A 1-dimensional dynamic model for a sorption-compressor cell

•A 1-D dynamic model is developed for designing sorption-compressor cells.•Simulation cases are discussed for understanding the dynamics in sorption cells.•He and Ne experiments operating at 77K were carried out to validate the model. Sorption-based cooler is considered as an excellent candidate for...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2017-04, Vol.107, p.213-224
Main Authors: Wu, Y., Mulder, T., Vermeer, C.H., Holland, H.J., ter Brake, H.J.M.
Format: Article
Language:English
Subjects:
Activated carbon
Adsorption
Computer simulation
Convection modes
Cryogenic temperature
Dynamic model
Heat transfer
Helium
Liquid nitrogen
Low temperature physics
Mass transfer
Mathematical models
Neon
Numerical analysis
Sorption
Sorption compressor
Studies
Thermodynamic properties
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Summary:•A 1-D dynamic model is developed for designing sorption-compressor cells.•Simulation cases are discussed for understanding the dynamics in sorption cells.•He and Ne experiments operating at 77K were carried out to validate the model. Sorption-based cooler is considered as an excellent candidate for the vibration-free cooling at cryogenic temperature. In a such cooler, the sorption compressor is the most critical module. To design a sorption-compressor, effective numerical models are essential which allow one to simulate the details of the heat and mass transfer within the sorption-compressor cell, predict the system performance and optimize various parameters. This paper presents a 1-dimensional dynamic model for a sorption-compressor cell, which is based on extensive adsorption-isotherm measurements and realistic thermal properties of materials at low temperatures. This numerical model combines the mass and energy equations while the momentum equation is skipped. It assumes the pressure to be uniform within the cell. However, the convection term in the energy equation is evaluated in this model with proper approximation without calculating the velocity field. A typical simulation case is presented to understand the details during a sorption compression that occur in the sorption-compressor cell. Experiments based on helium and neon operating at 77K (liquid nitrogen temperature) were carried out to validate this model. The measured compressor performance was deviated from the simulation about 18%, but that is a reasonable inaccuracy for design propose and is well reasoned. Such 1-D dynamic model is qualified to be further used to design sorption compressor.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2016.11.040