Operation and model description of advanced biological nitrogen removal treatments of highly ammonium loaded wastewaters

[eng] The conventional Biological Nitrogen Removal (BNR) process consists on the oxidation of ammonia to nitrate (nitrification) and the subsequent reduction of nitrate to nitrogen gas (denitrification) using biodegradable COD as electron donor. If this BNR process is carried out over nitrite, it is...

Descripción completa

Detalles Bibliográficos
Autor: Dosta Parras, Joan
Tipo de recurso: tesis doctoral
Estado:Versión publicada
Fecha de publicación:2007
País:España
Institución:Universidad de Barcelona
Repositorio:Dipòsit Digital de la UB
OAI Identifier:oai:diposit.ub.edu:2445/35411
Acceso en línea:https://hdl.handle.net/2445/35411
http://www.tdx.cat/TDX-1106107-105322
http://hdl.handle.net/10803/1535
Access Level:acceso abierto
Palabra clave:Depuració d'aigües residuals
Contaminació de l'aigua
Nitrificació
Biodegradació
Bacteris anaerobis
Compost
Reciclatge de residus
Purification of sewage
Water pollution
Nitrification
Biodegradation
Anaerobic bacteria
Waste recycling
Descripción
Sumario:[eng] The conventional Biological Nitrogen Removal (BNR) process consists on the oxidation of ammonia to nitrate (nitrification) and the subsequent reduction of nitrate to nitrogen gas (denitrification) using biodegradable COD as electron donor. If this BNR process is carried out over nitrite, it is obtained a saving of 25% of the aeration costs, the 40% of the external COD to denitrify and the 30% of sludge produced. Another feasible treatment is the combination of partial nitrification (oxidation of the 50% of NH4+-N to NO2--N) with Anammox (denitrification of NO2--N to N2 using NH4+-N as electron donor). When compared with conventional BNR, this process avoids the requirement of COD to denitrify, leads to a saving of 65% of the oxygen supply and produces little sludge. In this thesis, several BNR processes have been tested to remove the nitrogen present in three wastewaters widely generated in Catalonia: supernatant from Anaerobic Digestion (AD) of municipal sewage sludge, supernatant from AD of the organic fraction of municipal solid waste and supernatant from AD of pig slurry. For these three wastewaters, the Sequencing Batch Reactor (SBR) technology was tested, operating with 3 cycles per day, SRT 11-12 days, temperature 30-32 ºC and using an external carbon source to denitrify. The working free ammonia concentrations and the reduced dissolved oxygen concentrations led to the inhibition of the nitrite oxidation to nitrate. Moreover, the integration of a coagulation/flocculation step inside the operating SBR cycle was studied to reduce the effluent COD. The operating nitrogen loading rates were around 0.85 kg N m-3 day-1. The SBR operation was also modelled by means of an Activated Sludge Model extended to describe the BNR over nitrite. This model includes pH calculation, the inhibition of nitrification by pH, NH3 and HNO2, oxygen supply and the stripping of CO2 and NH3. A methodology based on respirometric batch tests was proposed to assess the model parameters. Once calibrated, the proposed model showed very good agreement between experimental and simulated data of the three studied SBR treatments. The SHARON-Denitrification process was also studied in this work. This biological process takes place in a continuous reactor where aerobic/anoxic periods are alternated under specific HRT and temperature conditions that favours ammonium oxidizers growth and assures the total wash-out of nitrite oxidizers. An optimized performance of this process was obtained at HRT 2.1 days, 33 ºC, cycle length of 2 h and using methanol to denitrify. However, the use of supernatant of hydrolysed primary sludge as the organic carbon source to denitrify improved the process efficiency due to the alkalinity present in the primary sludge. The obtained operating nitrogen loading rate of this reactor was 0.38 kg N m-3 day-1. Furthermore, two biological nitrogen removal treatments for partial nitrification of sludge reject water were operated and modelled: the SHARON process and the partial nitrification in a SBR. Both processes showed a good performance in the generation of an effluent with a NH4+-N to NO2--N on molar basis of approximately 1. In the SBR, the key factor responsible of the inhibition of nitrite oxidizers was the working free ammonia concentration. For the SHARON process the key factor was the implemented SRT at the operating temperature. Finally, an Anammox SBR was operated to treat a highly ammonium loaded synthetic wastewater, that represented the effluent obtained in the partial nitrification units. The feasibility of the Anammox process at different temperature conditions (between 18 and 30ºC) was tested. At 18 ºC, a stable operation was achieved treating 0.30 kg N (L day)-1, with a stoichiometry slightly different from that obtained under 30 ºC.