Experimental research on the thermal method of drilling by melting the well in ice mass with simultaneous controlled expansion of its diameter

Сербин, Д В; Дмитриев, А. Н.

doi:10.31897/pmi.2022.82

Cited by 7 publications

(4 citation statements)

References 18 publications

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“…The results of comparison between the model and real data showed that presented model calculates the heat transfer coefficient with an error margin of 20%, 30%, and 25% for bubble, annular, and slug flows, respectively. Furthermore, the integration of permafrost attributes such as the latent heat of fusion (17), alongside considerations of permafrost thawing, the migration of water from proximal zones around the well to more remote areas, and the temperature gradient, has facilitated the introduction of a novel thermal model for a producing well by the authors (18). Field tests of the model showed high convergence of the calculation results with real data.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Nucleation Time of Gas Hydrates in Presence of Paraffin During Mechanized Oil Production

Korobov,

Vorontsov,

Buslaev

et al. 2024

IJE

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The objective of this study is to investigate the nucleation timing of gas hydrate molecules in oil flows. This research focuses on examining how paraffin particles impact the formation timing of hydrate deposits during the mechanical production of oil. A thorough comprehension and control over the formation of organic deposits within the wellbore can substantially mitigate equipment maintenance expenses, enhance the safety and consistency of production, and bolster the economic viability of extracting hydrocarbons. The initial segment of the paper outlines a methodology for identifying the formation depths of gas hydrates and asphaltene-resin-paraffin deposits (ARPD) in operational oil wells through the resolution of thermobaric differential equation systems. Subsequent laboratory experiments were conducted to assess the nucleation timing of gas hydrates in the presence of paraffin. These tests were performed in a specialized high-pressure autoclave that enables the establishment of requisite thermobaric conditions. An internal agitator in the autoclave facilitates the needed dispersion within the system to emulate well flow conditions. Experimental findings revealed that paraffin particles impede the formation of gas hydrate deposits and decelerate their nucleation process. Notably, a 3% increase in paraffin concentration within the mixture was observed to prolong the nucleation timing of gas hydrates by a factor of nine. Based on the review of available literature, it is deduced that further comprehensive investigations are essential for the advancement of a temporal model governing the operational dynamics of production wells under the influence of gas hydrate and ARPD formation.

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Section: Introductionmentioning

confidence: 99%

Analysis of Nucleation Time of Gas Hydrates in Presence of Paraffin During Mechanized Oil Production

Korobov,

Vorontsov,

Buslaev

et al. 2024

IJE

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“…In addition, it is difficult to manually carry out a planned and uniform bit feed using the winch brake device. Errors in the values of the WOB and ROP, and the uneven supply of drilling tools, can lead to emergencies, complications, and a decrease in the qualitative and quantitative indicators of drilling [3,4].…”

Section: Introductionmentioning

confidence: 99%

“…The results also showed that for the most efficient operation of the hydraulic thrusting device, an accurate selection of drilling fluid density and piston diameter is necessary. Scientists recommend using a piston with a diameter of 125 mm and a length of 1000 mm at a fluid density of 1000-1500 kg/m 3 and to use a piston with a diameter of 155 mm and a length of 1600 mm at a fluid density of 1500-2300 kg/m 3 .…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Nonlinear Processes in the “Thruster—Downhole Motor—Bit” System While Extended Reach Well Drilling

et al. 2023

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The relevance of the application of hydraulic thruster technology is determined by the technological limitations of drilling both vertical and horizontal wells. The existing experimental studies confirm the effectiveness of the technology, but its widespread implementation is hindered by the lack of scientific foundations for its operation in combination with a downhole motor and bit. Our research methodology includes methods for analyzing scientific and technical information as well as methods of numerical modeling using programming languages and ready-made software packages for CFD calculations. Verification of the simulation results was carried out on the basis of the experimental field studies previously conducted with the participation of the authors of the article. This article presents the results of the analysis of the current state of the problem and computer physical and mathematical modeling of the work of the thruster together with the bit and downhole motor when drilling a deviated section of a well. Based on the simulation results, the expediency of using hydraulic thrusters in the practice of drilling wells with the possibility of predicting and operatively regulating the operation parameters of the “Hydraulic Thrusting Device—Downhole Motor—Bit” system is theoretically substantiated and scientifically confirmed.

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“…Russia plays one of the leading roles in ensuring the supply of energy resources to world markets, with permafrost occupying about 65% of the country's territory and a significant part of mineral deposits concentrated in the Russian Arctic [6][7][8]. The integrated development of the Arctic is not an easy task in terms of maintaining the sustainability of infrastructure and the energy costs of economic activity [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Thermal Stabilization of Permafrost Using Thermal Coils Inside Foundation Piles

2023

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The article deals with the issue of thermal stabilization of soils to preserve the stability of pile foundations in permafrost conditions. The purpose of the work is to develop a technology for year-round freezing of soils by supplying coolant cooled by a refrigeration machine to thermal elements placed inside piles. In this work, the temperature regime of the system "pile foundation – soil" in the stationary formulation of the problem was simulated, and the influence of the depth of placement of thermal elements inside the piles on the soil temperature was investigated. The simulation was performed in the COMSOL software environment, taking into account the heat transfer due to thermal conduction and convection. In the presented model, a platform is fixed on piles, and a heat source is placed on the platform. It is found that an area of thawed soil has formed on the leeward side of the pile foundation. It is concluded that, under certain conditions, deep thermal elements for freezing or keeping the soil frozen should be placed at different depths. Thus, under given conditions, a greater depth of the thermal element placement in the pile, closest to the soil thawing zone, allows to reduce the surface temperature of the pile below ground level and, therefore, increase its bearing capacity. The authors also propose an original unit for soil thermostabilization based on the absorption cooling machine, which can operate at the expense of thermal energy generated by technological sources located on the platform. Doi: 10.28991/CEJ-2023-09-04-013 Full Text: PDF

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Experimental research on the thermal method of drilling by melting the well in ice mass with simultaneous controlled expansion of its diameter

Cited by 7 publications

References 18 publications

Analysis of Nucleation Time of Gas Hydrates in Presence of Paraffin During Mechanized Oil Production

Analysis of Nucleation Time of Gas Hydrates in Presence of Paraffin During Mechanized Oil Production

Numerical Simulation of Nonlinear Processes in the “Thruster—Downhole Motor—Bit” System While Extended Reach Well Drilling

Thermal Stabilization of Permafrost Using Thermal Coils Inside Foundation Piles

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