Sage Journals: Discover world-class research

Abstract

At present, the traction force and traction speed of the drilling robot cannot be controlled. However, if the speed of the drilling robot is too high, the bit will be damaged because of the shock load. If the speed of the drilling robot is too low, the drilling efficiency will be very low. The existing control system and control algorithm of the drilling robot cannot meet the requirements of the drilling conditions. A control system of the weight on bit and the rate of penetration of the drilling robot was invented. On the basis, a dual-loop fuzzy proportional integral derivative (PID) control algorithm of the pressure difference and flow rate was proposed to control the weight on bit and rate of penetration. Furthermore, the simulation model of the dual-loop fuzzy PID control algorithm was established. It is found that the proposed dual-loop fuzzy PID control algorithm has the characteristics of small overshoot and good tracking. Furthermore, the correctness of the theory was verified by the experiments. The experiments show that the average amplitude of rate of penetration vibration by using adaptive PID controller is less than 50% of that of PID controller. The maximum weight on bit with the adaptive PID controller is only 45.94% of that of the conventional PID controller. The overshoot of the adaptive PID controller is only 24.07% of that of the conventional PID controller. At the same time, the vibration amplitude of the conventional PID controller is obviously larger than that of the adaptive PID controller. The proposed adaptive PID controller in this paper can effectively reduce the vibration of the bit. By reducing the vibration of the bit, the life of the bit can be extended. Finally, it is of great significance to realize the efficient and intelligent drilling process.

Keywords

dual-loop fuzzy PID control algorithm drilling robot coiled tubing drilling

Get full access to this article

View all access options for this article.

References

Majid

Corredor

FER

Kuru

. Quantitative evaluation of critical conditions required for effective hole cleaning in coiled-tubing drilling of horizontal wells. SPE Drill Complet 2016; 31: 188–199.

Shao

. Horizontal well production testing technology. Oil Gas Well Test 2007; 25: 73–74.

Livescu

Craig

. Critical review of the coiled tubing friction-reducing technologies in extended-reach wells. Part 1: lubricants. J Petrol Sci Eng 2017; 157: 747–759.

McAllister

Hawkins

, et al. Application of downhole tractor in gas well zonal isolation. In: SPE/ICoTA well intervention conference and exhibition. The Woodlands, Texas, USA, March 2020. https://doi.org/10.2118/199830-MS.

Hallundbaek

Knut

Haukvik

, et al. Wireline well tractor: case histories. In: Offshore technology conference. Houston, Texas, May 1997. https://doi.org/10.4043/8535-MS.

Liu

Zhao

Zhu

, et al. Review, classification and structural analysis of downhole robots: core technology and prospects for application. Rob Auton Syst 2019; 115: 104–120.

Frans

Cuauro

Chalco

, et al. Tractor production logging in long cased horizontal wells; operational experience from the Al Shaheen Field, Offshore Qatar. In: International petroleum technology conference. Kuala Lumpur, Malaysia, December 2014. https://doi.org/10.2523/IPTC-18015-MS.

Liu Q

Yang

et al.

. Design of two-way locking mechanism of telescopic downhole tractor. J Southwest Petro Univ 2018; 40: 1–10.

Zhang

Zhao

Gao

. Design of differential cable tractor for horizontal wells. Oil Field Equipment 2012; 41: 45–49.

10.

Shaydakov VV, Lyagov AV and Zinatullina EY et al. Coiled tubing drilling of lateral wellbore. Construction of Oil and Gas Wells Onshore Sea 2018; 8: 1–25.

11.

Zhao

Han

Liu

, et al. Combined control mechanism of WOB and ROP with downhole robot in coiled tubing drilling process. SPE J 2021; 27: 153–166.

12.

Liu

Zhao

Zhu

, et al. Mechanical model of drilling robot driven by the differential pressure of drilling fluid. Arab J Sci Eng 2019; 44: 1447–1458.

13.

Fang

Shang

Yang

, et al. An energy efficient two-stage supply pressure hydraulic system for the downhole traction robot. Math Probl Eng 2018; 9: 1–9.

14.

Bllom

Moore

Levay

. Tractor with improved valve system. Patent 7607495, 2007, USA.

15.

Mock

Krueger

Bloom

, et al. Tractor with improved valve system. Patent 7493967, 2009, USA.

16.

Prasannavenkadesan

Pandithevan

. Mechanistic models to predict thrust force and torque in bone drilling: an in-vitro study validated with robot-assisted surgical drilling parameters. Proc Inst Mech Eng E: J Process Mech Eng 2021; 235: 1984–1997.

17.

Amir Hasani

Norouzi

Larimi

, et al. Computational study on drilling mud flow through wellbore annulus by giesekus viscoelastic model. Proc Inst Mech Eng E: J Process Mech Eng 2021; 235: 66–79.

18.

Chatterjee

Mahapatra

Abhishek

. Simulation and optimization of machining parameters in drilling of titanium alloys. Simul Model Pract Theory 2016; 62: 31–48.

19.

Chatterjee

Mahapatra

Bharadwaj

, et al. Drilling of micro-holes on titanium alloy using pulsed Nd:YAG laser: parametric appraisal and prediction of performance characteristics. Proc Inst Mech Eng B: J Eng Manuf 2019; 233: 1872–1889.

20.

Chatterjee

Mahapatra

Bharadwaj

, et al. Prediction of quality characteristics of laser drilled holes using artificial intelligence techniques. Eng Comput 2021; 37: 1181–1204.

21.

Zhao

Liu

Zhu

. Nonlinear dynamic model and characteristization of coiled tubing drilling system based on drilling robot. J Vib Eng Technol 2021; 9: 541–561.

22.

Veiga

Suárez

Val

AGD

, et al. Evaluation on advantages of low frequency assisted drilling (LAFD) aluminium alloy Al7075. Int J Mechatron Manuf Syst 2020; 13: 230.

23.

Arizmendi

Fernández

Gil

, et al. Identification of tool parallel axis offset through the analysis of the topography of surfaces machined by peripheral milling. Int J Mach Tools Manuf 2010; 50: 1097–1114.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

1.99 MB

Control algorithm of weight on bit and rate of penetration based on drilling robot

Abstract

Keywords

Get full access to this article

References

Supplementary Material