6533b857fe1ef96bd12b510b

RESEARCH PRODUCT

CFD Investigation of Spacer-Filled Channels for Membrane Distillation

Mariagiorgia La CervaAndrea CipollinaSalah Al-tahar BouguechaGiorgio MicaleNedim TurkmenMohammed AlbeiruttyMichele Ciofalo

subject

Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciMaterials scienceProcess modelingSpacer-filled channelFiltration and SeparationMembrane distillation02 engineering and technologyHeat transfer coefficientcomputational fluid dynamicsComputational fluid dynamicsMembrane distillationlcsh:Chemical technologyArticlesymbols.namesakeTemperature polarization020401 chemical engineeringComputational fluid dynamicLiquid crystalChemical Engineering (miscellaneous)lcsh:TP1-11850204 chemical engineeringlcsh:Chemical engineeringSettore ING-IND/19 - Impianti NucleariThermochromic liquid crystalsbusiness.industryDesalinationProcess Chemistry and TechnologyReynolds numberlcsh:TP155-156Mechanics021001 nanoscience & nanotechnologyPolarization (waves)6. Clean waterHeat transfersymbols0210 nano-technologybusiness

description

The membrane distillation (MD) process for water desalination is affected by temperature polarization, which reduces the driving force and the efficiency of the process. To counteract this phenomenon, spacer-filled channels are used, which enhance mixing and heat transfer but also cause higher pressure drops. Therefore, in the design of MD modules, the choice of the spacer is crucial for process efficiency. In the present work, different overlapped spacers are investigated by computational fluid dynamics (CFD) and results are compared with experiments carried out with thermochromic liquid crystals (TLC). Results are reported for different flow attack angles and for Reynolds numbers (Re) ranging from ~200 to ~800. A good qualitative agreement between simulations and experiments can be observed for the areal distribution of the normalized heat transfer coefficient. Trends of the average heat transfer coefficient are reported as functions of Re for the geometries investigated, thus providing the basis for CFD-based correlations to be used in higher-scale process models.

yearjournalcountryeditionlanguage
2019-07-25Membranes
10.3390/membranes9080091http://dx.doi.org/10.3390/membranes9080091