Prediction of heat transfer for compact tube heat exchanger based on porous models

Abstract

A prediction method for temperature distributions in compact heat exchanger was developed by modeling the microchannel as a fluid-saturated porous medium. The study focused on the mathematical formulas and solution methods for convective heat transfer of heat core. Firstly, the correlation mechanisms and laws between the key parameters' effects and heat transfer were revealed and explained. The results show that the temperature/pressure/velocity contours obtained from the porous-media model are consistent with those of the tube-matrix. The longitudinal pitch has little effect on the flow characteristics and the Reynolds number. Transverse pitch has significant effects on the flow characteristics and the Reynolds number. Under different pitch conditions, the Nusselt number obtained by Zukauskas-correlation is larger than that of porous-media model, which is larger than that of tube-matrix. Secondly, the simplified model and fast calculation method were developed. Tube bundles of the heat exchanger core were modelled as micro-channels and theoretically as fluid-saturated porous structures. Results show that the heat transfer performance predicted by the micro-channels, tube-matrix, and porous-media model is consistent under the same boundary conditions. These results are consistent with the experiment. In addition, the computing cost and time required for the porous-media and micro-channels model is relatively reduced. Especially for the micro-channels model, the calculating time is less than one tenth of the original. Compared with the time-consuming numerical method, the new analytical solution has the advantages of cost and speed.