Identifying the operating features of a device for creating implosion impact on the water bearing formation

Authors

DOI:

https://doi.org/10.15587/1729-4061.2023.287447

Keywords:

well development, implosion impact, casing string collapse, inlet valve, Tonirekshin field

Abstract

The object of the study reported in this paper is the parameters of a device for implosion impact on aquifers during well development.

The problem of increasing the productivity of aquifers was solved by removing colmatation products formed during the drilling process and restoring the natural permeability of the formations. This could ensure high production of wells and their long-term trouble-free operation. One of the most effective ways to develop wells is implosion impact. However, its use is hampered by the complexity of the structure of existing devices, the high cost of use, and the insufficient reliability of their operation. To overcome this, an original device for implosion impact on aquifers was designed and its operating parameters were determined.

A procedure has been devised for determining the maximum permissible sizes of intervals not filled with liquid under the conditions of preventing casing string collapse. The effect of these intervals on reducing the total weight of the casing string was investigated.

An optimal well structure was proposed for the conditions of the Tonirekshin field. The critical dimensions of empty intervals were calculated for all wall thicknesses of casing pipes included in the well design. It has been established that the amount of weight reduction of the casing string in the well due to the Archimedean force for field conditions is 43–47 %. Archimedean force increases with increasing pipe wall thickness. Reducing the weight of the casing string reduces the required winch power, allowing the use of lighter drilling rigs.

The procedure for preparing for repeated implosion impacts has been studied.

The studies performed and the recommendations presented will be effective when drilling and developing wells under the conditions of the Mangistau Peninsula, at the Tonirekshin field.

Author Biographies

Boranbay Ratov, Satbayev University

Doctor of Technical Sciences, Professor, Head of Department

Department of Geophysics

Ardak Borash, Yessenov University

PhD Student

Department Ecology and Geology

Marian Biletskiy, Satbayev University

PhD, Associate Professor

Department of Geophysics

Volodymyr Khomenko, Dnipro University of Technology

PhD, Associate Professor

Department Oil and Gas Engineering and Drilling

Yevhenii Koroviaka, Dnipro University of Technology

PhD, Associate Professor, Head of Department

Department Oil and Gas Engineering and Drilling

Aigul Gusmanova, Yessenov University

PhD, Associate Professor, Dean

Oleksandr Pashchenko, Dnipro University of Technology

PhD, Associate Professor

Department Oil and Gas Engineering and Drilling

Valerii Rastsvietaiev, Dnipro University of Technology

PhD, Associate Professor

Department Oil and Gas Engineering and Drilling

Oleksandr Matуash, National University «Yuri Kondratyuk Poltava Polytechnic»

PhD, Associate Professor

Department of Drilling and Geology

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Identifying the operating features of a device for creating implosion impact on the water bearing formation

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Published

2023-10-31

How to Cite

Ratov, B., Borash, A., Biletskiy, M., Khomenko, V., Koroviaka, Y., Gusmanova, A., Pashchenko, O., Rastsvietaiev, V., & Matуash O. (2023). Identifying the operating features of a device for creating implosion impact on the water bearing formation. Eastern-European Journal of Enterprise Technologies, 5(1 (125), 35–44. https://doi.org/10.15587/1729-4061.2023.287447

Issue

Vol. 5 No. 1 (125) (2023): Engineering technological systems

Section

Engineering technological systems

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Copyright (c) 2023 Boranbay Ratov, Ardak Borash, Marian Biletskiy, Volodymyr Khomenko, Yevhenii Koroviaka, Aigul Gusmanova, Oleksandr Pashchenko, Valerii Rastsvietaiev, Oleksandr Matуash

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