annular groove, which corresponds to the wedge of the slope guiding device, is provided with a section of the arc-shaped dovetail groove with a wide inner part and a narrow outer part, and the rest of the annular groove is provided with a trapezoid groove with a wide inner part and a wide outer part.

The utility model has the advantages that:

1. because the valve core and the pressure spring are arranged between the limiting pipe and the setting clamp edge in the lower conical body, the upper end of the valve core is in clearance fit with the inner hole of the lower conical body and is propped against the lower end surface of the limiting pipe under the action of the pressure spring; a circulation gap is formed between the lower end of the valve core and the setting clamp edge under the action of the pressure spring, so that the drilling fluid can flow out of the setting anchoring device to realize the circulation of the drilling fluid, and a wireless logging instrument can be adopted for orientation; when the discharge capacity of the drilling fluid reaches or exceeds a preset value, the valve core is pressed on the setting clamp edge to close the flow gap, so that the setting anchoring device realizes pressure-holding setting, and the requirements of circulating drilling fluid and setting pressure-holding when a wireless logging instrument is used for orientation can be met; greatly simplifying the orientation operation, shortening the orientation time and saving considerable cost of the orientation operation.

2. The window-opening sidetracking tool and the wireless logging instrument can be simultaneously lowered into a well during operation, and the drilling fluid can be directly circulated to start orientation and setting when reaching a preset position in the well, so that the operation of lifting the gyroscope by using a logging truck is omitted, and the phenomenon that the tool cannot be set due to the fact that impurities attached to the inner wall of a drilling tool fall off and are accumulated to form blockage caused by lifting the gyroscope is avoided; the directional operation time and the well construction period are greatly shortened, and the setting success rate is improved.

3. Because the lower end of the valve core forms a circulation gap with the setting clamp edge under the action of the pressure spring, the drilling fluid inside and outside the windowing sidetracking tool is communicated, and the mistaken setting caused by pressure excitation or suction in the process of taking up the windowing sidetracking tool can be avoided.

4. Because the pressure spring is sleeved on the valve core, after the windowing sidetracking tool is subjected to pressure holding and setting, the valve core is reset under the action of the pressure spring to recover the circulation gap after the setting pressure is released on the ground, so that the drilling fluid can be recovered to a circulation state, and the windowing sidetracking tool can be used for the windowing sidetracking of open hole wells and wells seriously damaged by sleeves.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a sectional view a-a of fig. 1.

Fig. 3 is an enlarged view of a portion of the setting anchor of fig. 1.

Fig. 4 is a sectional view B-B of fig. 3.

In the figure: the device comprises a shoe guiding pipe 1, a setting sleeve 2, a setting clamp edge 201, a circulation gap 3, a valve core 4, a notch 401, a pressure spring 5, a longitudinal slip 6, a shear screw 7, a lower conical body 8, a sealing ring 9, a limiting pipe 10, a strip-shaped hole 101, a cylinder sleeve 11, an upper conical body 12, a radial slip 13, a shear screw 14, a jet pipe 15, an inclined iron 16 of an inclined guider, a liquid guide pipe 17, a milling cone head 18, a positioning block 19, a positioning screw 20, a positioning bolt 21, a milling cone 22 and a positioning key 23.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1-4, the utility model relates to a wireless self-orienting hydraulic pressure deflector, which comprises a hollow milling cone 22, a deflector wedge 16 and a setting anchoring device which are connected in sequence, wherein a positioning key 23 is inserted and welded on the upper part of the milling cone 22 along the radial direction, and the positioning key 23 protrudes out of the inner wall of the milling cone and is aligned with the inclined plane central line of the deflector wedge 16; the locating key 23 matches with a keyway on the wireless logging tool guide used to determine the orientation of the slope of the whipstock 16. The hole of milling awl 22 is for the shoulder hole that from top to bottom descends in proper order, and the connection screw that is used for connecting the drilling tool is milled 22 hole upper ends of the awl, and a section aperture that the hole of milling awl 22 corresponds navigation key 23 department is greater than wireless logging instrument guide diameter 2 millimeters, navigation key 23 protrusion mills 3 millimeters on the awl 22 inner wall.

The outer edge of the lower portion of the milling cone 22 is pressed on the upper portion of the inclined plane of the wedge guider 16, an annular groove is processed on the lower portion of the milling cone 22 along the circumferential direction, one side of the annular groove, corresponding to the wedge guider 16, is an arc-shaped dovetail groove with a wide inner part and a narrow outer part, the rest of the annular groove is a trapezoid groove with a wide inner part and a narrow outer part, a positioning block 19 is fixedly arranged on the inclined plane of the wedge guider 16, the side, corresponding to the wedge guider 16, of the positioning block 19 is cylindrical and is inserted and welded on the wedge guider 16, an arc-shaped clamping edge matched with the arc-shaped dovetail groove is arranged on the positioning block 19, the positioning block 19 is clamped into the arc-shaped dovetail groove through the arc-shaped clamping edge, and a positioning screw 20 is.

And a positioning bolt 21 is arranged between the upper end of the slope iron 16 of the slope guider and the milling cone 22 along the radial direction. An auxiliary water hole is formed in the position, corresponding to the positioning bolt 21, of the milling cone 22 in the radial direction, a blind hole communicated with the auxiliary water hole is formed in the positioning bolt 21, the positioning bolt 21 blocks the auxiliary water hole when the wedge 16 of the wedge guider is not separated from the milling cone 22, and after the positioning bolt 21 is cut off when the wedge 16 of the wedge guider is separated from the milling cone 22, an inner hole of the milling cone is communicated with the outside of the milling cone 22 through the auxiliary water hole and the blind hole, so that a pump is prevented from being blocked due to the fact that a nozzle hole of the milling cone is blocked by stratum or cement, and sufficient drilling pressure can be guaranteed during windowing.

A liquid guide pipe 17 for communicating the inner hole of the milling cone 22 with the inner cavity of the setting anchoring device is arranged in the wedge 16 of the slope guide, a milling cone head 18 is fixedly connected to the lower end of the milling cone 22, a nozzle hole communicated with the inner hole of the milling cone 22 is arranged on the milling cone head 18, and the upper end of the liquid guide pipe 17 is led out from the upper part of the inclined plane of the wedge of the slope guide and is inserted and welded into the nozzle hole.

The setting anchoring device comprises a cylinder sleeve 11 fixedly connected to the outer edge of the lower end of the inclined iron 16 of the slope guiding device and a jet pipe 15 inserted and fixed in a central hole of the lower end of the inclined iron 16 of the slope guiding device, and the upper end of the jet pipe 15 is mutually inserted and connected with the lower end of the liquid guide pipe 17. A hollow upper conical body 12 and a hollow lower conical body 8 are arranged in the cylinder sleeve 11, the lower end of the jet pipe 15 is inserted into a central hole of the upper conical body 12 in a clearance fit manner, and sealing rings 9 are respectively arranged between the jet pipe 15 and the upper conical body 12 and between the upper conical body and the cylinder sleeve 11 and between the lower conical body and the cylinder sleeve 11. Radial slips 13 are uniformly distributed on the outer wall of an upper conical body 12 through the circumference of shear screws 14, longitudinal slips 6 are uniformly distributed on the outer wall of a lower conical body 8 through the circumference of shear screws 7, the radial slips 13 and the longitudinal slips 6 can extend out of a rectangular opening formed in the outer wall of a cylinder sleeve 11 under the pushing of the upper conical body 12 and the lower conical body 8, a limiting pipe 10 is arranged in a central hole of the lower conical body 8, the upper end of the limiting pipe 10 is connected with an inner hole of the upper conical body 12 through coarse-tooth threads, the limiting pipe 10 is connected with the lower conical body 8 through fine-tooth-shaped threads, the tooth tips of the zigzag threads on the limiting pipe 10 face downwards, and strip-shaped holes 101 which are longitudinally arranged are uniformly distributed on the pipe wall of the. The lower end of the cylinder sleeve 11 is connected with a shoe guide pipe 1 through threads.

The two ends of the lower conical body are straight pipe sections, the seat sleeve 2 is inserted into and welded in the lower port of the lower conical body, the upper port of the seat sleeve 2 forms a seat clamp edge 201 at the lower end of the inner hole of the lower conical body, and the seat clamp edge is conical. A valve core 4 and a pressure spring 5 sleeved on the valve core 4 are arranged between the limiting pipe and the setting clamp edge in the lower conical body, the upper end of the valve core 4 is in clearance fit with the inner hole of the lower conical body and is propped against the lower end surface of the limiting pipe under the action of the pressure spring 5; the lower end of the valve core 4 forms a circulation gap 3 with the setting clamp edge 201 under the action of the pressure spring 5, and the circulation gap is used for enabling drilling fluid to flow out of the setting anchoring device to achieve circulation of the drilling fluid, so that the drilling fluid can be circulated to carry out data transmission when the wireless logging instrument is used for orientation. When the discharge volume of the drilling fluid reaches or exceeds a preset value, the pressure spring 5 is pushed by the drilling fluid to compress the valve core 4, and the lower end of the valve core 4 is pressed on the setting clamp edge to close the flow gap 3, so that the pressure-built setting is realized.

The valve core 4 is in a stepped shaft shape, the shaft diameter of the upper end of the valve core is larger than that of the lower portion of the valve core, the upper end of the valve core is in sliding clearance fit with the inner hole of the lower conical body, and the lower end of the valve core is in a semi-spherical shape or a conical shape matched with the setting clamp edge, so that the valve core 4 is arranged along the axis of the lower conical body. Two or more fan-shaped openings 401 are uniformly distributed on the outer edge of the upper end of the valve core 4 along the circumference, and three openings are taken as an example in the embodiment for realizing the circulation of the drilling fluid.

During operation, the specific operation steps are as follows:

1. the upper end of the milling cone is connected with the drilling tool, the wireless logging instrument is placed in the drilling tool and reaches the inner cavity of the milling cone under the action of self gravity, and when the wireless logging instrument guide continues to descend through the positioning key 23, the wireless logging instrument guide is limited by the size of the inner cavity of the milling cone and the positioning key 23 and under the action of self gravity, the pen point of the wireless logging instrument guide is forced to guide the key groove to be clamped on the positioning key 23.

2. After the windowing sidetracking drilling tool is lowered to a preset position in the well by a drilling tool, the drilling tool is connected with an upper drill rod or a top drive, and then the drilling fluid can be pumped to circulate, wherein the discharge capacity of the drilling fluid is slightly larger than the lower limit of the discharge capacity required by the work of the wireless logging instrument. Drilling fluid enters the inner hole of the milling cone, the liquid guide pipe 17, the jet pipe 15 and the inner hole of the upper conical body 12 through the inner hole of the drilling tool and the wireless logging instrument in sequence, the limiting pipe 10 reaches the valve core 4, the valve core 4 is pushed by the drilling fluid and then can compress the pressure spring 5 to move downwards, but the flowing gap 3 cannot be sealed, the drilling fluid is ejected out of the seat sleeve pipe 2 through the fan-shaped notch 401 at the upper end of the valve core 4 and the flowing gap 3 at the lower end of the valve core 4 and enters the shoe guide pipe 1, and then returns to the ground through an annular space formed by the window opening side drilling tool, the drilling tool and the casing pipe in the well, the azimuth angle of the inclined iron 16 inclined plane of the inclined guide is adjusted to the designed azimuth angle by rotating the drilling tool according.

3. Then the discharge capacity of the drilling fluid is increased, the pressure difference generated when the drilling fluid passes through the valve core is increased, the pressure on the valve core formed by the pressure difference forces the pressure spring 5 to compress until the valve core presses on the setting clamp edge 4 and seals the flow gap 3, at the moment, the valve core presses on the setting clamp edge under the pressure action of the drilling fluid to be suppressed, the drilling tool is filled with the high-pressure drilling fluid, the high-pressure drilling fluid entering between the upper conical body 12 and the lower conical body 8 through the strip-shaped hole 101 pushes the upper conical body 12 and drives the limiting pipe 10 to generate a sliding buckle phenomenon with the lower conical body 8, finally, the upper conical body 12 shears the shearing screw 14, the lower conical body 8 shears the shearing screw 7 and forces the radial slips 13 and the longitudinal slips 6 to be clamped on a well wall, and when the pumping pressure reaches a preset value, the pump is stopped and stabilized for 30 seconds. And then the drilling tool is positively rotated, the drilling tool drives the milling cone to rotate to cut off the positioning bolt 21 and the positioning screw 20, so that the auxiliary water hole of the milling cone is opened, the positioning block 19 is screwed out from the arc-shaped dovetail groove, the drilling tool is continuously rotated, the liquid guide pipe 17 is screwed off at the outlet of the nozzle hole to enable the nozzle hole to naturally form a milling cone nozzle, at the moment, the inclined iron 16 of the slope guider and the milling cone 22 are completely separated, the pump can be started again to circulate drilling fluid, and the drilling tool is rotated and drill pressure is applied to perform window-. In the windowing process, once the nozzle hole of the milling cone is blocked by stratum or cement, a part of high-pressure drilling fluid is released through the auxiliary water hole of the milling cone, so that the pump blocking caused by pressure blocking is avoided.

While the embodiments of the invention have been described above, it is not intended to be limited to the details shown, or described, but rather to cover all modifications, which would come within the scope of the appended claims, and all changes which come within the meaning and range of equivalency of the art are therefore intended to be embraced therein.

Claims (9)

1. A wireless self-orienting hydraulic integrated window-opening sidetracking tool comprises a hollow milling cone, an angle iron of an angle guide and a setting anchoring device which are sequentially connected, wherein the setting anchoring device comprises a cylinder sleeve, an upper conical body, a lower conical body and a limiting pipe, wherein the upper conical body and the lower conical body are arranged in the cylinder sleeve, and the limiting pipe is connected with the upper conical body and the lower conical body; the lower end of the inner hole of the lower conical body is provided with a setting and clamping edge; the method is characterized in that:

a valve core and a pressure spring sleeved on the valve core are arranged between the limiting pipe and the setting clamping edge in the lower conical body, and the upper end of the valve core is in clearance fit with the inner hole of the lower conical body; a circulation gap is formed between the lower end of the valve core and the setting clamp edge under the action of the pressure spring and is used for enabling the drilling fluid to flow out of the setting anchoring device to realize the circulation of the drilling fluid; when the discharge volume of the drilling fluid reaches or exceeds a preset value, the pressure spring is compressed, and the valve core is pressed on the setting clamp edge to close the flow gap, so that the pressure-built setting is realized.

2. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 1, wherein: the valve core is in a stepped shaft shape, the shaft diameter of the upper end of the valve core is larger than that of the lower portion of the valve core, the upper end of the valve core is in sliding clearance fit with the inner hole of the lower conical body, and the lower end of the valve core is in a semi-spherical shape or a conical shape matched with the setting clamp edge, so that the valve core is arranged along the axis of the lower conical body.

3. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 2, wherein: two or more fan-shaped openings are uniformly distributed on the outer edge of the upper end of the valve core along the circumference and are used for realizing the circulation of the drilling fluid.

4. The wireless self-orienting hydraulic integrated window sidetracking tool according to any one of claims 1-3, wherein: a positioning key is arranged on the milling cone along the radial direction, protrudes out of the inner wall of the milling cone and is aligned with the central line of the inclined plane of the inclined iron of the slope guider; the positioning key is matched with a key groove on the wireless logging instrument for determining the inclined plane direction of the wedge guider, so that the positioning of the wireless logging instrument is facilitated.

5. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 4, wherein: the lower portion of the milling cone is pressed on the upper portion of an inclined plane of the wedge guider, a positioning bolt is arranged between the upper end of the wedge guider and the milling cone along the radial direction, an auxiliary water hole is arranged on the milling cone along the radial direction corresponding to the positioning bolt, a blind hole communicated with the auxiliary water hole is formed in the positioning bolt, the auxiliary water hole is blocked by the positioning bolt when the wedge of the wedge guider and the milling cone are not separated, the inner hole of the milling cone is communicated with the outside through the auxiliary water hole and the blind hole of the positioning bolt when the wedge of the wedge guider and the milling cone are separated, namely the positioning bolt is cut off, so that a pump is prevented from being blocked due to the fact that a nozzle hole of the milling cone is blocked by strata or cement, and sufficient drilling.

6. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 5, wherein: the wedge of the slope guiding device is clamped in an arc-shaped dovetail groove arranged on the outer edge of the lower part of the milling cone through a positioning block, an arc-shaped clamping edge matched with the arc-shaped dovetail groove is arranged on the positioning block, and the positioning block is clamped in the arc-shaped dovetail groove through the arc-shaped clamping edge; the positioning block and the positioning key are respectively positioned on two sides of the axis of the milling cone.

7. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 1 or 6, wherein: a nozzle hole at the lower end of the milling cone and a liquid guide pipe for connecting the inner cavity of the setting anchoring device are arranged in the wedge of the slope guiding device, and the lower end of the liquid guide pipe is connected with a jet pipe in the setting anchoring device.

8. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 7, wherein: slips which can extend out of the outer wall of a cylinder sleeve are respectively and uniformly connected to an upper conical body and a lower conical body in the setting anchoring device, two ends of a limiting pipe are respectively in threaded connection with the upper conical body and the lower conical body, and strip-shaped holes are uniformly distributed in the limiting pipe; the upper end and the lower end of the jet pipe are respectively inserted with the liquid guide pipe and the upper conical body.

9. The wireless self-orienting hydraulic integrated window sidetracking tool of claim 6, wherein: an annular groove is formed in the lower portion of the milling cone along the circumferential direction, one side of the annular groove, corresponding to the wedge of the slope guider, is provided with a section of arc-shaped dovetail groove with a wide inner part and a narrow outer part, and the rest of the annular groove is a trapezoid groove with a narrow inner part and a wide outer part.

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