Pathak, Mihir Gaurang.
Periodic flow physics in porous media of regenerative cryocoolers.
Degree: PhD, Mechanical Engineering, 2013, Georgia Tech
Pulse tube cryocoolers (PTC) are a class of rugged and high-endurance refrigeration systems that operate without moving parts at their low temperature ends, and are capable of reaching temperatures down to and below 123 K. PTCs are particularly suitable for applications in space, guiding systems, cryosurgery, medicine preservation, superconducting electronics, magnetic resonance imaging, weather observation, and liquefaction of gases. Applications of these cryocoolers span across many industries including defense, aerospace, biomedical, energy, and high tech. Among the challenges facing the PTC research community is the improvement of system efficiency, which is a direct function of the regenerator component performance. A PTC implements the theory of oscillatory compression and expansion of the gas within a closed volume to achieve desired refrigeration. An important deficiency with respect to the state of art models dealing with PTCs is the limited understanding of the hydrodynamic and thermal transport parameters associated with periodic flow of a cryogenic fluid in micro-porous structures. In view of the above, the goals of this investigation include: 1) experimentally measuring and correlating the steady and periodic flow Darcy permeability and Forchheimer’s inertial hydrodynamic parameters for available rare-Earth ErPr regenerator filler; 2) employing a CFD-assisted methodology for the unambiguous quantification of the Darcy permeability and Forchheimer’s inertial hydrodynamic parameters, based on experimentally measured steady and periodic flow pressure drops in porous structures representing recently developed regenerator fillers; and 3) performing a direct numerical pore-level investigation for steady and periodic flows in a generic porous medium in order to elucidate the flow and transport processes, and quantify the solid-fluid hydrodynamic and heat transfer parameters. These hydrodynamic resistances parameters were found to be significantly different for steady and oscillatory flows.
Advisors/Committee Members: Ghiaasiaan, S. Mostafa (advisor), Desai, Prateen (committee member), Walker, Mitchell (committee member), Wilhite, Alan (committee member), Haynes, Comas (committee member), Radebaugh, Ray (committee member).
Subjects/Keywords: Regenerator; ErPr; Nusselt; Porous media; Pore level; Periodic flow; Oscillatory flow; Darcy permeability; Forchheimer; Hydrodynamic; Thermal dispersion; Conjugate; Heat transfer; CFD; Pulse tube; Cryocooler; Cryogenics; Physics; Rare-Earth; Steady flow; Low temperature engineering; Materials at low temperatures; Porous materials Thermal properties; Porous materials
…and ErPr Filler Material (right).
Figure 3.2: Filler material volumetric heat… …permeability and
Forchheimer’s inertial hydrodynamic parameters for available rare-Earth ErPr… …available rare-Earth ErPr regenerator fillers.
2. Employing a CFD-assisted methodology for the…
to Zotero / EndNote / Reference
APA (6th Edition):
Pathak, M. G. (2013). Periodic flow physics in porous media of regenerative cryocoolers. (Doctoral Dissertation). Georgia Tech. Retrieved from http://hdl.handle.net/1853/49056
Chicago Manual of Style (16th Edition):
Pathak, Mihir Gaurang. “Periodic flow physics in porous media of regenerative cryocoolers.” 2013. Doctoral Dissertation, Georgia Tech. Accessed August 15, 2020.
MLA Handbook (7th Edition):
Pathak, Mihir Gaurang. “Periodic flow physics in porous media of regenerative cryocoolers.” 2013. Web. 15 Aug 2020.
Pathak MG. Periodic flow physics in porous media of regenerative cryocoolers. [Internet] [Doctoral dissertation]. Georgia Tech; 2013. [cited 2020 Aug 15].
Available from: http://hdl.handle.net/1853/49056.
Council of Science Editors:
Pathak MG. Periodic flow physics in porous media of regenerative cryocoolers. [Doctoral Dissertation]. Georgia Tech; 2013. Available from: http://hdl.handle.net/1853/49056