Abstract
This document examines the experimental application of the gas scavenging
membrane distillation (SGMD) process and its advantages and disadvantages. SGMD
is the least used configuration in membrane distillation (MD), and it is more expensive
to build. Scavenging Gas Membrane Distillation (SGMD) is used to treat complicated
solutions with volatile molecules to separate. In this study, heat and mass transport
mechanisms, as well as modeling and simulation studies, are systematically reviewed.
In SGMD, the main operating parameters are supply temperature, supply flow rate, gas
temperature, and gas flow rate. Furthermore, the performance of SGMD is discussed
and highlighted. Potential applications and areas in which SGMD could excel are
mentioned. Finally, future research opportunities in SGMD are identified.
A hollow fiber scavenging gas membrane distillation (SGMD) module is examined in
this study. Our SGMD distillation unit has been modeled by mathematical equations
and simulated by a runtime program on Matlab software to evaluate the effects of heat
transfer and mass transfer. Also, we have found that the heat and mass transfer in our
SGMD desalination system is defined by the temperature evolution in the vaporization
chamber and the inert gas velocity of the gas. The model predicts a small error of 3.6%
with the experimental data reported in the literature, indicating the reliability of
simulated results
Keywords: Collector Solar, Desalination, Energy, Fluid Velocity, SGMD.