Numerical simulation of non-adiabatic capillary tubes. Special emphasis on the near-saturation zone

•A numerical model to simulate non-adiabatic capillary tubes is proposed.•The model has an enhanced capability to address convergence difficulties.•A comprehensive validation of the model is carried out.•The model is used to carry out parametric studies on non-adiabatic capillary tubes.•The non-uniformity of the heat flux is numerically studied.

The aim of this article is to present a distributed numerical model that simulates the thermal and fluid-dynamic phenomena inside non-adiabatic capillary tubes. The resolution approach is based on a two-phase flow model where the fluid domain is discretized in a one-dimensional way, and the governing equations (continuity, momentum, and energy) are solved by means of a step-by-step algorithm. The model explained herein consists of an improved and extended version of previous works (Escanes et al., 1995; García-Valladares et al., 2002a,b; Ablanque et al., 2010) including two additional features. On the one hand, it allows the simulation of the two typical geometric arrangements found in capillary-tube/suction-line heat exchangers (i.e. concentric and lateral). On the other hand, it has an enhanced capability to address the convergence difficulties found in distributed models at the near-saturation zone. This document presents the major numerical adaptations done to the model, a comprehensive validation of the two geometric configurations, the model performance when tackling the aforementioned numerical difficulties and finally, some numerical studies.