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Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells. / Lyhin, P. A.; Toropetsky, K. V.; Ulyanov, V. N. et al.

In: Mathematical Models and Computer Simulations, Vol. 11, No. 5, 01.09.2019, p. 704-714.

Research output: Contribution to journalArticlepeer-review

Harvard

Lyhin, PA, Toropetsky, KV, Ulyanov, VN, Usov, EV & Chuhno, VI 2019, 'Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells', Mathematical Models and Computer Simulations, vol. 11, no. 5, pp. 704-714. https://doi.org/10.1134/S2070048219050119

APA

Lyhin, P. A., Toropetsky, K. V., Ulyanov, V. N., Usov, E. V., & Chuhno, V. I. (2019). Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells. Mathematical Models and Computer Simulations, 11(5), 704-714. https://doi.org/10.1134/S2070048219050119

Vancouver

Lyhin PA, Toropetsky KV, Ulyanov VN, Usov EV, Chuhno VI. Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells. Mathematical Models and Computer Simulations. 2019 Sept 1;11(5):704-714. doi: 10.1134/S2070048219050119

Author

Lyhin, P. A. ; Toropetsky, K. V. ; Ulyanov, V. N. et al. / Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells. In: Mathematical Models and Computer Simulations. 2019 ; Vol. 11, No. 5. pp. 704-714.

BibTeX

@article{15592f7e22a747ada2f1d5b40f76df65,
title = "Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells",
abstract = "Abstract: A transient mathematical model for modeling the transport of cuttings in the drilling mudflow during drilling horizontal and directional wells is presented. The model is based on a two-layer model that takes into account the cuttings in the fluid flow and the motionless cutting substrate. The relationships for calculating the mass exchange between the substrate and the cuttings in the flow, the friction and heat transfer between the cuttings and the fluid flow, as well as the heat transfer between the fluid and the substrate with the annulus. Options for simulating Newtonian and non-Newtonian fluid motion are implemented. It is assumed that the fluid moves in the annular channel formed by the well wall and the drill string. The presence of eccentricity in the channel is taken into account. To simulate the motion and heat transfer, a system of mass, momentum, and energy equations is solved for each component separately. The numerical implementation is based on the finite volume method, the convective terms are written in the counterflow form. The results of the test calculations demonstrating the efficiency of the model proposed are presented. The problem on the displacement of cuttings from an arbitrarily oriented well is considered.",
keywords = "cuttings, fluid, multicomponent model, simulation, well",
author = "Lyhin, {P. A.} and Toropetsky, {K. V.} and Ulyanov, {V. N.} and Usov, {E. V.} and Chuhno, {V. I.}",
year = "2019",
month = sep,
day = "1",
doi = "10.1134/S2070048219050119",
language = "English",
volume = "11",
pages = "704--714",
journal = "Mathematical Models and Computer Simulations",
issn = "2070-0482",
publisher = "Springer Science + Business Media",
number = "5",

}

RIS

TY - JOUR

T1 - Transient Thermal-Nonequilibrium Model for Predicting the Removal of Cuttings when Drilling Directional Wells

AU - Lyhin, P. A.

AU - Toropetsky, K. V.

AU - Ulyanov, V. N.

AU - Usov, E. V.

AU - Chuhno, V. I.

PY - 2019/9/1

Y1 - 2019/9/1

N2 - Abstract: A transient mathematical model for modeling the transport of cuttings in the drilling mudflow during drilling horizontal and directional wells is presented. The model is based on a two-layer model that takes into account the cuttings in the fluid flow and the motionless cutting substrate. The relationships for calculating the mass exchange between the substrate and the cuttings in the flow, the friction and heat transfer between the cuttings and the fluid flow, as well as the heat transfer between the fluid and the substrate with the annulus. Options for simulating Newtonian and non-Newtonian fluid motion are implemented. It is assumed that the fluid moves in the annular channel formed by the well wall and the drill string. The presence of eccentricity in the channel is taken into account. To simulate the motion and heat transfer, a system of mass, momentum, and energy equations is solved for each component separately. The numerical implementation is based on the finite volume method, the convective terms are written in the counterflow form. The results of the test calculations demonstrating the efficiency of the model proposed are presented. The problem on the displacement of cuttings from an arbitrarily oriented well is considered.

AB - Abstract: A transient mathematical model for modeling the transport of cuttings in the drilling mudflow during drilling horizontal and directional wells is presented. The model is based on a two-layer model that takes into account the cuttings in the fluid flow and the motionless cutting substrate. The relationships for calculating the mass exchange between the substrate and the cuttings in the flow, the friction and heat transfer between the cuttings and the fluid flow, as well as the heat transfer between the fluid and the substrate with the annulus. Options for simulating Newtonian and non-Newtonian fluid motion are implemented. It is assumed that the fluid moves in the annular channel formed by the well wall and the drill string. The presence of eccentricity in the channel is taken into account. To simulate the motion and heat transfer, a system of mass, momentum, and energy equations is solved for each component separately. The numerical implementation is based on the finite volume method, the convective terms are written in the counterflow form. The results of the test calculations demonstrating the efficiency of the model proposed are presented. The problem on the displacement of cuttings from an arbitrarily oriented well is considered.

KW - cuttings

KW - fluid

KW - multicomponent model

KW - simulation

KW - well

UR - http://www.scopus.com/inward/record.url?scp=85073193311&partnerID=8YFLogxK

U2 - 10.1134/S2070048219050119

DO - 10.1134/S2070048219050119

M3 - Article

AN - SCOPUS:85073193311

VL - 11

SP - 704

EP - 714

JO - Mathematical Models and Computer Simulations

JF - Mathematical Models and Computer Simulations

SN - 2070-0482

IS - 5

ER -

ID: 21860562