CN111794691A - Double-layer continuous pipe tool joint structure and assembling method thereof - Google Patents

Double-layer continuous pipe tool joint structure and assembling method thereof Download PDF

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Publication number
CN111794691A
CN111794691A CN202010629470.XA CN202010629470A CN111794691A CN 111794691 A CN111794691 A CN 111794691A CN 202010629470 A CN202010629470 A CN 202010629470A CN 111794691 A CN111794691 A CN 111794691A
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CN
China
Prior art keywords
pipe connector
outer pipe
inner pipe
bushing
connector
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CN202010629470.XA
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Chinese (zh)
Inventor
潘田佳
袁娇
颜子敏
高杭
李志刚
俞海明
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Sichuan Honghua Petroleum Equipment Co Ltd
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Sichuan Honghua Petroleum Equipment Co Ltd
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Application filed by Sichuan Honghua Petroleum Equipment Co Ltd filed Critical Sichuan Honghua Petroleum Equipment Co Ltd
Priority to CN202010629470.XA priority Critical patent/CN111794691A/en
Publication of CN111794691A publication Critical patent/CN111794691A/en
Pending legal-status Critical Current

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    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B17/00Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
    • E21B17/02Couplings; joints
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B17/00Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
    • E21B17/20Flexible or articulated drilling pipes, e.g. flexible or articulated rods, pipes or cables
    • E21B17/203Flexible or articulated drilling pipes, e.g. flexible or articulated rods, pipes or cables with plural fluid passages

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  • Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Geology (AREA)
  • Mining & Mineral Resources (AREA)
  • Mechanical Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Environmental & Geological Engineering (AREA)
  • Fluid Mechanics (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • Geochemistry & Mineralogy (AREA)
  • Quick-Acting Or Multi-Walled Pipe Joints (AREA)

Abstract

The invention discloses a double-layer continuous pipe tool joint structure and an assembling method thereof, belonging to the technical field of drilling devices; the structure comprises an outer pipe connecting device and an inner pipe connecting device, wherein the inner pipe connecting device is connected with an inner pipe, the outer pipe connecting device is connected with an outer pipe, a first flow passage is arranged in the inner pipe connecting device and is communicated with the inner pipe to form a first liquid channel, the inner pipe is sleeved in the outer pipe, a gap is formed between the outer side wall of the inner pipe and the inner side wall of the outer pipe to form a pipe interlayer, a second flow passage is arranged in the inner pipe connecting device at the outer side of the first flow passage, and the second flow passage is communicated with the pipe clamp layer to form a second liquid channel; the invention solves the problem that the traditional continuous pipe usually adopts a single-layer structure, effectively realizes the effect that the structure has double channels by means of the design of the inner pipe and the outer pipe, and effectively realizes the input and the discharge of liquid by means of the double channels and independently designed channels.

Description

Double-layer continuous pipe tool joint structure and assembling method thereof
Technical Field
The invention relates to a tool joint structure of a double-layer continuous pipe, and belongs to the technical field of drilling devices.
Background
Coiled tubing has been widely used in the fields of well workover, acidizing, fracturing, perforating, well logging, well completion, drilling, plug removal, etc. in oil and gas fields, downhole tools are connected with coiled tubing through coiled tubing connectors. Single layer coiled tubing has been used in the field, while double layer coiled tubing is still under investigation.
The connector for double-layer continuous pipe operation is used for connecting a double-layer continuous pipe and a downhole tool during double-layer continuous pipe downhole operation, the tool joint can be simultaneously connected with an inner pipe, an outer pipe and the downhole tool of the double-layer continuous pipe, the connector can be used in occasions of double-layer continuous pipe drilling, well logging, blockage removal and the like, particularly in the application of a sea surface drilling device, the cost of the device and the construction difficulty of the device can be increased to a great extent by adding a device for recovering/discharging liquid independently, the environment is not a conventional environment, and the requirement is relatively higher.
The double-layer continuous oil pipe device and the matched tool thereof have the characteristics of negative pressure, an independent loop circulation channel, no interference with well fluid in a well shaft of a well, and the like, and are particularly suitable for well conditions such as a horizontal well, a low-pressure oil reservoir, a loose sand reservoir, heavy oil and extra-heavy oil, serious leakage, long-section open hole or screen pipe completion and the like; negative pressure sand washing of the horizontal well is carried out, so that the sand washing operation is effective and thorough; the single circulation loop of the double-layer coiled tubing can be used for smoothly discharging the accumulated liquid in the shaft and recovering the yield.
Disclosure of Invention
The invention aims to: aiming at the existing problems, the tool joint structure of the double-layer continuous pipe and the assembling method thereof are provided, the tool joint can be used for simultaneously connecting an inner pipe, an outer pipe and an underground tool of the double-layer continuous pipe, can be used in occasions of drilling, logging, blockage removal and the like of the double-layer continuous pipe, and has the advantages of simple structure, easiness in installation, simplicity in operation, good process feasibility and the like.
The technical scheme adopted by the invention is as follows:
the utility model provides a double-deck coiled tubing tool joint structure, includes outer tube connecting device and inner tube connecting device, inner tube connecting device is connected with the inner tube, outer tube connecting device is connected with the outer tube, be provided with first runner in the inner tube connecting device, first runner forms first liquid channel with the inner tube intercommunication, the inner tube cover is located in the outer tube, the lateral wall of inner tube with the outer tube inside wall between have the clearance in order to form the pipe intermediate layer, the inner tube connecting device at first runner outside place is provided with the second runner, the second runner forms second liquid channel with pipe clamp layer intercommunication.
Further, the outer pipe connecting device comprises an outer pipe connector and an outer pipe assembling structure for assembling an outer pipe, the inner pipe connecting device is an inner pipe connector, and the outer pipe connector is assembled and connected with the inner pipe connector.
Further, the outer pipe assembling structure comprises a slip which is arranged inside the outer pipe connector and used for assembling the outer pipe, and a lining is further arranged between the slip and the inner pipe connector.
Further, the inner side of one end part of the outer pipe connector is conical for assembling slips, the slips clamp the outer pipe through the matching of the conical shape and the slips, and the other end part of the outer pipe connector is assembled and connected with the inner pipe connector.
Furthermore, a backing ring is further arranged between the slip and the bushing, the backing ring is an annular spring pad and comprises 1 outer ring and 2 inner rings, and the contact surface of the outer ring and the inner ring is a conical surface.
Further, the bushing includes a first bushing and a second bushing, the second bushing is disposed between the first bushing and the grommet, the first bushing is disposed between the second bushing and the inner tube connector end, the first bushing is semi-cylindrical, and 2 first bushings are used in pairs.
Furthermore, the outer pipe connector and the inner pipe connector are assembled through threaded connection, and the outer pipe connector and the inner pipe connector are fixedly assembled through a set screw after being assembled and connected.
Further, the other end of the inner pipe connector is provided with threads for connecting a downhole tool.
Furthermore, the external structure of the slip is conical, the large end of the cone is provided with a section of cylinder, and the inside of the slip is provided with axial slip teeth and annular slip teeth.
Furthermore, the first flow channel is a through hole penetrating through the middle part of the inner pipe connector, the second flow channel is a plurality of strip-shaped flow channels uniformly distributed on the outer side of the first flow channel, and the second flow channel penetrates through the inner pipe connector.
A double-layer continuous pipe tool joint structure assembling method comprises the following steps:
a. assembling an outer pipe connecting device, namely selecting an outer pipe, and sequentially sleeving an outer pipe connector, a slip, a backing ring and a second lining with a sealing device from the lower end of the outer pipe;
b. assembling the inner pipe and the inner pipe connector, aligning the upper shoulder surface of the inner pipe connector with the lower end surface of the inner pipe, and keeping the position of the inner pipe connector fixed; then pressing the inner pipe into the annular groove of the inner pipe connector by using a tool to complete the connection of the inner pipe connector and the inner pipe;
c. installing a first bush, installing the first bush of each semicircular ring outside the assembled inner pipe, and moving a second bush downwards to enable the lower end face of the second bush to be in contact with the upper end face of the first bush and the lower end face of the first bush to be in contact with the upper shoulder face of the inner pipe connector;
then the backing ring and the slip are sequentially moved downwards, so that the lower end face of the backing ring is contacted with the upper end face of the second lining, and the lower end face of the slip is contacted with the upper end face of the backing ring;
then the outer pipe connector is moved downwards, so that the lower end face of the outer pipe connector is below the lower end face of the first bushing, and the bushing is initially installed;
d. installing the outer pipe connector, continuously moving the outer pipe connector downwards, and connecting the outer pipe connector with the thread of the inner pipe connector through the thread on the outer pipe connector until the thread tightening torque reaches the design requirement;
e. and after the threaded connection of the outer pipe connector and the inner pipe connector is completed, the anti-return set screws are installed at the positions of the holes axially and uniformly distributed at the lower end of the outer pipe connector, so that the threads are prevented from being reversely buckled.
In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:
1. the double-layer continuous pipe tool joint structure solves the problem that the traditional continuous pipe usually adopts a single-layer structure, the structure has a double-channel effect by means of the design of an inner pipe and an outer pipe, meanwhile, the input and the discharge of liquid are effectively realized by means of the double-channel and independently designed channels, the assembly is convenient from the design of the structure, the double-layer continuous pipe tool joint structure further has the adaptability of the continuous pipe, and the difficulty of field construction and the production cost of the device are reduced;
2. according to the double-layer continuous pipe tool joint structure, the outer pipe is effectively assembled through the design of the outer pipe connecting device, the clamping effect of the clamping piece on the outer pipe is effectively guaranteed in the axial direction, and the problems that the outer pipe is loosened and falls off or the sealing effect is poor in the using process are solved;
3. the double-layer continuous pipe tool joint structure effectively realizes modularization of each connecting part on the structural design, can effectively reduce the assembly difficulty of the continuous pipe tool structure, is convenient for processing the whole structure, and effectively breaks through the difficult problem of double-layer continuous pipe tools.
Drawings
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic structural view of an outer tube connector of the present invention;
FIG. 3 is a schematic diagram of the construction of the inner tube connector of the present invention;
FIG. 4 is a schematic cross-sectional view of an inner tube connector of the present invention;
FIG. 5 is a schematic diagram of the construction of the slips of the present invention;
FIG. 6 is a schematic cross-sectional view of a slip of the present invention;
FIG. 7 is a schematic view of the grommet according to the present invention;
fig. 8 is an enlarged assembly view of the sealing ring of the present invention.
The labels in the figure are: 1-outer pipe, 2-inner pipe, 3-outer pipe connector, 4-inner pipe connector, 5-first flow channel, 6-second flow channel, 7-slips, 71-axial slips, 72-circumferential slips, 8-backing ring, 81-outer ring, 82-inner ring, 9-first lining, 10-second lining, 11-set screw, 12-sealing ring and 13-retaining ring.
Detailed Description
All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.
Any feature disclosed in this specification may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.
Example 1
The utility model provides a double-deck coiled tubing tool joint structure, as shown in fig. 1 to 8, includes outer tube connecting device and inner tube connecting device, inner tube connecting device is connected with inner tube 2, outer tube connecting device is connected with outer tube 1, be provided with first runner 5 in the inner tube connecting device, first runner 5 forms first liquid channel with the inner tube intercommunication, the inner tube cover is located in the outer tube, the lateral wall of inner tube with the outer tube inside wall between have the clearance in order to form the pipe intermediate layer, the inner tube connecting device at first runner outside place is provided with second runner 6, the second runner forms second liquid channel with pipe clamp layer intercommunication.
In this embodiment, in the design of its structure, can realize the assembly of outer tube 1 through the design of outer tube connecting device, the assembly of inner tube 3 is realized to inner tube connecting device, in the assembling process, the external diameter that adopts inner tube 3 is less than the internal diameter of outer tube 1, and in this way realize that there is certain clearance between outer tube 1 and the inner tube 3, thereby form the pipe intermediate layer, and in specific structural design, utilize inner tube 3 and pipe intermediate layer and set up first runner 5 and the second runner 6 on inner tube connecting device respectively to communicate in order to realize two independent liquid passages, and in this middle of, first liquid passage is the inlet channel of liquid, and the second liquid passage is the flowing back passageway, the design of double-deck continuous tube has effectively been realized with the help of the design of this structure, the assembly problem of double-deck continuous tube has been solved.
As a more specific design, the outer pipe connecting device and the inner pipe connecting device are further designed, the outer pipe connecting device comprises an outer pipe connector 3 and an outer pipe assembling structure for assembling an outer pipe, the inner pipe connecting device is an inner pipe connector 4, and the outer pipe connector 3 is assembled and connected with the inner pipe connector 4. In the integral structure design, all parts are required to be integrated, and in the design, the integral structure assembly is realized by the assembly of the outer pipe connector 3 and the inner pipe connector 4.
As a more optimized design, the outer pipe assembling structure comprises a slip 7 which is arranged inside the outer pipe connector 3 and is used for assembling the outer pipe 1, and a lining sleeve and a backing ring are further arranged between the slip 7 and the inner pipe connector 4. Axial force can be effectively transmitted by means of the design of the bushing, and axial impact force can be relieved by means of the design of the backing ring.
In a more specific design, the inner side of one end part of the outer pipe connector 3 is conical for assembling slips 7, the slips clamp the outer pipe through the matching of the conical shape and the slips 7, and the other end part of the outer pipe connector 3 is assembled and connected with the inner pipe connector 4. By means of the conical structure, the slips 7 are also conical, and when the outer pipe connector 3 is assembled, the conical structure can generate uniform force on the slips 7 when the outer pipe connector is axially moved, so that the slips can be inwards contracted to realize a clamping function. More specifically, the taper length of the interior of the outer pipe connector 3 is greater than the taper length of the slips 7 to provide assembly allowance for assembly.
In order to better realize the axial buffering effect, in a more specific design, a backing ring 8 is further arranged between the slip and the bushing, the backing ring 8 is an annular spring pad, the backing ring comprises 1 outer ring 81 and 2 inner rings 82, and the contact surface between the outer ring 81 and the inner rings 82 is a conical surface. Taking the figure as an illustration, 2 inner rings 82 are assembled in opposition to form an "I" like structure with an annular tapered groove into which the outer ring 81 fits and effects the assembly of the tapered surfaces. More specifically, the backing ring 8 serves to transmit the working axial loads and compensate for axial deformations and to withstand the impact loads that may occur during operation.
A further design is made for the bushing comprising a first bushing 9 and a second bushing 10, said second bushing 10 being arranged between the first bushing 9 and the grommet, said first bushing 9 being arranged between the second bushing 10 and the inner tube connector end, said first bushing 9 being semi-cylindrical, 2 first bushings 9 being used in pairs.
The second bushing 10 is described in detail with respect to the second bushing 10, which is located below the metal backing ring and within the inner space formed by the outer pipe connector 3 and the coiled tubing outer pipe 1, for transferring axial loads and sealing drilling fluid in the annular space of the tool joint for double casing coiled tubing. The second bush 10 is cylindrical, and both the inner wall side and the outer wall side thereof are provided with seal grooves in which a seal ring 12 and a retainer ring 13 are disposed. More specifically, its inner wall side and outer wall side are provided with 2 annular seal grooves respectively.
More specifically, the length of the outer tube 1 extends to the section where the first bush 9 and the second bush 10 are matched, and specifically, the end surface of the outer tube 1 is matched with the second bush 10. In this case, the tube sandwich, the gap between the inner side wall of the first liner 9 and the outer side wall of the inner tube 2, and the second flow channel 6 communicate to form a second fluid passage. More specifically, the first bushing 9 includes 2 semi-cylindrical structures. When the pipe fitting is attached, the lower end surface of the second bush 10 is brought into contact with the upper end surface of the first bush 9, and the lower end surface of the first bush 9 is brought into contact with the upper shoulder surface of the inner pipe connector 4.
In a specific structure design, the outer pipe connector 3 and the inner pipe connector 4 are assembled by a threaded connection, and the outer pipe connector 3 and the inner pipe connector 4 are fixedly assembled by a set screw 11 after being assembled and connected. As a concrete description, in this design the outer tube connector 3 is provided with an internal thread and the inner tube connector 4 is provided with an external thread, which internal thread is at a distance from the end of the outer tube connector 3 for the fitting of a set screw. The specific assembly of the set screw 11 is: a plurality of screw holes are uniformly distributed on the circumferences of the outer pipe connector 3 and the inner pipe connector 4, and set screws 11 are fitted in the screw holes for preventing screw back-off. As will be described in more detail, the other end of the inner pipe connector 4 is also provided with a thread for connection to a downhole tool.
As a more specific design, as a specific structural design, the outer structure of the slip 7 is a conical shape, a section of cylinder is arranged at the large end of the conical shape, and an axial slip tooth 71 and an annular slip tooth 72 are processed inside the slip 7. Wherein the axial slip elements 71 are adapted to bear torque and the circumferential slip elements 72 are adapted to bear axial load. The stress is considered to be uniform, and in addition, the slips 8 are uniformly distributed with slots in the circumferential direction. The slotting effect is as follows: the two end parts of the slip 8 are both provided with strip-shaped grooves which are distributed in a circumferential array, and the strip-shaped grooves at the two end parts are arranged in a crossed manner. Considering that the slip 7 needs to be deformed annularly and the slip teeth need to have higher hardness, the slip 7 is made of 20 CrMnTi. The axial tooth type section and the annular tooth type section of the slip 7 can be segmented and independent or mutually communicated and intersected in the slip axial direction, and only the segmented and independent axial tooth and annular tooth in the slip axial direction are listed in the embodiment.
As a more specific design for the inner tube connector, the first flow channel 5 is a through hole penetrating through the middle of the inner tube connector, the second flow channel 6 is a plurality of strip-shaped flow channels uniformly distributed on the outer side of the first flow channel, and the second flow channel 6 penetrates through the inner tube connector. In this design, illustrated in the drawings, the second flow channels 6 are distributed in a circumferential array to ensure the overall rigidity of the inner pipe connector 4.
On the basis of the specific structural design, as an assembly mode of the outer pipe 1, the connecting screw thread between the outer pipe connector 3 and the inner pipe connector 4 is screwed, so that the inner conical surface on the upper part of the outer pipe connector 3 is tightly pressed with the outer conical surface of the slips 7, further the slips are pressed into the outer pipe 1, the axial load and the working torque of the double-layer continuous pipe tool joint during working are borne according to the friction force between the inner conical surface of the outer pipe connector 3 and the outer conical surface of the slips 7 and the friction force between the inner wall surface of the slips 7 and the outer pipe 1 of the double-layer continuous pipe, and the connection between the slips and the outer pipe of the double-layer continuous pipe tool joint and.
Secondly, as the assembly mode of the inner pipe 2, the inner pipe 2 is pressed into an annular groove at the upper part of the inner pipe connector 4 by a special tool, two sides of the annular groove are supplemented with sealing grooves, and a sealing ring 12 and a retaining ring 13 are arranged in the annular groove to seal the drilling fluid. As a specific description, the end of the inner pipe connector 4 for connecting the outer pipe connector 3 is further provided with a fitting portion for fitting the inner pipe 2, and the fitting portion is provided with a plurality of annular grooves, and the inner pipe 2 is fitted to the fitting portion. In a more specific design, two sides of the annular groove are also provided with sealing grooves, and a sealing ring 12 and a retaining ring 13 are assembled in the annular groove. The sealing effect of the structure is effectively realized by means of the mode.
As a more specific description, in fig. 1, the upper end is the upper portion in use and the lower end is the lower portion in use, depending on the actual state. The outer pipe connector 3 is described, the inner conical surface of the middle part of the outer pipe connector 3 is pressed against the outer conical surface of the slips 7, so that the slips are pressed against the outer pipe 1, and the slips 7 are connected with the outer pipe 1. Inside the cylindrical structure in the middle of the outer pipe connector 3 is mounted a backing ring 8 (metal pad), a first bushing 9 and a second bushing 10 for transferring axial loads and compensating axial deformations. The connecting thread at the lower end of the outer pipe connector 3 is matched with the connecting thread at the upper end of the inner pipe connector, so that the outer pipe connector 3 is pressed against the slips 7, the slips 7 are pressed against the outer pipe 1, and the function that the slips 7 clamp the outer pipe 1 is realized. The lower end of the thread of the outer pipe connector 3 is uniformly provided with threaded holes along the circumferential direction for installing retaining set screws 11 and preventing the thread from being reversely buckled.
Example 2
Based on embodiment 1, a further design is made for the inner tube connector 4, and the upper part of the inner tube connector 4 is provided with uniformly distributed annular grooves for connecting the inner tube 2. Meanwhile, two sides of the annular groove are provided with sealing grooves for installing a sealing ring 12 and a check ring 13 to seal the drilling fluid.
In a more specific structural design, an acme female trapezoidal thread is arranged in the middle of the inner pipe connector 4 and is used for connecting the outer pipe connector 3. Seal grooves are formed in two sides of the Ack female thread and used for installing a seal ring 12 and a check ring 13 to seal drilling fluid. The lower part of the lower side sealing groove of the Ack female thread is provided with a circumferential groove for mounting a set screw 11. As a specific description, the outer tube connector 3 is provided with an acme female thread matching with the inner tube connector.
As a more specific design, the lower part of the inner pipe connector 4 is provided with a digital thread for connecting a downhole tool. The lower part of the digital thread is also provided with a cylindrical part for matching with a downhole tool, and the cylindrical part is provided with a sealing groove in which a sealing ring 12 and a retainer ring 13 can be assembled. So as to seal the drilling fluid and form a drilling fluid input flow passage.
Between the acme female thread and the number thread is provided a thickening cylinder to facilitate gripping of the inner tube connector 4 when the threads are tightened.
Example 3
On the basis of embodiment 1 and different from embodiment 1, on the basis of the design of the present structure, it is theoretically applicable that the first liquid passage is a liquid discharge passage of liquid, and the second liquid passage is a liquid feed passage.
Specifically, the first liquid channel formed by the communication between the first flow channel 5 and the inner tube 2 is a liquid discharge channel, and the second liquid channel formed by the communication between the second flow channel 6 and the tube clamping layer is a liquid inlet channel.
Example 4
In the following description, based on the structural design of embodiments 1 to 3, taking fig. 1 as an example, the upper end (the upper end of the outer pipe connector) is the upper portion when in use, and the lower end (the lower end of the inner pipe connector connecting tool) is the lower portion when in use, in accordance with the actual state.
A double-layer continuous pipe tool joint structure assembling method comprises the following steps:
a. assembling an outer pipe connecting device, namely selecting an outer pipe 1, and sequentially sleeving an outer pipe connector 3, a slip 7, a backing ring 8 and a second lining 10 with a sealing device from the lower end of the outer pipe 1;
b. assembling the inner pipe 2 with the inner pipe connector 4, aligning the upper shoulder surface of the inner pipe connector 4 with the lower end surface of the inner pipe 2, and keeping the position of the inner pipe connector 4 fixed; then, pressing the inner pipe 2 into the annular groove of the inner pipe connector 4 by using a tool to complete the connection of the inner pipe connector 4 and the inner pipe 2;
c. installing a first bush 9, installing the first bush 9 of 2 semicircular rings outside the assembled inner pipe 2, and moving a second bush 10 downwards to enable the lower end face of the second bush 10 to be in contact with the upper end face of the first bush 9 and the lower end face of the first bush 9 to be in contact with the upper shoulder face of the inner pipe connector 4;
then, the backing ring 8 and the slip 7 are moved downwards in sequence, so that the lower end face of the backing ring 8 is contacted with the upper end face of the second lining 10, and the lower end face of the slip 7 is contacted with the upper end face of the backing ring 8;
then the outer pipe connector 3 is moved downwards, so that the lower end face of the outer pipe connector 3 is below the lower end face of the first lining 10, and the lining 1 is primarily installed;
d. installing the outer pipe connector 3, continuing to move the outer pipe connector 3 downwards, and connecting the outer pipe connector 3 with the threads of the inner pipe connector 4 through the threads on the outer pipe connector until the thread tightening torque reaches the design requirement;
e. and installing set screws 11, and after the threaded connection of the outer pipe connector 3 and the inner pipe connector 4 is completed, installing the backstopping set screws 11 at the positions of the lower end of the outer pipe connector 3, which are uniformly provided with holes in the axial direction, so as to prevent the threads from being reversely buckled.
In summary, the following steps:
1. the double-layer continuous pipe tool joint structure solves the problem that the traditional continuous pipe usually adopts a single-layer structure, the structure has a double-channel effect by means of the design of an inner pipe and an outer pipe, meanwhile, the input and the discharge of liquid are effectively realized by means of the double-channel and independently designed channels, the assembly is convenient from the design of the structure, the double-layer continuous pipe tool joint structure further has the adaptability of the continuous pipe, and the difficulty of field construction and the production cost of the device are reduced;
2. according to the double-layer continuous pipe tool joint structure, the outer pipe is effectively assembled through the design of the outer pipe connecting device, the clamping effect of the clamping piece on the outer pipe is effectively guaranteed in the axial direction, and the problems that the outer pipe is loosened and falls off or the sealing effect is poor in the using process are solved;
3. the double-layer continuous pipe tool joint structure effectively realizes modularization of each connecting part on the structural design, can effectively reduce the assembly difficulty of the continuous pipe tool structure, is convenient for processing the whole structure, and effectively breaks through the difficult problem of double-layer continuous pipe tools.
The invention is not limited to the foregoing embodiments. The invention extends to any novel feature or any novel combination of features disclosed in this specification and any novel method or process steps or any novel combination of features disclosed.

Claims (10)

1. The utility model provides a double-deck coiled tubing tool joint structure which characterized in that: including outer tube connecting device and inner tube connecting device, inner tube connecting device is connected with the inner tube, outer tube connecting device is connected with the outer tube, be provided with first runner in the inner tube connecting device, first runner forms first liquid channel with the inner tube intercommunication, the inner tube is located to the inner tube cover, the lateral wall of inner tube with the outer tube inside wall between have the clearance in order to form the pipe intermediate layer, the inner tube connecting device at first runner outside place is provided with the second runner, the second runner forms second liquid channel with pipe clamp layer intercommunication.
2. The double layer coiled tubing tool joint construction of claim 1, wherein: the outer pipe connecting device comprises an outer pipe connector and an outer pipe assembling structure for assembling an outer pipe, the inner pipe connecting device is an inner pipe connector, and the outer pipe connector is assembled and connected with the inner pipe connector.
3. The double-layered coiled tubing tool joint construction of claim 2, wherein: the outer pipe assembling structure comprises slips which are arranged inside the outer pipe connector and used for assembling the outer pipe, and a lining is further arranged between the slips and the inner pipe connector.
4. A double layer coiled tubing tool joint construction of claim 3, wherein: the inner side of one end part of the outer pipe connector is conical for assembling slips, the slips clamp the outer pipe through the matching of the conical shape and the slips, and the other end part of the outer pipe connector is assembled and connected with the inner pipe connector.
5. A double layer coiled tubing tool joint construction of claim 3, wherein: still be provided with the backing ring between slips and the bush, the backing ring is annular spring pad, the backing ring includes 1 outer loop and 2 inner rings, the outer loop with the inner ring contact surface is the conical surface.
6. The double layer coiled tubing tool joint construction of claim 5, wherein: the bushing comprises a first bushing and a second bushing, the second bushing is arranged between the first bushing and the backing ring, the first bushing is arranged between the second bushing and the end of the inner pipe connector, the first bushing is semi-cylindrical, and 2 first bushings are used in pairs.
7. A double layer coiled tubing tool joint construction of claim 3, wherein: the outer pipe connector and the inner pipe connector are assembled through threaded connection, the outer pipe connector and the inner pipe connector are fixedly assembled through a set screw after being assembled and connected, and the other end of the inner pipe connector is further provided with threads for connecting a downhole tool.
8. A double layer coiled tubing tool joint construction of claim 3, wherein: the slip is characterized in that the outer structure of the slip is conical, a section of cylinder is arranged at the large end of the cone, and axial slip teeth and annular slip teeth are machined in the slip.
9. The double-layered coiled tubing tool joint construction of claim 2, wherein: the first flow channel is a through hole penetrating through the middle part of the inner pipe connector, the second flow channel is a plurality of strip-shaped flow channels uniformly distributed on the outer side of the first flow channel, and the second flow channel penetrates through the inner pipe connector.
10. The assembling method of the double-layer continuous pipe tool joint structure is characterized by comprising the following steps of: the method comprises the following steps:
a. assembling an outer pipe connecting device, namely selecting an outer pipe, and sequentially sleeving an outer pipe connector, a slip, a backing ring and a second lining with a sealing device from the lower end of the outer pipe;
b. assembling the inner pipe and the inner pipe connector, aligning the upper shoulder surface of the inner pipe connector with the lower end surface of the inner pipe, and keeping the position of the inner pipe connector fixed; then pressing the inner pipe into the annular groove of the inner pipe connector 4 by using a tool to complete the connection of the inner pipe connector and the inner pipe;
c. installing a first bushing, installing the 2 semi-cylindrical first bushing outside the assembled inner pipe, and moving a second bushing downwards to enable the lower end surface of the second bushing to be in contact with the upper end surface of the first bushing and the lower end surface of the first bushing to be in contact with the upper shoulder surface of the inner pipe connector;
then the backing ring and the slip are sequentially moved downwards, so that the lower end face of the backing ring is contacted with the upper end face of the second lining, and the lower end face of the slip is contacted with the upper end face of the backing ring;
then the outer pipe connector is moved downwards, so that the lower end face of the outer pipe connector is below the lower end face of the first bushing, and the bushing is initially installed;
d. installing the outer pipe connector, continuously moving the outer pipe connector downwards, and connecting the outer pipe connector with the thread of the inner pipe connector through the thread on the outer pipe connector until the thread tightening torque reaches the design requirement;
e. and after the threaded connection of the outer pipe connector and the inner pipe connector is completed, the anti-return set screws are installed at the positions of the holes axially and uniformly distributed at the lower end of the outer pipe connector, so that the threads are prevented from being reversely buckled.
CN202010629470.XA 2020-07-03 2020-07-03 Double-layer continuous pipe tool joint structure and assembling method thereof Pending CN111794691A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202010629470.XA CN111794691A (en) 2020-07-03 2020-07-03 Double-layer continuous pipe tool joint structure and assembling method thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202010629470.XA CN111794691A (en) 2020-07-03 2020-07-03 Double-layer continuous pipe tool joint structure and assembling method thereof

Publications (1)

Publication Number Publication Date
CN111794691A true CN111794691A (en) 2020-10-20

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Family Applications (1)

Application Number Title Priority Date Filing Date
CN202010629470.XA Pending CN111794691A (en) 2020-07-03 2020-07-03 Double-layer continuous pipe tool joint structure and assembling method thereof

Country Status (1)

Country Link
CN (1) CN111794691A (en)

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