2026-04-19T09:25:06Zhttps://recercat.cat/oai/requestoai:recercat.cat:2117/1043782025-07-17T08:13:03Zcom_2072_1033col_2072_452950
RECERCAT
author
Torras Ortiz, Santiago
author
Castro González, Jesús
author
Rigola Serrano, Joaquim
author
Morales, Sergio
author
Galione Klot, Pedro Andrés
author
Lehmkuhl Barba, Oriol
author
Oliva Llena, Asensio
2014
Low Thrust Cryogenic Propulsion (LTCP) systems [1] need a thermal energy storage acting as a heat accumulator, where a cryogenic flow of (LOx) propellant is gasified inside, under a fast transient evaporation process. The heat accumulator is heated by means of a secondary fluid (typically He or N2) which is exchanged from fuel cells. The heat exchanged or stored between both fluid flows is assured by means of a thermal energy storage tank filled of a Phase Change Material (PCM).
A numerical model of the thermal and fluid-dynamic behavior of the two-phase flow inside ducts working under cryogenic conditions, coupled with the analysis of the PCM accumulator is proposed [2]. The numerical analysis is based on: i) a one-dimensional and transient integration of the governing equations (conservation of mass, momentum and energy) for the fluid flow of propellant, and ii) a multi-dimensional and transient integration of the conservative governing equations in the region occupied by the PCM, taking into account turbulence modeling for solving the convection phenomena involved. The solid elements are modeled considering a multidimensional and transient treatment of the thermal conduction equation.
The numerical results are experimentally validated by means of a series of experimental tests [3] [4]. The comparative analysis shows the good agreement between both numerical results and experimental data. Different results under working conditions of the cryogenic flow and/or the PCM material, shows the possibility of this model for design optimization purposes.Peer ReviewedPostprint (published version)
Restricted access - publisher's policy
Àrees temàtiques de la UPC::Enginyeria mecànica::Mecànica de fluids
Heat storage
Propulsion systems
Thermal energy storage
Cryogenic conditions
Phase change materials
Numerical modeling
experimental comparison
Calor -- Emmagatzematge
Sistemes de propulsió
Numerical modeling and experimental validation of Thermal Energy Storage tanks for propulsion systems under cryogenic conditions
Conference lecture