Mathematical Modeling of Non-Stationary Modes of a Helium Liquefier

Mathematical Modeling of Non-Stationary Modes of a Helium Liquefier

Dynamic models of a heat exchanger, a turboexpander, a helium phase separator, and a dynamic model of the entire helium liquefaction installation were created. This model is necessary for modeling unsteady operating conditions of a helium liquefier. When creating models for heat exchangers, laws of...

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Veröffentlicht in:Chemical and petroleum engineering 2020-07, Vol.56 (3-4), p.302-309
Hauptverfasser: Lavrov, N. A., Khutsieva, S. I., Butkevich, I. K.
Format: Artikel
Sprache:eng
Schlagworte:
Analysis
Chemistry
Chemistry and Materials Science
Dynamic models
Energy conservation
Equipment and supplies
Finite difference method
Geotechnical Engineering & Applied Earth Sciences
Heat exchangers
Heating
Helium
Industrial Chemistry/Chemical Engineering
Industrial Pollution Prevention
Laws, regulations and rules
Liquefaction
Mineral Resources
Separators
Turboexpanders
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Beschreibung
Zusammenfassung:Dynamic models of a heat exchanger, a turboexpander, a helium phase separator, and a dynamic model of the entire helium liquefaction installation were created. This model is necessary for modeling unsteady operating conditions of a helium liquefier. When creating models for heat exchangers, laws of conservation of energy of flows, heat transfer walls, the core and body of heat exchangers were used along with laws of conservation of energy and mass for the helium phase separator. The system of equations for unknown values in exact coordinates and time is solved by the finite difference method. The obtained results adequately describe the unsteady processes taking place in the installation.
ISSN:0009-2355
1573-8329
DOI:10.1007/s10556-020-00773-0