Abstract
The measurement of local temperature distributions within a membrane distillation (MD) channel is a crucial step for the optimization of the channel and spacer geometry. This information allows the estimation of temperature polarization phenomena, which can dramatically influence the thermal efficiency of the process and the optimal choice of the geometric configuration (net spacer features, channel size, etc.). In the present work, a recently presented experimental technique, based on the use of thermochromic liquid crystals and digital image analysis, has been employed in order to assess the temperature polarization phenomena. The local heat transfer coefficient distribution on the membrane surface in a MD spacer-filled channel was thus assessed. The membrane has been modelled by a heat transfer polycarbonate layer. Different diamond spacer geometries were investigated, in order to highlight how the geometrical features affect both pressure drop and heat transfer in spacer-filled channels.
Acknowledgements
This work was carried out with the financial support of the MEDIRAS project within the EU-FP7 research programme (Contract No. TREN/FP7EN/218938). NSW (polynets) and Delstar Naltex are gratefully acknowledged for providing the spacer material for the tests. The engineers Marina Renda and Cristoforo Costanza are acknowledged for carrying out some of the experiments presented in this work. Authors Al-Sharif and Albeirutty would like to acknowledge the National Science, Technology and Innovation Plan (NSTIP) of the Kingdom of Saudi Arabia, which has made their contribution possible under Project WAT1576-03-11.
Notes
Presented at the Conference on Desalination for the Environment: Clean Water and Energy 11–15 May 2014, Limassol, Cyprus