Персона: Глебов, Василий Борисович
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Институт ядерной физики и технологий
Цель ИЯФиТ и стратегия развития - создание и развитие научно-образовательного центра мирового уровня в области ядерной физики и технологий, радиационного материаловедения, физики элементарных частиц, астрофизики и космофизики.
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Василий Борисович
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- ПубликацияТолько метаданныеSimulation of Crude Chloroform Purification Methods(2019) Naletov, V. A.; Glebov, M. B.; Naletov, A. Y.; Khitrov, N. V.; Glebov, V. B.; Глебов, Василий Борисович© 2019, Springer Science+Business Media, LLC, part of Springer Nature. Crude chloroform purification methods to remove impurities with properties similar to those of chloroform (1,1-dichloroethane and cis-1,2-dichloroethylene) were analyzed. The considered methods for removing impurities from crude chloroform included reaction-rectification and separate processing in a reactor and a distillation column. The results of simulation of the above schemes are presented. Comparative analysis of the results taking into consideration economic viability showed that purification of crude chloroform by reaction-rectification shows great promise.
- ПубликацияТолько метаданныеImplementing energy-efficient autonomous power systems with trigeneration for increasing the profitability of oil production(2019) Naletov, V. A.; Glebov, M. B.; Naletov, A. Y.; Glebov, V. B.; Глебов, Василий Борисович© 2019, Neftyanoe Khozyaistvo. All rights reserved. Heavy oil production is characterized by low profitability and low oil recovery factor value. This is due to the necessity of using external power sources for the production process, on one hand, and on the other hand – due to the limited number of possibilities for using cheap resources in implementing efficient enhanced oil recovery methods. These problems can be successfully solved by utilizing energy-efficient multifunctional power systems. The design of suitable power equipment for cost-effective heavy oil production must be based on ener-gy-saving and, preferably, energy-autonomous power systems. In this regard, for high-viscosity oil fields with low gas-solubility factor values and increased power consumption per unit of oil produced the technology of power generation from associated petroleum gas becomes economically attractive. Such systems present a combined solution to the problems defined and do not require external carbon dioxide sources. The autonomous trigeneration power can be adapted for the feedstocks available on-site (associated petroleum gas or the flue gases from nearby power plants if present), produce the heat and power necessary for heating the viscous oil and produce carbon dioxide to reduce oil viscosity and improve phase mobility. Implementing trigeneration power systems makes it economically viable to develop and apply thermal and gas injection methods for improving oil recovery. The power systems comprise, as a rule, a power module that uses the associated petroleum gas produced on-site, a carbon dioxide capture module and a compression module for obtaining liquid or supercritical carbon dioxide. The structure of the autonomous trigeneration power system and the methodology of its implementation for oil production are presented. A comparison of the proposed autonomous power system with analogous overseas solutions is given.