Model for estimating the medium cross-sectional area and the pressure surface of a deformed pipe section with wellbore walls

Authors

  • Ya. S. Grydzhuk Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska St., Ivano-Frankivsk, 76019
  • O. S. Kondur Vasyl Stefanyk Carpathian National University 57 Shevchenko Str., Ivano-Frankivsk, 76018, Ukraine
  • О. О. Slabyi Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska St., Ivano-Frankivsk, 76019
  • T. I. Kondur Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska St., Ivano-Frankivsk, 76019
  • I. Yu. Mokhniy Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska St., Ivano-Frankivsk, 76019

DOI:

https://doi.org/10.31471/1993-9868-2026-1(45)-72-91

Keywords:

drill string, borehole wall, contact area, mid-section, torus, cylinder, indentation, mathematical modelling, numerical methods.

Abstract

. This article addresses a relevant scientific and applied problem in oil and gas engineering: the development of mathematical tools for the precise determination of the geometric parameters of contact between the drill string and the borehole walls. During the construction of deep deviated and horizontal wells, the drill string, under the action of significant axial and bending loads, undergoes deformations that lead to its local embedding in the filter cake and rock formation. Traditional approaches, based on point contact modelling or approximate empirical relationships, do not allow for an adequate assessment of the adhesive forces and viscous resistance, which significantly influence energy consumption and the efficiency of axial force transmission to the bit. This paper proposes an innovative geometric model in which the local contact zone of the deflected section of the drill bit is identified as part of the surface of a torus cut out by a circular cylinder, which models the borehole. This approach allowed the complex curvature of both surfaces to be taken into account. Using methods of parameterisation and analysis of singular points, the authors established analytical relationships for determining the coordinates of the intersection boundary and formulated integral equations for calculating the area of the contact surface and the area of the mid-section. Since the obtained integrals are not expressed in elementary functions, the Simpson numerical method was applied to solve them, implemented in Python and Maple code. Numerical modelling carried out for various pipe sections of coiled tubing (CT), drill pipe (DP) and weighted drill pipe (WDP) sections revealed important patterns: it was established that the contact area exceeds the area of the mid-section cross-section by 2–3 orders of magnitude. It has been demonstrated that as the insertion depth increases fivefold, the cross-sectional area increases by approximately ninefold, indicating a critical increase in hydrodynamic resistance. For cases of small deformations, the authors have proposed simplified parabolic formulas, which facilitate practical engineering calculations. The results of the study form the basis for improving methods for calculating the total drag forces on the drill string and for designing wellbore profiles with large zenith angles, thereby minimising the risk of tool snagging.

Downloads

Download data is not yet available.

References

1. Chudyk I. I., Yurych A. R., Kozlov A. A. Vrakhuvannia kaverno- i zholoboutvorennia pry proektuvanni neoriientovanykh KNBK. Rozvidka ta rozrobka naftovykh i hazovykh rodovyshch. 2007. No 2 (23). Р. 45–50.

2. Chudyk I. I. Uzahalnena metodyka rozrakhunku enerhetychnykh vytrat pry roboti neoriientovanykh komponovok nyzu burylnoi kolony dlia rotornoho sposobu burinnia. Naukovyi visnyk IFNTUNH. 2013. № 2 (35). P. 121–128.

3. Chudyk I. I., Riznychuk A. I. Doslidzhennia peredumov zholoboutvorennia na stinkakh sverdlovyny zamkamy burylnoi kolony. Rozvidka ta rozrobka naftovykh i hazovykh rodovyshch. 2014. No 2 (51). Р. 80–87.

4. Analytical estimation of inertial properties of the curved rotating section in a drill string / Ja. Grydzhuk, I. Chudyk, A. Velychkovych, A. Andrusyak. Eastern-European Journal of Enterprise Technologies. 2019. Vol. 1, No 7 (97). P. 6–14. DOI: https://doi.org/10.15587/1729-4061.2019.154827

5. Volpi L. P., Cayeux E., Time R. W. Whirling dynamics of a drill-string with fluid–structure interaction. Geoenergy Science and Engineering. 2024. Vol. 232. Art. 212423. https://doi.org/10.1016/j.geoen.2023.212423

6. Fluid–Structure Interaction Study in Unconventional Energy Horizontal Wells Driven by Recursive Algorithm and MPS Method / X. Gao, D. Zhao, Y. Zhang, Y. Chen, Z. Gao, X. Zhang, S. Wang. Applied Sciences. 2025. Vol. 15, No 12. Art. 6743. https://doi.org/10.3390/app15126743

7. Research on friction characteristics of drill string in whole well section of gas drilling based on finite element method / Dianchen Liu, Xiao Huang, Ke Deng, Pan Fang, Hai Yan, Chengxiao Li, Ketao Cai. Journal of Vibroengineering. 2025. Vol. 27, issue 3. P. 567–581. https://doi.org/10.21595/jve.2025.24519

8. Research on the dynamic behavior of flexible drilling tools in ultrashort-radius radial horizontal wells / Z. Lin, M. Luo, J. Wang, T. Xiu, Q. Li. Scientific Reports. 2024. Vol. 14. Art. 7230. https://doi.org/10.1038/s41598-024-57742-3

9. Mechanism of wellbore instability considering tubular-string contact with the wellbore wall / Y. Zhou, H. Zhang, Y. Wu, X. Li, C. Xi, K. Lv, H. Zhang, X. Wang. Scientific Reports. 2025. Vol. 15. Art. 26375. https://doi.org/10.1038/s41598-025-10714-7

10. Rovenski V. Modeling of Curves and Surfaces with MATLAB®. New York : Springer, 2010. 459 p. (Springer Undergraduate Texts in Mathematics and Technology). http://doi.org/10.1007/978-0-387-71278-9

11. Surface to Surface Intersections / N. M. Patrikalakis, T. Maekawa, K. H. Ko, H. Mukundan. Shape Interrogation for Computer Aided Design and Manufacturing. 2004. P. 449–458. https://doi.org/10.1080/16864360.2004.10738287

12. Shapochka A. I., Mitsa O. V. Kompiuterne modeliuvannia peretyniv kvadratychnykh poverkhon. Innovatsiina nauka: poshuk vidpovidei na vyklyky suchasnosti: materialy mizhnar. nauk.-prakt. konf. (Mohyliv-Podilskyi, 6 hrud. 2024 r.). Mohyliv-Podilskyi: MTsND, 2024. S. 219–224. https://doi.org/10.62731/mcnd-06.12.2024.003

13. Breda A., Trocado A., Dos Santos J. Topological Properties of the Intersection Curves Between a Torus and Families of Parabolic or Elliptical Cylinders. Axioms. 2024. Vol. 13, no. 12. Art. 852. https://doi.org/10.3390/axioms13120852

14. Pro analitychne vyznachennia ploshchi zony kontaktuvannia prohnutnoi dilianky burylnoi kolony iz stinkoiu sverdlovyny / Ya. S. Hrydzhuk ta in. Perspektyvy rozvytku mashynobuduvannia ta transportu – 2023: materialy III Mizhnar. nauk.-tekhn. konf. (m. Vinnytsia, 1–3 cherv. 2023 r.). Vinnytsia: VNTU, 2023. S. 63–65. URL: https://conferences.vntu.edu.ua/index.php/prmt/pmrt2023/paper/viewFile/18357/15173 (data zvernennia: 06.05.2024).

15. Handbook of Computer Aided Geometric Design / ed. by G. Farin, J. Hoschek, M.-S. Kim. Amsterdam: North-Holland, 2002. 825 p. DOI: https://doi.org/10.1016/B978-0-444-51104-1.X5000-X

Downloads

Published

28.05.2026

How to Cite

Grydzhuk, Y. S., Kondur, O. S., Slabyi О. О., Kondur, T. I., & Mokhniy, I. Y. (2026). Model for estimating the medium cross-sectional area and the pressure surface of a deformed pipe section with wellbore walls. Oil and Gas Power Engineering, (1(45), 72–91. https://doi.org/10.31471/1993-9868-2026-1(45)-72-91

Issue

No. 1(45) (2026): Oil and Gas Power Engineering

Section

SCIENTIFIC AND TECHNICAL PROBLEMS OF PETROLEUM ENGINEERING

License

Copyright (c) 2026 Oil and Gas Power Engineering

Creative Commons License

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Similar Articles

1 2 3 4 5 6 7 8 9 10 > >> 

You may also start an advanced similarity search for this article.