Transient simulation of a miniature Joule–Thomson (J–T) cryocooler with and without the distributed J–T effect.

The aim of this work is to develop a transient program for the simulation of a miniature Joule–Thomson (J–T) cryocooler to predict its cool-down characteristics. A one dimensional transient model is formulated for the fluid streams and the solid elements of the recuperative heat exchanger. Variation of physical properties due to pressure and temperature is considered. In addition to the J–T expansion at the end of the finned tube, the distributed J–T effect along its length is also considered. It is observed that the distributed J–T effect leads to additional cooling of the gas in the finned tube and that it cannot be neglected when the pressure drop along the length of the finned tube is large. The mathematical model, method of resolution and the global transient algorithm, within a modular object-oriented framework, are detailed in this paper. As a part of verification and validation of the developed model, cases available in the literature are simulated and the results are compared with the corresponding numerical and experimental data. [ABSTRACT FROM AUTHOR]