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The function of breaking deformations within the rock mass in the bottomhole of a hydromechanical drilling well is dependent on various technological means and methods. A sequential analysis has been conducted to identify the most influential factors in this process. Positive features of hydromechanical drilling have been outlined from the viewpoint of effective intensification of basic technical and economic parameters of the process of well construction with different purposes. Complete operational similarity and technological interconnection of a mechanism of the formation of different parts of a hydromechanical drilling well have been shown in terms of their stipulation by the properties of rock formations and mode support of a well construction process. Top-priority of a hydromechanical drilling type has been proved to generate as many parameters of dynamic effect on rock mass, which results in the increasing scope of bottomhole breaking processes. Attention has been paid to the study of the problem of tool support for drilling operations from the viewpoint of tracing the nature of bottomhole processes running in terms of different technical and technological factors. The possibility and necessity of using surface-active substances (SAS) as the main activators of positive deformation interactions in the “metal pellets – rock” pair have been proved and substantiated; use will be based on the developed methodological approaches of rational selection of a component-concentration composition of a breaking medium. Originality. The efficiency of a hydromechanical drilling type is stipulated by the degree of dynamic effect on the rock bottomhole; depending on its geological-mineralogical and physicomechanical features, it can be intensified by increasing frequency of impacting, interpretation of the effecting mechanism, variation of the cleaning agent type as well as directed activation of the manifestation of surface and interphase interactions. Practical implications. The represented results of analytical and laboratory-experimental studies are the basis for the development of methodological foundations to elaborate the mode parameters of the technology of hydromechanical drilling for the construction of wells. They belong to the basic initial data applied while developing the design and working characteristics of the corresponding modernised operating members.
Wydawca
Czasopismo
Rocznik
Tom
Strony
285--299
Opis fizyczny
Bibliogr. 27 poz., fot., tab., wykr.
Twórcy
autor
- Dnipro University of Technology, Ukraine
autor
- Al-Balqa Applied University, Jordan
autor
- Dnipro University of Technology, Ukraine
autor
- Dnipro University of Technology, Ukraine
autor
- Dnipro University of Technology, Ukraine
autor
- Dnipro University of Technology, Ukraine
Bibliografia
- [1] M.A. Myslyuk, I.Y. Rybchych, R.S. Yaremiychuk, Drilling Wells: Handbook: in 5 volumes, Volume 1: General Information. Drilling Installations. Equipment and Tools, Interpress LTD, Kyiv (2002).
- [2] J.C. Lopez, J.E. Lopez, F. Javier, Drilling and Blasting of Rocks, CRC Press Taylor & Francis (2017).
- [3] Ye. Koroviaka, J. Pinka, S. Tymchenko, V. Rastsvietaiev, V. Astakhov, O. Dmytruk, Elaborating a Scheme for Mine Methane Capturing While Developing Coal Gas Seams. Mining of Mineral Deposits 14 (3), 21-27 (2020). DOI: https://doi.org/10.33271/mining14.03.021.
- [4] M.E. Hossain, M.R. Islam, Drilling engineering: Problems and Solutions, Scrivener Publishing (2018).
- [5] A. Ighnatov, Research into Parameters Characterizing the Process of Withdrawing Clay-Mud Formations from Bore Hole Vuggy Zones. Mining of Mineral Deposit 10 (1), 63-68 (2016). DOI: https://doi.org/10.15407/mining10.01.063.
- [6] A. Ihnatov, Y. Koroviaka, V. Rastsvietaiev, L. Tokar, Development of the rational bottomhole assemblies of the directed well drilling. Gas Hydrate Technologies: Global Trends, Challenges and Horizons – 2020, E3S Web of Conferences. 230, 01016 (2021). DOI: https://doi.org/10.1051/e3sconf/202123001016.
- [7] A.O. Ihnatov, Conformities to Law Work of Backwall Device are at Application of Coiled Tubing. Tooling Materials Science 22, 126-133 (2019). DOI: https://doi.org/10.33839/2223-3938-2019-22-1.
- [8] Z.X. Zhang, Rock Fracture and Blasting. Theory and Applications. Elsevier Inc. Publishing (2016).
- [9] M. Dudlya, V. Sirik, V. Rastsvetaev, T. Morozova, Rotary Drilling System Efficiency Reserve. Progressive Technologies of Coal, Coalbed Methane, and Ores Mining 123-130 (2014). DOI: https://doi.org/10.1201/b17547.
- [10] L.R. Yurych, PhD thesis, Improving the Technology of Drilling Wells Taking into Account the State of the Rock Destruction Tool, Ivano-Frankivsk National Technical University of Oil and Gas, Ivano-Frankivsk, Ukraine (2021).
- [11] M.E. Hossain, A.A. Al-Majed, Fundamentals of Sustainable Drilling Engineering, Scrivener Publishing (2015).
- [12] N. Vaddadi, Introduction to oil well drilling, Bathos publishing (2015).
- [13] Carlson Diane, Plummer (Carlos) Charles, Physical Geology Earth Revealed 9th Edition, McGraw-Hill Education (2020).
- [14] S.G. Robello, L. Xiushan, Advanced Drilling Engineering, Gulf Publishing Company (2009).
- [15] A.A. Ihnatov, To the Question of Determining Bottom-Hole Performance Characteristics of Hydromechanics Drilling Devices. Tooling Materials Science 23, 78-88 (2020). DOI: https://doi.org/10.33839/2708-731X-2020-23-1.
- [16] V. Moisyshyn, B. Borysevych, R. Sheherbiy, Mulifactorial Mathematical Model of Mechanical Drilling Speed. Mining of Mineral Deposits. A Balcema Book 359-368 (2013). DOI: https://doi.org/10.1201/b16354.
- [17] М.А. Mysliuk, Modeling Technological Decision-Making in Drilling. Oil and Gas Industry 3, 11-15 (2010).
- [18] G.L. Curry, R.M. Feldman, Manufacturing Systems. Modeling and Analysis, Springer (2012).
- [19] S. Datta, J.P. Davim, Optimization in Industry. Springer (2019).
- [20] J.G. Speight Formulas and Calculations for Drilling Operations. Scrivener Publishing (2018).
- [21] A. Ihnatov, S. Viatkin, Impact Drill for Well Drilling. UA Patent No. 102707 (2013). https://base.uipv.org/searchINV/search.php?action=viewdetails&IdClaim=189994.
- [22] A. Davidenko, A. Ihnatov, Abrasive-Mechanical Shock Drilling of Wells. National Mining University, Dnipropetrovsk (2013).
- [23] A.O. Ihnatov, Ye.A. Koroviaka, Jan Pinka, V.O. Rastsvietaiev, O.O. Dmytruk, Geological and Mining-Engineering Peculiarities of Implementation of Hydromechanical Drilling Principles. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu 1, 11-18 (2021). DOI: https://doi.org/10.33271/nvngu/20211/011.
- [24] K.S. Birdi, Surface and Colloid Chemistry Principles and Applications. Published CRC Press (2020).
- [25] K.K. Sharma, L.K. Sharma, Physical Chemistry. Vikas Publishing (2016).
- [26] A. Bahl, B.S. Bahl, G.D. Tuli, Essentials of Physical Chemistry, 28/e. S. Chand Publishing (2020).
- [27] M. Dudlia, J. Pinka, K. Dudlia, V. Rastsvietaiev, M. Sidorova, Influence of Dispersed Systems on Exploratory Well Drilling. Solid State Phenomena 277, 44-53 (2018). DOI: https://doi.org/10.4028/www.scientific.net/SSP.277.44.
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Bibliografia
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bwmeta1.element.baztech-ee2d1b35-9b8e-4dc6-bca1-8171347dff50