Theoretical and experimental fundamentals of designing promising technological equipment to improve efficiency and environmental safety of highly viscous oil recovery from deep oil reservoirs
- Authors: Moiseyev V.A.1, Nazarov V.P.2, Zhuravlev V.Y.2, Zhuykov D.A.2, Kubrikov M.V.2, Klokotov Y.N.1
-
Affiliations:
- ZAO KOMPOMASH-TEK
- Siberian State Aerospace University
- Issue: Vol 52, No 7 (2016)
- Pages: 753-759
- Section: Article
- URL: https://journals.rcsi.science/0001-4338/article/view/148478
- DOI: https://doi.org/10.1134/S0001433816070033
- ID: 148478
Cite item
Abstract
The development of new technological equipment for the implementation of highly effective methods of recovering highly viscous oil from deep reservoirs is an important scientific and technical challenge. Thermal recovery methods are promising approaches to solving the problem. It is necessary to carry out theoretical and experimental research aimed at developing oil-well tubing (OWT) with composite heatinsulating coatings on the basis of basalt and glass fibers. We used the method of finite element analysis in Nastran software, which implements complex scientific and engineering calculations, including the calculation of the stress-strain state of mechanical systems, the solution of problems of heat transfer, the study of nonlinear static, the dynamic transient analysis of frequency characteristics, etc. As a result, we obtained a mathematical model of thermal conductivity which describes the steady-state temperature and changes in the fibrous highly porous material with the heat loss by Stefan–Boltzmann’s radiation. It has been performed for the first time using the method of computer modeling in Nastran software environments. The results give grounds for further implementation of the real design of the OWT when implementing thermal methods for increasing the rates of oil production and mitigating environmental impacts.
Keywords
About the authors
V. A. Moiseyev
ZAO KOMPOMASH-TEK
Author for correspondence.
Email: info@compomash-tek.ru
Russian Federation, Moscow, 127018
V. P. Nazarov
Siberian State Aerospace University
Email: info@compomash-tek.ru
Russian Federation, Krasnoyarsk, 660037
V. Y. Zhuravlev
Siberian State Aerospace University
Email: info@compomash-tek.ru
Russian Federation, Krasnoyarsk, 660037
D. A. Zhuykov
Siberian State Aerospace University
Email: info@compomash-tek.ru
Russian Federation, Krasnoyarsk, 660037
M. V. Kubrikov
Siberian State Aerospace University
Email: info@compomash-tek.ru
Russian Federation, Krasnoyarsk, 660037
Y. N. Klokotov
ZAO KOMPOMASH-TEK
Email: info@compomash-tek.ru
Russian Federation, Moscow, 127018