CN107420086B - Simulation method and system for drill rod rotating speed in deep water conduit running-in process - Google Patents

Abstract

The invention discloses a method and a system for simulating the rotating speed of a drill rod in the process of running a deepwater conduit into a water well, wherein the method comprises the following steps: according to the soil distribution of a target seabed area, arranging layered soil for experiments in a soil box, maintaining a preset experiment condition, and adjusting the rotating speed of a motor in the injection launching device for multiple times so as to adjust the rotating speed of a drill rod; reference signals are collected through a multi-channel data collector electrically communicated with a pressure sensor, a tension sensor, a displacement sensor and a jet pump, and the reference signals comprise: pressure signals, tension signals, displacement signals; and selecting the target drill rod rotating speed in the process of running the deepwater conduit under the preset experimental condition according to the acquired reference signal. The method and the system for simulating the rotating speed of the drill rod in the running process of the deepwater conduit can be used for carrying out indoor experimental simulation and evaluation on the rotating speed of the drill rod in the running process of the deepwater conduit.

Description

Simulation method and system for drill rod rotating speed in deep water conduit running-in process

Technical Field

The invention relates to the technical field of pipe jet running in deepwater drilling, in particular to a method and a system for simulating the rotating speed of a drill rod in the running process of a deepwater pipe.

Background

In the oil and gas drilling industry of ocean engineering, the jet pipe descending technology is widely applied because the time of drilling operation can be saved and the effects of reducing the risk and the cost of drilling can be achieved. Further, a deep water jet guide pipe suction technology is specially designed for the development of oil and gas fields in deep water areas, and is a new technology developed on the basis of jet drilling and mud motor application. When the technology is implemented, a drill bit and a mud motor are lowered into a special tool through a guide pipe and form a jet lowering string, namely a drill string. The drill bit is mainly used for crushing soil in front of a guide pipe shoe, and then pumping mud through the drill column to carry rock debris out of the bottom of the well from the annular space between the inner wall of the guide pipe and the drill column and directly discharge the rock debris into the seabed. During run in, the guide pipe sinks under its own weight and the weight of the entire drill string etc. down the pilot drilled with the drill bit and squeezes the surrounding formation to the design depth. After running to the design depth, after a certain "waiting time", cementing stresses are built up between the pipe and the formation clay and consolidated over time, thus ensuring that the pipe is "suspended" from sinking.

When using jet run-in conduit technology, it is necessary to determine the run-in depth of the conduit and the construction parameters during the run-in process. On one hand, if the designed running depth of the guide pipe is too large, economic waste can be caused, even the guide pipe cannot run into the guide pipe, and the exposed mud surface line of the seabed wellhead is too high to cause well hole scrapping; on the other hand, if the designed running depth of the guide pipe is too small, safety accidents such as insufficient bearing capacity of a pipe column of the guide pipe, sinking and instability of a wellhead and the like can be caused, and huge economic waste is also caused. In addition, one of the core construction parameters in the running process is the running speed of the guide pipe. Wherein the descending speed of the guide pipe depends on the rotating speed of the drill rod. Therefore, it is necessary to provide a method and a system for simulating the drill rod rotation speed during the running-in process of the deepwater conduit, so as to simulate and evaluate the drill rod rotation speed, thereby obtaining reasonable drill rod rotation speed parameters, providing a basis for the deepwater conduit to be sprayed and run-in, finally realizing the improvement of drilling efficiency and saving expensive deepwater drilling cost.

Disclosure of Invention

The invention aims to provide a method and a system for simulating the rotating speed of a drill rod in the running-in process of a deepwater guide pipe, which can be used for carrying out indoor experimental simulation and evaluation on the rotating speed of the drill rod in the running-in process of the deepwater guide pipe.

The above object of the present invention can be achieved by the following technical solutions:

a method for simulating the rotating speed of a drill rod in the process of running a deepwater guide pipe comprises the following steps:

according to the soil distribution of a target seabed area, arranging layered soil for experiments in a soil box, and arranging a pressure sensor in the layered soil, wherein an experiment frame is arranged outside the soil box;

installing a jet running-in device on the experiment frame, and arranging a tension sensor at the position where the jet running-in device is connected with the experiment frame; a displacement sensor is arranged above the jet running-in device; communicating the jet running-in device with a jet pump, wherein a motor and a drill rod for transmitting rotary power to a conduit are arranged in the jet running-in device;

maintaining a preset experimental condition, and regulating the rotating speed of the motor for multiple times so as to regulate the rotating speed of the drill rod;

through with pressure sensor, tension sensor, displacement sensor and jet pump electric property intercommunication's multichannel data collection station gather reference signal, reference signal includes: pressure signals, tension signals, displacement signals;

and selecting the target drill rod rotating speed in the process of running the deepwater conduit under the preset experimental condition according to the acquired reference signal.

In a preferred embodiment, the lower end of the drill rod is provided with a drill bit, and the predetermined experimental conditions include: a predetermined weight-on-bit, a predetermined bit extension.

A system for evaluating the rotation speed of a drill rod in the process of running a deepwater guide pipe comprises:

the device comprises an experiment frame, a soil box provided with a layered soil body, a jet running device, a jet pump, a multi-channel data collector, a controller, a displacement sensor, a pressure sensor and a tension sensor; wherein the content of the first and second substances,

the injection running-in device is provided with: the drill pipe comprises a motor, a drill rod and a guide pipe, wherein the motor is provided with a rotating shaft; the drill rod penetrates through the guide pipe, a drill bit is arranged at the lower end of the drill rod, and the upper end of the drill rod is connected with the rotating shaft;

the controller stores a target descending distance of the catheter; the controller is electrically connected with the multi-channel data acquisition unit;

the multi-channel data acquisition unit is electrically connected with the displacement sensor, the pressure sensor, the tension sensor and the jet pump,

and maintaining a preset experimental condition, adjusting the rotating speed of the drill rod by adjusting the rotating speed of the motor, sending a closing signal to the jet pump and the jet running-in device by the controller through the multi-channel data acquisition unit each time when the displacement signal detected by the displacement sensor indicates the running-in distance of the pipe running-in target, and selecting the target rotating speed of the drill rod in the running-in process of the deepwater pipe under the preset experimental condition by the controller according to the signals acquired by the sensors.

In a preferred embodiment, the pressure sensors are distributed optical fiber pressure sensors, and the pressure sensors are arranged at equal intervals along the soil stress measuring points in the vertical direction and at equal intervals along the radial direction of the guide pipe.

In a preferred embodiment, the jet drive-in apparatus comprises:

a conduit having a longitudinally extending chamber;

the gland is sleeved at the upper end of the guide pipe; a liquid discharge hole is formed in the gland and communicated with the cavity for discharging liquid in the cavity;

a drilling assembly, comprising:

a motor provided with a rotating shaft;

the drill rod penetrates through the guide pipe, the lower end of the drill rod is provided with a drill bit, and the upper end of the drill rod is connected with the rotating shaft;

the liquid injection head is arranged at the upper end of the rotating shaft and is used for injecting liquid into the drill rod;

and the balancing weight is positioned at the upper part of the liquid injection head and is used for adjusting the drilling pressure of the drill rod component.

In a preferred embodiment, the drill head further comprises an adjustment mechanism for adjusting the extent to which the drill head protrudes relative to the lower end of the guide tube.

In a preferred embodiment, the adjustment mechanism is disposed between the gland and the conduit.

In a preferred embodiment, the adjusting mechanism is a matching mechanism of an adjusting bolt and a threaded hole, a first extending portion extending along the longitudinal direction is formed on the press cover, the first extending portion is sleeved at the upper end of the guide pipe, a plurality of threaded holes are distributed on the first extending portion along the circumferential direction or the longitudinal direction, and the adjusting bolt can penetrate through the threaded holes.

In a preferred embodiment, a second extension portion is further disposed on the press cover and located inside the first extension portion, the first extension portion and the second extension portion form a concentric annular cavity, and the upper end of the catheter can be clamped into the concentric annular cavity formed by the first extension portion and the second extension portion.

In a preferred embodiment, a rotary sealing spherical head is arranged between the liquid injection head and the rotating shaft, the liquid injection head is fixedly connected with the rotary sealing spherical head, and the rotating shaft is rotatably connected with the rotary sealing spherical head.

In a preferred embodiment, the motor is disposed on the press cover, and the motor is an electric motor or a hydraulic motor.

The invention has the characteristics and advantages that: according to the method and the system for simulating the rotating speed of the drill rod in the running-in process of the deepwater guide pipe, which are provided by the invention, the influence analysis of the rotating speed of the drill rod on the running-in process of the guide pipe in the running-in process can be simulated through the motor, the rotating shaft and the like in the jet running-in device, the indoor experimental evaluation can be carried out on the rotating speed construction parameters of the drill rod in the running-in process of the deepwater guide pipe, so that the complex linear correlation relation between the soil quality condition of the seabed and the process parameters of a running pipe column is researched, therefore, reasonable rotating speed parameters of the drill rod are obtained, a basis is provided for the jet running-in of the deepwater guide pipe, the hydraulic jet auxiliary.

Specific embodiments of the present application are disclosed in detail with reference to the following description and drawings, indicating the manner in which the principles of the application may be employed. It should be understood that the embodiments of the present application are not so limited in scope. The embodiments of the application include many variations, modifications and equivalents within the spirit and scope of the appended claims.

Features that are described and/or illustrated with respect to one embodiment may be used in the same way or in a similar way in one or more other embodiments, in combination with or instead of the features of the other embodiments.

It should be emphasized that the term "comprises/comprising" when used herein, is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps or components.

Drawings

FIG. 1 is a schematic structural diagram of a system for evaluating the rotation speed of a drill rod in a process of running a deep water pipe in an embodiment of the application;

FIG. 2 is a schematic view of a jet drive-in apparatus according to an embodiment of the present disclosure;

fig. 3 is a flowchart illustrating steps of a method for simulating the rotation speed of a drill pipe during a process of running a deep water pipe in accordance with an embodiment of the present disclosure.

Description of reference numerals:

1-experiment frame; 2-a soil box; 3-a jet run-in device; 4-a displacement sensor; 5-a pressure sensor; 6-layered soil body; 7-a jet pump; 8-a multi-channel data collector; 9-a controller; 10-a tension sensor; 31-a lifting ring; 32-a counterweight block; 33-liquid injection head; 34-rotating the sealed spherical head; 35-a motor; 36-a rotating shaft; 37-a gland; 38-drain holes; 311-drill rods; 312-a catheter; 313-a centralizer; 314-a drill bit; 315-a chamber; 111. a first extension portion; 112. a second extension portion; 39-adjusting member.

Detailed Description

The technical solutions of the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments, it should be understood that these embodiments are merely illustrative of the present invention and are not intended to limit the scope of the present invention, and various equivalent modifications of the present invention by those skilled in the art after reading the present invention fall within the scope of the appended claims.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

When the deepwater conduit running design is carried out, a running pipe column needs to be simulated and designed and calculated so as to research the complex nonlinear relation between the soil condition of the seabed stratum and the running controllability parameters (such as bit pressure, drilling fluid discharge capacity, drill rod rotating speed, drill bit elongation, drill bit size, conduit running speed and the like). Furthermore, the hydraulic jet auxiliary soil breaking capacity is realized by optimizing the types of the drill bits and the drilling parameters for different stratums, so that not only can the time be greatly saved, but also the expensive deepwater drilling cost is saved, the effect of improving the drilling efficiency is very obvious, and the hydraulic jet auxiliary soil breaking capacity has great significance for the jet running-in technology.

The invention provides a method and a system for simulating the rotating speed of a drill rod in the running-in process of a deepwater guide pipe, which can be used for carrying out indoor experimental simulation and evaluation on the rotating speed construction parameters of the drill rod in the running-in process of the deepwater guide pipe, thereby obtaining reasonable rotating speed parameters of the drill rod, providing a basis for the jet running-in of the deepwater guide pipe, finally realizing the improvement of drilling efficiency and saving expensive deepwater drilling cost.

Referring to fig. 1 and 2, in an embodiment of the present application, there is provided a system for evaluating a rotation speed of a drill pipe during a deep water pipe running process, where the system may include: the device comprises an experiment frame 1, a soil box 2 provided with a layered soil body 6, a jet running device 3, a jet pump 7, a multi-channel data collector 8, a controller 9, a displacement sensor 4, a pressure sensor 5 and a tension sensor 10.

In this embodiment, the experimental rig 1 may be erected on the periphery of the soil box 2, which may be used to provide the suspension force of the jet drive-down apparatus 3. Specifically, the experiment frame 1 may have a horizontal plate and a plurality of support plates supporting the horizontal plate, and the plurality of support plates may be fixed on a plane on which the experiment frame 1 is placed. In addition, the form of the experimental rack 1 is not limited to the above examples, and the present application is not specifically limited thereto. In addition, the tension sensor 10 may be fixed to the laboratory bench 1. For example, it may be fixed to the horizontal plate.

A connecting piece can be arranged between the tension sensor 10 and the injection running-in device 3, one end of the connecting piece is connected with the tension sensor 10, and the other end of the connecting piece is connected with the injection running-in device 3. The tension sensor 10 may be provided on the link. Specifically, the form of the connecting member may be a steel wire rope, or the like, or may also be other forms, and the application is not limited in particular herein. The tension sensor 10 is used to calculate the weight-on-bit, i.e. weight-on-bit.

In the present embodiment, the soil box 2 may be used for accommodating soil for simulating a seabed stratum, and specifically, the soil box 2 may have a hollow box shape having a bottom wall and a side wall surrounding the bottom wall. The cross-sectional shape of the soil box 2 may be rectangular, circular, etc., or may even be other irregular shapes, and the specific application is not limited in this respect.

In the present embodiment, the soil box 2 has a certain depth, and a layered soil body 6 is disposed in the soil box 2 according to the distribution of the bottom soil body of the seabed, so as to simulate the soil body distribution of the target seabed area.

In this embodiment, the jet running device 3 may be used to run the catheter 312 into the designed depth. Specifically, referring to fig. 2 in combination, an injection insertion device 3 provided in the embodiment of the present application may include: a conduit 312 having a longitudinally extending cavity 315; a gland 37 fitted over the upper end of the guide tube 312; a liquid discharge hole 38 is arranged on the gland 37 at the upper end of the guide pipe 312, and the liquid discharge hole 38 is communicated with the cavity 315 for discharging liquid in the cavity 315; a drilling assembly, comprising: a motor 35 provided with a rotating shaft 36; a drill rod 311 at least partially penetrating the guide pipe 312, wherein a drill bit 314 is arranged at the lower end of the drill rod 311, and the upper end of the drill rod is connected with the rotating shaft 36; a weight block 32 provided at an upper portion of the guide pipe 312 for adjusting a drilling pressure of the drill pipe 311; and an injection head 33 provided at the upper end of the rotary shaft 36 for injecting liquid into the drill pipe 311.

By utilizing the jet running-in device 3 provided by the application, the adjustment of each parameter can be carried out in a laboratory, and the influence of each parameter on the running-in process in the jet running-in process of the deep water jet drilling guide pipe 312 is analyzed. Wherein, the design of the balancing weight 32 can simulate and analyze the influence analysis of different drilling pressures on the descending of the drilling conduit 312; the motor 35 can simulate and analyze the effect of the rotational speed of the drill pipe 311 on the running process of the drill pipe 312; the design of the drain hole 38 can simulate the well bottom return drilling fluid drain passage, and further determine the influence of the flow rate of the drilling fluid drain on the running-in process of the drilling guide pipe 312; the injection head 33 can control the injection amount of the drilling fluid, the influence of the injection amount of the drilling fluid on the drilling process can be analyzed, and the parameters can be optimized through the components, so that the construction efficiency of the drilling guide pipe 312 in the actual construction process is improved.

In this embodiment, the conduit 312 may have a longitudinally extending chamber 315 (in the operating state). The chamber 315 may be a cylindrical chamber 315, such that the drill rod 311 can be inserted into the guide tube 312 and can rotate relative to the guide tube 312. The pressing cover 37 may be a cover body having an upper end closed and a lower end opened. The inner diameter of the gland 37 is matched with the outer diameter of the conduit 312, so that the gland 37 can be sleeved on the conduit 312, and the upper end of the conduit 312 is blocked. Wherein, the mode of cover establishing can include threaded connection, joint or welding. Of course, the guide tube 312 may have other structures, and is not limited to the structure limited by the present embodiment.

The drilling assembly may include a drill pipe 311 and a motor 35 drivingly connected to the drill pipe 311. Drill pipe 311 is used to drill into a formation (laboratory test formation, where the reference to the test formation may also be adjusted). Specifically, the drill pipe 311 may be at least partially disposed within the conduit 312. The upper end of the drill rod 311 may be rotatably connected to the gland 37. The lower end of the drill pipe 311 may be provided with a drill bit 314, the drill bit 314 being driven by the drill pipe 311 to drill a well downwards. To facilitate rotation of the drill rod 311 by the motor 35, the motor 35 may be disposed on the gland 37. The motor 35 and the drill rod 311 can be in transmission connection by means of a rotating shaft 36, so that the motor 35 can drive the drill rod 311 to rotate. The motor 35 can simulate and analyze the influence of the rotating speed of the drill rod 311 on the running-in process of the drilling guide pipe 312, analyze the influence of the rotating speed on the running-in process of the drilling guide pipe 312 in the jetting and running-in process of the deep water jetting, and further optimize parameters, so that the construction efficiency in the actual construction process is improved. Wherein the motor 35 may comprise at least one of an electric motor 35 and a hydraulic motor 35. The transmission mode between the motor 35 and the drill rod 311 is not limited to the connection mode of the rotating shaft 36, and may also be a gear connection or a chain connection, which is not limited in the present application.

In an alternative embodiment, a centralizer 313 may be disposed within the conduit 312 for centralizing the drill rod 311.

In the present embodiment, an injection head 33 may be provided at the upper end of the rotating shaft 36, and the injection head 33 communicates with the drill rod 311 and injects a liquid into the drill rod 311. After entering the drill pipe 311, the liquid can continuously drain the formation components drilled by the drill bit 314 out of the drainage hole 38, thereby ensuring that the drill bit 314 continuously drills downwards.

In the present embodiment, the drain hole 38 may be provided in the cover 37, and the drain hole 38 communicates with the chamber 315 to discharge the liquid in the chamber 315. Specifically, the drain hole 38 may be provided at an upper end of the gland 37 or circumferentially on a side wall of the gland 37. Preferably, the drain holes 38 may be formed on a sidewall of the pressing cover 37 at equal intervals in the circumferential direction. The liquid discharge hole 38 is communicated with the cavity 315, so that a channel for discharging the drilling fluid in the cavity 315 is formed, the influence of the discharge flow of the drilling fluid on the running-in process of the drilling guide pipe 312 is determined, and further parameter optimization is performed, so that the construction efficiency in the actual construction process is improved. Wherein the greater the number of ports 38, the greater the flow rate of drilling fluid exiting.

A weight 32 may be provided at the upper portion of the gland 37, which adjusts the drilling pressure of the drill pipe 311 by changing its own weight or changing the value of the pressure applied to the guide pipe 312. The weight 32 can apply a pressure to the gland 37 which in turn can act on the drill pipe 311 so that the drill pipe 311 has a drilling pressure towards the drilling direction so that the drill pipe 311 can continue to drill downwards. The counterweight 32 can adjust the self weight or adjust the pressure on the gland 37 in a hydraulic adjusting mode, so that an experimenter can analyze the influence of the drilling pressure on the running-in process of the deep water jet drilling guide pipe 312 in the jet running-in process of the deep water jet drilling guide pipe 312 by adjusting the pressure applied to the gland 37 by the counterweight 32 in a laboratory, and further optimize parameters, thereby improving the construction efficiency in the actual construction process.

In an alternative embodiment, a position limiting part for arranging the counterweight 32 is fixed above the liquid injection head 33, and the upper end of the position limiting part is provided with a hanging ring 31. The limiting portion may be sleeved with a plurality of counterweights 32 with different masses, so that the counterweights 32 provide different drilling pressures to the drill rod 311.

In this embodiment, the jet running device 3 further comprises an adjusting member 39, and the adjusting member 39 is used for adjusting the length of the part of the lower end of the drill rod 311 extending out of the guide pipe 312. Specifically, the adjusting member 39 may be disposed between the gland 37 and the guide pipe 312 such that the adjusting member 39 can adjust the position of the guide pipe 312 with respect to the gland 37, that is, the distance between the upper end of the guide pipe 312 and the bottom wall of the gland 37 can be adjusted, the length of the portion of the lower end of the drill rod 311 protruding out of the guide pipe 312 becomes longer when the distance is shortened, and the length of the portion of the lower end of the drill rod 311 (the drill bit 314) protruding out of the guide pipe 312 decreases when the distance is increased. The design mode of the application can realize the extension of different drill bits 314 in the process of running in through the simulated drilling guide pipe 312 in a laboratory so as to research the soil breaking efficiency of the pipe column combination on specific seabed soil conditions under the condition of the extension of different drill bits 314, and further optimize parameters, thereby improving the construction efficiency in the actual construction process.

In a specific embodiment, the adjustment member 39 may be a mating mechanism of an adjustment bolt and a threaded hole. An adjustment bolt may be provided between the gland 37 and the conduit 312. For example, an adjustment bolt may be threaded into the conduit 312, with the end of the adjustment bolt abutting the outer wall of the conduit 312. When adjusting the extension of the drill 314, the operator may first loosen the adjusting bolt, then adjust the relative position between the gland 37 and the guide tube 312 to extend the drill 314 to a desired length, and then tighten the adjusting bolt. Of course, the present embodiment does not specifically limit the adjusting member 39 in the present application, and the adjusting member 39 can adjust the extending amount of the drill 314 according to the requirements of the present application.

Specifically, the gland 37 is formed with a first extending portion 111 extending along the longitudinal direction, the first extending portion 111 is sleeved on the upper end of the guide pipe 312, a plurality of threaded holes are circumferentially or longitudinally distributed on the first extending portion 111, and the adjusting bolt can be inserted into the threaded holes. The first extension portion 111 may be a cylindrical structure with a diameter larger than that of the guide tube 312, such that the first extension portion 111 can be sleeved on the guide tube 312, and the threaded hole may be disposed on the first extension portion 111, such that the guide tube 312 and the gland 37 can be fixed by the adjusting bolt.

In an alternative embodiment, the gland 37 is further provided with a second extension portion 112 located inside the first extension portion 111, the first extension portion 111 and the second extension portion 112 may form a concentric annular cavity, and the upper end of the conduit 312 can be clamped into the concentric annular cavity formed by the first extension portion 111 and the second extension portion 112, so as to ensure that the conduit 312 and the gland 37 can be stably connected.

In an alternative embodiment, the gland 37 may further be provided with a rotary sealing ball 34, and the rotary sealing ball 34 is rotatably connected to the upper end of the drill rod 311, so that the drill rod 311 can rotate relative to the guide pipe 312. Wherein, the rotary sealing spherical head 34 is positioned between the liquid injection head 33 and the gland 37, one end of the rotary sealing spherical head 34 is communicated with the liquid injection head 33, and the other end of the rotary sealing spherical head 34 is connected with the gland 37. A transmission member capable of being in transmission connection with a driving shaft of the motor 35 may be disposed in the rotary sealing spherical head 34, the drill rod 311 may extend into the rotary sealing spherical head 34 and be in rotation connection with the transmission member, and the motor 35 may further drive the drill rod 311 to rotate. Meanwhile, the drill pipe 311 can be communicated with the injection head 33 through the rotary sealing spherical head 34, and drilling fluid can be injected into the drill pipe 311 through the rotary sealing spherical head 34. Wherein, the rotary sealing spherical head 34, the balancing weight 32 and the gland 37 can be coaxially arranged. Of course, in other embodiments, the weight 32 and the rotary sealing spherical head 34 may be disposed on the pressing cover 37 in parallel, which is not limited in the present application.

In the present embodiment, the jet pump 7 is used to provide a high-pressure liquid flow to the jet running device 3, so as to realize the hydraulic jet auxiliary soil-breaking function. The pressure of the liquid flow provided by the jet pump 7 can be adaptively adjusted according to factors such as different soil distributions, and the like, and in particular, the present application is not limited specifically herein. Specifically, the outlet end of the jet pump 7 may be communicated with the liquid injection head 33 of the injection running-in device 3 through a high-pressure line. In addition, the jet pump 7 may be communicated with the multi-channel data collector 8, on one hand, the multi-channel data collector 8 may control the pump pressure of the jet pump 7 according to a predetermined pump pressure stored by the controller 9; on the other hand, the multi-channel data collector 8 can collect the pump pressure of the jet pump 7 in real time and then feed back the collected pump pressure data to the controller 9. Accordingly, the controller 9 may compare the fed-back pump pressure data with predetermined pump pressure data to monitor the operating state of the jet pump 7.

In this embodiment, the displacement sensor 4 is configured to detect a displacement signal of the conduit 312 in the jet drop device 3, convert the displacement signal of the conduit 312 in the jet drop device 3 into an electrical signal, and transmit the electrical signal to the controller 9 through the multi-channel data collector 8. The controller 9 stores a target lowering distance of the guide tube 312 in the jet lowering device 3, and when the lowering distance of the guide tube 312 in the jet lowering device 3 reaches the target lowering distance, the controller 9 controls the motor 35 to stop working, and accordingly, the guide tube 312 in the jet lowering device 3 stops moving down. Specifically, the displacement sensor 4 may be disposed directly above the jet running device 3, and the running depth of the guide pipe 312 in the jet running device 3 is determined by sensing the distance from the running position of the guide pipe 312 in the jet to the running position.

In this embodiment, the pressure sensor 5 is used to detect the pressure within the stratified soil 6. Specifically, in the test jetting and running process, the pressure sensor 5 can sense the stress change of the soil around the guide pipe 312 and the drill 314 along with the soil in the jetting process, so that the disturbance rule of the jetting and running process on the surrounding soil can be found. In particular, the pressure sensor 5 may be in the form of a distributed optical fiber pressure sensor 5, so as to preferably sense the soil stress variation of the soil body. Of course, the pressure sensor 5 may have other forms, and the present application is not limited thereto. When the pressure sensor 5 is a distributed optical fiber pressure sensor 5, the sensors may be arranged at equal intervals along the soil stress measuring point in the vertical direction, and at equal intervals along the radial direction of the conduit 312.

In this embodiment, the multi-channel data collector 8 is electrically connected to the displacement sensor 4, the pressure sensor 5, the tension sensor 10, and the jet pump 7, and is configured to collect corresponding data signals at the displacement sensor 4, the pressure sensor 5, the tension sensor 10, and the jet pump 7. Meanwhile, the multi-channel data collector 8 is electrically connected to the controller 9, so as to transmit the collected data to the controller 9, or receive the output signal of the controller 9, and transmit the output signal to each component electrically connected to the controller. In the present embodiment, the electrical connection may be a wired connection or a wireless connection, and the present application is not limited to this specific embodiment.

Specifically, the multi-channel data collector 8 may be a data collection product having a USB interface, and for example, may be: the SZSC-16S is a 16-channel, the SZSC-32S is a 32-channel, and the SZSC-16S and the SZSC-32S can be connected with various desktop computers, notebook computers and industrial personal computers with USB interfaces to form a high-performance data acquisition and measurement system.

In this embodiment, the controller 9 is configured to cooperate with the multi-channel data collector 8 to form a data collection and measurement system. The controller 9 may be a desktop computer, a notebook computer, an industrial personal computer, etc., and particularly, the form of the controller 9 is not limited in this application. The controller 9 may be provided with a USB interface, and is connected to the multichannel data collector 8 through the USB interface. Of course, the connection mode between the controller 9 and the multi-channel data collector 8 may also be connected in other wireless modes, such as bluetooth, infrared, or WIFI, specifically, this application is not limited in this respect. When the multi-channel data acquisition device is used specifically, the controller 9 can store, analyze and compare signals acquired by the multi-channel data acquisition device 8.

Referring to fig. 3, in an embodiment of the present application, there is also provided a method for simulating a rotation speed of a drill pipe during a deep water pipe running process, where the method may include the following steps:

step S10: according to the soil distribution of a target seabed area, arranging layered soil for experiments in a soil box, and arranging a pressure sensor in the layered soil, wherein an experiment frame is arranged outside the soil box;

step S12: installing a jet running-in device on the experiment frame, and arranging a tension sensor at the position where the jet running-in device is connected with the experiment frame; a displacement sensor is arranged above the jet running-in device; communicating the jet running-in device with a jet pump, wherein a motor and a drill rod for transmitting rotary power to a conduit are arranged in the jet running-in device;

step S14: maintaining a preset experimental condition, and regulating the rotating speed of the motor for multiple times so as to regulate the rotating speed of the drill rod;

step S16: through with pressure sensor, tension sensor, displacement sensor and jet pump electric property intercommunication's multichannel data collection station gather reference signal, reference signal includes: pressure signals, tension signals, displacement signals;

step S18: and selecting the target drill rod rotating speed in the process of running the deepwater conduit under the preset experimental condition according to the acquired reference signal.

In the embodiment, the deep water engineering geological characteristics can be combined, and laboratory layered soil bodies with similarity can be prepared indoors. Based on the similarity principle, a feeding pipe column combination, a bottom drilling tool combination and the extension of a drill bit can be designed; the value range of each parameter is determined by the similarity mainly according to the technical experience of similar drilled wells, and the parameter value range can be widened in the experimental process. The lower end of the drill rod is provided with a drill bit, and the preset experimental conditions comprise: a predetermined weight-on-bit, a predetermined bit extension.

Specifically, when a simulation experiment is performed, a series of grouping experiments can be performed:

the extension of the drill bit in the design simulation experiment can be set as the extension sequence value of the drill bit, such as: m1, M2, … … Mn (unit: meter);

the run-in gravity (weight on bit) for the design simulation experiment can be set to the value of the weight on bit sequence, such as: g1, G2, … … Gn (unit: kN);

the run-in speed of the simulation experiment is designed, and the sequence value of the run-in speed can be as follows: v1, V2, … … Vn (unit: m/s).

In this embodiment, each parameter design is based on the well data or well engineering design of the same area. And (4) carrying out a series of grouping experiments subsequently, setting M, G, V parameters as fixed values respectively, and carrying out the evaluation of the running process of the deepwater conduit under the condition of researching different drill rod rotation speed parameters.

Generally, the drilling speed, the extension amount of a drill bit, the running-in gravity, the running-in speed and other parameters have complex nonlinear relations, and the parameters have multiple solutions due to the soil property. By the method for simulating the rotating speed of the drill rod in the process of running the deep water conduit into the deep water conduit, the optimal combination of all parameters under the soil body conditions with different properties can be obtained, particularly, the rotating speed of a motor in the jet running-in device is adjusted for multiple times according to an experimental design scheme under the condition that other parameters are fixed, so that the target rotating speed of the drill rod in the process of running the deep water conduit into the deep water conduit is optimized, the adaptability research and determination of the process of running the jet conduit into the deep water conduit are realized, and the drilling speed parameter of the drill rod is optimized. The actual deepwater conduit running-in process can be guided through the optimized drilling speed parameter of the drill rod, so that the running-in efficiency of jet running-in is improved, and safety accidents are reduced.

On the whole, the simulation method of the drill rod rotating speed in the deepwater guide pipe running-in process can perform indoor experimental evaluation on the drill rod rotating speed construction parameters in the deepwater guide pipe running-in process so as to research the complex linear correlation relationship between the seabed soil condition and the running pipe column process parameters, thereby obtaining reasonable drill rod rotating speed parameters, providing a basis for deepwater guide pipe jet running-in, finally realizing the improvement of drilling efficiency and saving expensive deepwater drilling cost.

Any numerical value recited herein includes all values from the lower value to the upper value that are incremented by one unit, provided that there is a separation of at least two units between any lower value and any higher value. For example, if it is stated that the number of a component or a value of a process variable (e.g., temperature, pressure, time, etc.) is from 1 to 90, preferably from 20 to 80, and more preferably from 30 to 70, it is intended that equivalents such as 15 to 85, 22 to 68, 43 to 51, 30 to 32 are also expressly enumerated in this specification. For values less than 1, one unit is suitably considered to be 0.0001, 0.001, 0.01, 0.1. These are only examples of what is intended to be explicitly recited, and all possible combinations of numerical values between the lowest value and the highest value that are explicitly recited in the specification in a similar manner are to be considered.

Unless otherwise indicated, all ranges include the endpoints and all numbers between the endpoints. The use of "about" or "approximately" with a range applies to both endpoints of the range. Thus, "about 20 to about 30" is intended to cover "about 20 to about 30", including at least the endpoints specified.

All articles and references disclosed, including patent applications and publications, are hereby incorporated by reference for all purposes. The term "consisting essentially of …" describing a combination shall include the identified element, ingredient, component or step as well as other elements, ingredients, components or steps that do not materially affect the basic novel characteristics of the combination. The use of the terms "comprising" or "including" to describe combinations of elements, components, or steps herein also contemplates embodiments that consist essentially of such elements, components, or steps. By using the term "may" herein, it is intended to indicate that any of the described attributes that "may" include are optional.

A plurality of elements, components, parts or steps can be provided by a single integrated element, component, part or step. Alternatively, a single integrated element, component, part or step may be divided into separate plural elements, components, parts or steps. The disclosure of "a" or "an" to describe an element, ingredient, component or step is not intended to foreclose other elements, ingredients, components or steps.

The above embodiments in the present specification are all described in a progressive manner, and the same and similar parts among the embodiments may be referred to each other, and each embodiment is described with emphasis on being different from other embodiments.

The above description is only a few embodiments of the present invention, and although the embodiments of the present invention are described above, the above description is only for the convenience of understanding the present invention, and is not intended to limit the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (8)

1. A system for evaluating the rotating speed of a drill rod in the process of running a deepwater conduit is characterized by comprising:

the device comprises an experiment frame, a soil box provided with a layered soil body, a jet running device, a jet pump, a multi-channel data collector, a controller, a displacement sensor, a pressure sensor and a tension sensor; wherein the content of the first and second substances,

the injection running-in device is provided with: a drilling assembly, the drilling assembly comprising: the drill pipe comprises a motor, a drill pipe, a liquid injection head and a guide pipe with a chamber extending along the longitudinal direction, wherein the motor is provided with a rotating shaft; the drill rod penetrates through the guide pipe, a drill bit is arranged at the lower end of the drill rod, and the upper end of the drill rod is connected with the rotating shaft; the liquid injection head is arranged at the upper end of the rotating shaft and is used for injecting liquid into the drill rod; a rotary sealing spherical head is arranged between the liquid injection head and the rotating shaft, the liquid injection head is fixedly connected with the rotary sealing spherical head, and the rotating shaft is rotatably connected with the rotary sealing spherical head;

the controller stores a target descending distance of the catheter; the controller is electrically connected with the multi-channel data acquisition unit;

the multi-channel data acquisition unit is electrically connected with the displacement sensor, the pressure sensor, the tension sensor and the jet pump,

and maintaining a preset experimental condition, adjusting the rotating speed of the drill rod by adjusting the rotating speed of the motor, sending a closing signal to the jet pump and the jet running-in device by the controller through the multi-channel data acquisition unit each time when the displacement signal detected by the displacement sensor indicates the running-in distance of the pipe running-in target, and selecting the target rotating speed of the drill rod in the running-in process of the deepwater pipe under the preset experimental condition by the controller according to the signals acquired by the sensors.

2. The system for evaluating the rotating speed of the drill rod during the running process of the deep water guide pipe as claimed in claim 1, wherein the pressure sensors are distributed optical fiber pressure sensors, and the pressure sensors are arranged along soil stress measuring points at equal intervals in the vertical direction and are arranged at equal intervals in the radial direction of the guide pipe.

3. The system for evaluating the rotational speed of a drill pipe during running of a deepwater conductor as claimed in claim 1, wherein the jet running device further comprises:

the gland is sleeved at the upper end of the guide pipe; a liquid discharge hole is formed in the gland and communicated with the cavity for discharging liquid in the cavity;

the drilling assembly further comprises:

and the balancing weight is positioned at the upper part of the liquid injection head and is used for adjusting the drilling pressure of the drill rod.

4. The system for evaluating the rotational speed of a drill pipe during running of a deep water conductor according to claim 3, further comprising an adjusting mechanism for adjusting the extent of extension of said drill bit with respect to the lower end of said conductor.

5. The system for evaluating the rotational speed of a drill pipe during running of a deepwater conduit as recited in claim 4, wherein the adjustment mechanism is disposed between the gland and the conduit.

6. The system for evaluating the rotation speed of the drill rod during the running process of the deepwater conduit as claimed in claim 5, wherein the adjusting mechanism is a matching mechanism of an adjusting bolt and a threaded hole, the press cover is formed with a first extending part extending along the longitudinal direction, the first extending part is sleeved on the upper end of the conduit, the first extending part is provided with a plurality of threaded holes distributed along the circumferential direction or the longitudinal direction, and the adjusting bolt can be arranged on the threaded holes in a penetrating way.

7. The system for evaluating the rotation speed of the drill rod during the running of the deep water conduit according to claim 6, wherein a second extension part is further arranged on the gland and positioned at the inner side of the first extension part, the first extension part and the second extension part form a concentric annular cavity, and the upper end of the conduit can be clamped into the concentric annular cavity formed by the first extension part and the second extension part.

8. The system for evaluating the rotation speed of the drill rod during the running of the deep water pipe as claimed in claim 3, wherein the motor is arranged on the gland, and the motor is an electric motor or a hydraulic motor.

Images