6533b853fe1ef96bd12ad7eb

RESEARCH PRODUCT

Nitrogen recovery using a membrane contactor: Modelling nitrogen and pH evolution

J. SerraltaJosé FerrerAurora SecoL. BorrásG. Noriega-hevia

subject

Membrane contactor for nitrogen recoverychemistry.chemical_elementPH modelling02 engineering and technologyAmmonia recovery010501 environmental sciences01 natural sciencesNutrient recovery from anaerobic digestionChemical Engineering (miscellaneous)Waste Management and DisposalTECNOLOGIA DEL MEDIO AMBIENTE0105 earth and related environmental sciencesContactorNitrogen recovery modellingChemistryProcess Chemistry and Technology021001 nanoscience & nanotechnologyAlkali metalPollutionNitrogenVolumetric flow rateAnaerobic digestionMembraneChemical engineeringReagentScientific method0210 nano-technology

description

[EN] A hollow fibre membrane contactor has been applied for nitrogen recovery from anaerobic digestion supernatant at different operating conditions obtaining nitrogen recovery efficiencies over 99 %. A mathematical model able to represent the time evolution of pH and nitrogen concentration during the recovery process is presented in this paper. The developed model accurately reproduced the results obtained in 26 experiments carried out at different pH values (from 9 to 11), temperatures (from 25 to 35 degrees C), membrane surfaces (from 1.2 to 2.4 m(2)) and feed flow rates (from 0.33 x 10(-5) to 5.83 x 10(-5) m(3)/s) predicting the variations in nitrogen recovery rates measured at the different operating conditions evaluated. Furthermore, due to the combination of nitrogen and pH modelling, the model is able to predict the variations in OH-concentration (alkali addition) required to increase and maintain the pH during the process. Thus, this model is a useful tool for process design and optimisation since it can predict nitrogen recovery rates and reagents consumption at different operational conditions such as flow rate, pH, membrane surface and temperature.

yearjournalcountryeditionlanguage
2020-08-01Journal of Environmental Chemical Engineering
https://doi.org/10.1016/j.jece.2020.103880