Your search keyword '"Damir Brdjanovic"' showing total 3 results

1. Effect of the co-treatment of synthetic faecal sludge and wastewater in an aerobic granular sludge system

Author

Claribel Buenaño-Vargas, Mark C.M. van Loosdrecht, Hector A. Garcia, Damir Brdjanovic, Christine M. Hooijmans, and Mary Luz Barrios-Hernández

Subjects

Environmental Engineering, Denitrification, 010504 meteorology & atmospheric sciences, Nitrogen, Suspended solids, chemistry.chemical_element, 010501 environmental sciences, Wastewater, 01 natural sciences, Waste Disposal, Fluid, chemistry.chemical_compound, Bioreactors, Nitrate, Settling, Environmental Chemistry, Protozoa, Vorticella spp, Co-treatment, Waste Management and Disposal, Effluent, 0105 earth and related environmental sciences, Sewage, Chemistry, Digested faecal sludge, Pulp and paper industry, Pollution, Aerobic granular sludge, Aeration

Abstract

The co-treatment of two synthetic faecal sludges (FS-1 and FS-2) with municipal synthetic wastewater (WW) was evaluated in an aerobic granular sludge (AGS) reactor. After characterisation, FS-1 showed the following concentrations, representative for medium-strength FS: 12,180 mg TSS L−1, 24,300 mg total COD L−1, 93.8 mg PO3-P L−1, and 325 mg NH4-N L−1. The NO3-N concentration was relatively high (300 mg L−1). For FS-2, the main difference with FS-1 was a lower nitrate concentration (18 mg L−1). The recipes were added consecutively, together with the WW, to an AGS reactor. In the case of FS-1, the system was fed with 7.2 kg total COD m−3d−1 and 0.5 kg Nitrogen m−3d−1. Undesired denitrification occurred during feeding and settling resulting in floating sludge and wash-out. In the case of FS-2, the system was fed with 8.0 kg total COD m−3d−1 and 0.3 kg Nitrogen m−3d−1. The lower NO3-N concentration in FS-2 resulted in less floating sludge, a more stabilised granular bed and better effluent concentrations. To enhance the hydrolysis of the slowly biodegradable particulates from the synthetic FS, an anaerobic stand-by period was added and the aeration period was increased. Overall, when compared to a control AGS reactor, a lower COD consumption (from 87 to 35 mg g−1 VSS h−1), P-uptake rates (from 6.0 to 2.0 mg P g VSS−1 h−1) and NH4-N removal (from 2.5 to 1.4 mg NH4-N g VSS−1 h−1) were registered after introducing the synthetic FS. Approximately 40% of the granular bed became flocculent at the end of the study, and a reduction of the granular size accompanied by higher solids accumulation in the reactor was observed. A considerable protozoa Vorticella spp. bloom attached to the granules and the accumulated particles occurred; potentially contributing to the removal of the suspended solids which were part of the FS recipe.

Published

2020

2. Microwave treatment of municipal sewage sludge

Author

Branko Lah, Hector A. Garcia, Ivan Mijatović, Christine M. Hooijmans, Eva Kocbek, and Damir Brdjanovic

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Waste management, Sludge drying, Evaporation, 010501 environmental sciences, Specific energy consumption, 01 natural sciences, Pollution, Activated sludge, Energy efficiency, Environmental Chemistry, Sewage sludge treatment, Environmental science, Specific energy, Sewage treatment, Waste Management and Disposal, Microwave generation efficiency, Microwave, Sludge, Municipal sludge, 0105 earth and related environmental sciences, Efficient energy use, Microwave irradiation

Abstract

Sewage sludge management and treatment can represent up to approximately 30% of the overall operational costs of a wastewater treatment plant. Microwave (MW) drying has been recognized as a feasible technology for sludge treatment. However, MW drying systems exhibit high energy expenditures due to: (i) unnecessary heating of the cavity and other components of the system, (ii) ineffective extraction of the condensate from the irradiation cavity, and (iii) an inefficient use of the microwave energy, among others issues. This study investigated the performance of a novel pilot-scale MW system for sludge drying, specifically designed addressing the shortcomings previously described. The performance of the system was assessed drying municipal centrifuged wasted activated sludge at MW output powers from 1 to 6 kW and evaluating the system's drying rates and exposure times, specific energy outputs, MW generation efficiencies, overall energy efficiencies, and specific energy consumption. The results indicated that MW drying significantly extends the duration of the constant rate drying period associated with the evaporation of the unbound sludge water, a phase associated with low energy input requirement for evaporating water. Moreover, the higher the MW output power, the higher the sludge power absorption density, and the MW generation efficiency. MW generation efficiencies of up to 70% were reported. The higher the power absorption density, the lower the chances for energy losses in the form of reflected power and/or energy dissipated into the MW system. Specific energy consumptions as low as 2.6 MJ L−1 (0.74 kWh L−1) could be achieved, well in the range of conventional thermal dryers. The results obtained in this research provide sufficient evidence to conclude that the modifications introduced to the novel pilot-scale MW system mitigated the shortcomings of existing MW systems, and that the technology has great potential to effectively and efficiently drying municipal sewage sludge.

Published

2020

3. Evaluation of a microwave based reactor for the treatment of blackwater sludge

Author

Audax Rweyemamu, Damir Brdjanovic, Christine M. Hooijmans, Hector A. Garcia, and Peter Matuku Mawioo

Subjects

Environmental Engineering, 0208 environmental biotechnology, Pathogen reduction, Sewage, 02 engineering and technology, Wastewater, 010501 environmental sciences, Waste Disposal, Fluid, 01 natural sciences, Article, Bioreactors, Blackwater, Escherichia coli, Bioreactor, Environmental Chemistry, Microwaves, Waste Management and Disposal, Volume reduction, Microwave irradiation, 0105 earth and related environmental sciences, Fecal sludge, Waste management, business.industry, Pollution, 020801 environmental engineering, Volume (thermodynamics), Sewage sludge treatment, Environmental science, Emergency sanitation, Water Microbiology, business, Microwave

Abstract

A laboratory-scale microwave (MW) unit was applied to treat fresh blackwater sludge that represented fecal sludge (FS) produced at heavily used toilet facilities. The sludge was exposed to MW irradiation at different power levels and for various durations. Variables such as sludge volume and pathogen reduction were observed. The results demonstrated that the MW is a rapid and efficient technology that can reduce the sludge volume by over 70% in these experimental conditions. The concentration of bacterial pathogenic indicator E. coli also decreased to below the analytical detection levels. Furthermore, the results indicated that the MW operational conditions including radiation power and contact time can be varied to achieve the desired sludge volume and pathogen reduction. MW technology can be further explored for the potential scaling-up as an option for rapid treatment of FS from intensively used sanitation facilities such as in emergency situations., Graphical abstract, Highlights • There is lack of fast and efficient fecal sludge treatment options in emergencies. • Microwave treatment is rapid and efficient in sludge volume and pathogen reduction. • Power and contact time can be varied to reach diverse levels of sludge treatment.

Published

2016