Evaluation of Concentration Polarization Due to the Effect of Feed Water Temperature Change on Reverse Osmosis Membranes

Water is a necessary resource for life development. Its excessive consumption has a negative impact, generating scarcity problems worldwide. Desalination is an alternative to solve these problems; its objective is to reduce the concentration of total dissolved solids to levels suitable for consumption. The most widely used desalination technology is reverse osmosis, which works by means of semipermeable membranes; however, lack of knowledge or wrong operation cause phenomena such as concentration polarization, which reduces the effective area for mass transfer in the membrane, increasing the energy consumption of the process. The objective of the present study is to evaluate the concentration polarization (β) of the concentration in reverse osmosis membranes by varying the temperature in the feed water (23, 25.5, 28, and 35 °C) for different concentrations (5000 and 10,000 mg L−1) in order to reduce its impact on energy consumption (kWh m−3). The results show that as the temperature increases, the specific energy consumption decreases for both concentrations. In the 5000 mg L−1 tests, the specific energy consumption decreased by 0.590 kWh m−3, representing 12.5%. For 10,000 mg L−1 tests, the specific energy consumption shows a reduction of 0.72 kWh m−3, which represents a percentage decrease of 14.54%.

[1]  J. A. Aguilar-Jiménez,et al.  State of the Art of Desalination in Mexico , 2022, Energies.

[2]  H. Sitaraman,et al.  Impact of Large-Scale Effects on Mass Transfer and Concentration Polarization in Reverse Osmosis Membrane Systems , 2022, SSRN Electronic Journal.

[3]  M. Purkait,et al.  Ameliorated polyvinylidene fluoride based proton exchange membrane impregnated with graphene oxide, and cellulose acetate obtained from sugarcane bagasse for application in microbial fuel cell , 2021, Journal of Environmental Chemical Engineering.

[4]  C. Adjiman,et al.  Correlations for Concentration Polarization and Pressure Drop in Spacer-Filled RO Membrane Modules Based on CFD Simulations , 2021, Membranes.

[5]  Yuan Wang,et al.  Analysis of Concentration Polarisation in Full-Size Spiral Wound Reverse Osmosis Membranes Using Computational Fluid Dynamics , 2021, Membranes.

[6]  Ewaoche John Okampo,et al.  Optimisation of renewable energy powered reverse osmosis desalination systems: A state-of-the-art review , 2021, Renewable and Sustainable Energy Reviews.

[7]  Shaofan Li,et al.  Surface slip on rotating graphene membrane enables the temporal selectivity that breaks the permeability-selectivity trade-off , 2020, Science Advances.

[8]  Iqbal M. Mujtaba,et al.  Performance evaluation of reverse osmosis brackish water desalination plant with different recycled ratios of retentate , 2020, Comput. Chem. Eng..

[9]  A. Karabelas,et al.  Analysis of temperature effects on the specific energy consumption in reverse osmosis desalination processes , 2020 .

[10]  Mohamed T. Mito,et al.  Reverse osmosis (RO) membrane desalination driven by wind and solar photovoltaic (PV) energy: State of the art and challenges for large-scale implementation , 2019, Renewable and Sustainable Energy Reviews.

[11]  Yiyang Dai,et al.  Processes , 2019, Encyclopedia of Personality and Individual Differences.

[12]  Arun Joseph,et al.  Dynamic simulation of the reverse osmosis process for seawater using LabVIEW and an analysis of the process performance , 2019, Comput. Chem. Eng..

[13]  A. Ruiz-García,et al.  Feed Spacer Geometries and Permeability Coefficients. Effect on the Performance in BWRO Spriral-Wound Membrane Modules , 2019, Water.

[14]  T. Matsuura,et al.  Temperature Effects on Concentration Polarization Thickness in Thin-Film Composite Reverse Osmosis Membranes , 2018, Chemical Engineering & Technology.

[15]  R. Sakr,et al.  Experimental investigation on the performance of a small reverse osmosis unit , 2018 .

[16]  J. S. Ramírez-Navas,et al.  Tecnología de membranas: Ultrafiltración , 2017 .

[17]  Shaofan Li,et al.  Molecular dynamics modeling of nano-porous centrifuge for reverse osmosis desalination , 2017, Desalination.

[18]  Ronan K. McGovern,et al.  On the asymptotic flux of ultrapermeable seawater reverse osmosis membranes due to concentration polarisation , 2016 .

[19]  C. Vörösmarty,et al.  Global water resources: vulnerability from climate change and population growth. , 2000, Science.

[20]  Germán Eduardo Dévora-Isiordia,et al.  Assessment of fixed, single-axis, and dual-axis photovoltaic systems applied to a reverse osmosis desalination process in northwest Mexico , 2021, DESALINATION AND WATER TREATMENT.

[21]  Ignacio A. de la Nuez Pestana,et al.  Performance evaluation and boron rejection in a SWRO system under variable operating conditions , 2021, Comput. Chem. Eng..

[22]  M. R. Martínez-Macías,et al.  Design of reverse osmosis desalination plant in Puerto Peñasco, Sonora, México , 2020 .

[23]  Adewale Giwa,et al.  Full-Scale Membrane Distillation Systems and Performance Improvement Through Modeling , 2019, Current Trends and Future Developments on (Bio-) Membranes.

[24]  I. Al-Mutaz,et al.  Development of a mathematical model for the prediction of concentration polarization in reverse osmosis desalination processes , 2017 .

[25]  L. Martinez-diez,et al.  Temperature and concentration polarization in membrane distillation of aqueous salt solutions , 1999 .